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Friday, December 20, 2013

Wondering About Ourselves


One of themes of this book is that if we are to satisfy our curiosity about the universe around and within us, we will need to use our imaginations to the best of our abilities, because the universe as we perceive with our physical senses will only take us so far. We saw this first in chapter two, in which our robotic exploration of the solar system revealed worlds which we had not foreseen, at least partly because we had not completely unleashed our imaginations on the possibilities. In chapters three and four we were forced to use our imaginations again to picture how the world of the ultra-tiny, or atoms and electrons, works, by suspending our common-sense ideas and perceptions so that such things could become real and not mere philosophical concepts, tangible things we could get our minds around and acquire a sense of their true nature. My point is that in these journeys we have gained a certain intellectual satisfaction – real questions leading to real answers – but again we are being warned that clinging to the world as modeled by our eyes and visual cortexes is a habit we are going to have to resist, one way or the other, if we expect to keep making progress.
This chapter is on biology, which is why I begin with this emphasis on imagination, for with the possible exception of quantum mechanics, I believe nowhere is imagination more required than on the subject of life. Living things, their origins, their myriad shapes and actions combined with their underlying foundations, and how their marvelous, interdependent, and beautiful adaptivity to all environments they find themselves in, is a series of mysteries that will not yield to the unimaginative mind, however much plodding thought is brought to bear on them. Unconvinced? Then let’s start with the big question, the question even the most renown scientists have been beating their heads against right up to today: What is life? We see it practically everywhere we look (at least on this isolated, tiny planet) and we generally find we have no difficulty in distinguishing it from the world of the non-living.
I think at this point most of us would stop and agree, perhaps after some careful thought, that there is something essential about living things. The impression of this essentialness, this intentionality I will call it, is indeed overwhelming, and easily hits us on the head as the prime divider between life and everything else. All non-living things seem to follow the laws of physics in a dumb, obvious way: a pebble thrown into the air traces out a perfect mathematical parabola as it interacts with the law of gravity, finally striking earth in a completely predictable place at a completely predictable time, given that we know its initial speed and angle with respect to the ground. A pebble thrown into the air … but what about a butterfly? When we watch a butterfly we put away our calculators and measuring instruments, and simply watch in wonder. A butterfly doesn’t blindly follow a parabola, it – well, it seems to do whatever it decides to do, which is why making measurements and calculations are pointless. A butterfly flies away, perhaps never to be seen again. Or maybe it alights on a flower and gazes at us, seemingly as equally puzzled by us as we are of it. We are just certain there’s something going on behind those tiny eyes. Something inexplicable. Something essential. Something that gets down to what makes a pebble just a pebble but a butterfly something ... at the risk of being misunderstood, miraculous.
We still have taken only a few steps in our attempt to define life, however. For the next question is, is our butterfly, and by implication ourselves, truly miraculous?
* * *
Let us try a different tack. Richard Dawkins, in The Blind Watchmaker, proposes a definition of biology that is unusual but which he claims to be perfectly workable: biology is the study of complex things that appear to have been designed for a purpose. I speak of intentionality, but complexity plus the appearance of design provides us with another way of describing it, perhaps an even better way to make progress. Dawkin’s point when applied to our butterfly is threefold; first, like all life forms it is far, far more complex than the pebble, far more complex than our solar system even; second, not only does it act as though it has a mind capable of intentions and a body capable of carrying those intentions out, it gives all the appearance in the world to have been designed that way, designed to fly (as well as many other things); and third, and most significantly, there is an intimate relationship between complexity, intentionality, and design. Flying is not a simple thing, not the way butterflies do it at any rate, so complexity plus design, or as I call it, intentionality, appears to improve our handle on what we mean when we say something is alive.
But is it enough? Or for that matter, is it really true? Living things do not always appear to be complicated. Anyone dissecting a butterfly – no easy task, admittedly – would marvel at its many interlocking intricate parts, but what about the simple amoeba? Or a bacterium? At first sight, such things do not appear to be particularly complex, but we all agree that they are alive; that, like the butterfly, they appear to move under the guidance of some internal intentions, some essence which non-living things, even complex ones like computers, do not possess.
Most of us, I suspect, will find ourselves easily moving along some kind of reasoning like this, perhaps without thinking about it very much. It does seem to handle our common sense objection to calling complex things like computers and airplanes biological while keeping “simple” things like bacteria and amoebas in the same camp as butterflies and human beings. Living things, from the simplest up to the most complex, really do seem to have some special quality or essence that ordinary matter lacks, whatever else that matter has. We almost can feel it there, at the most basic levels, and we are certain that we would never have any difficulty in distinguishing a living thing from the non-living, based on that feeling. Wherever in the universe we might find ourselves, the question of whether we were amongst life or not would appear to be elementary.
* * *
Or would it? To our astonishment, our common sense view of things biological begins to disintegrate the moment we apply curiosity and imagination to it, to dissect it and look into it at the finest levels science allows us to probe. In doing so, try as we might, we never encounter this special essence or quality which seems so obvious at first sight. Instead, what we do find, when we break out our detectors and other scientific instruments, is that living things are composed of atoms and moledcules like everything else, albeit not in the same elemental proportions, yet acting according to the same laws of physics and chemistry as everything else. The mechanical, Newtonian universe of objects and forces, modified by quantum effects on the smallest scales, appear all that is needed to explain why butterflies fly, or mate, or find food, or stare at us with the seeming same curiosity that we feel gazing upon it. All our initial impressions, and all the stories that have been told and retold aside, there appears no miraculous special something that we can affix to or inject matter with to make it come alive; no energy fields, no forces, no protoplasm, no elixir of the living, nothing we can pump into Dr. Frankenstein’s reassembled parts of corpses which will make it groan and open its eyes and have thoughts and feelings and break its bonds to move in accordance with them. There is nothing like that whatsoever. No, whatever it is that characterizes life lies elsewhere.
But the impression of such a force is so strong, so deep, so instinctual that, try as we might, we cannot simply abandon it without at least wondering why it is there, where it comes from, and what it tells us. Something is there, of that there can be no question.
Intentionality. Complexity. Design. Try to put aside your ordinary impressions and perceptions of things, and seed your mind, germinate in your mind, take root and push out of the soil and put forth leaves and vines in your mind, the theme that to satisfy our curiosity we must look at the world from a different perspective, the one that imagination unlocks. Very often, we find that when we look closely, what we thought we were seeing fades away, yet is replaced by something just as amazing – no, more so.
Let us start with the simplest of things that could be called living. Consider the virus. Here is something both considerably smaller and simpler than the smallest, simplest bacterium, all biologists would agree. But on the most microscopic of scales, that of individual atoms and molecules, even the simplest virus turns out to be a machine of remarkable complexity. At the very least it has to be able to recognize a host cell it can parasitize, whether it is a cell in your body or a bacterium (in which case it is called a bactaeriaphage), somehow figure out the molecular locks and other gizmos which cells use to protect themselves from invasion, penetrate the defenses, then usurp the molecular machinery the cell uses to replicate itself, perverting the cell into a factory for producing many more copies of the virus, copies which then have to figure out how to break out of the cell in order to repeat the cycle on other cells or bacteria, all the while avoiding or distracting the many other layers of defenses cells and bodies use to protect themselves from such invasions.
Biologists still debate whether viruses can be legitimately counted among the various kingdoms and domains of life, but there is no doubt that their hosts, whether bacteria or other single celled organisms or multicellular organisms, can be classified in the great Tree of Life, from which all other living things, be they plants, animals, fungi, or you, diverge from. And what dominates this tree, right down to the most primitive beginnings we have yet been able to detect, is a level of complexity that we simply do not encounter among the great many more things than don’t belong on this tree, from rocks to stars to solar systems to galaxies.
So after all this, have we cornered our quarry? We started with the at first sight idea that life possessed some special quality or substance or essence, then realized that we could not find that essence however hard we looked. But what we did find was that living things, even the simplest of them, showed a level of complex organization well beyond the most complex of non-living things.
Life is special. I don’t want to lose sight of that. We are fully justified in our grand division of matter into the non-living – things we explain only by the laws of physics and chemistry at a simple level – and the living, all the things we must also apply whatever biology has to teach us. What I have been trying to show is that, whatever that specialness is, it isn’t as obvious as it appears upon first sight. It is more subtle, involving a number of characters and qualities, one of which is complexity and another the appearance of design or purpose.
* * *
Again, I say that life truly is special. It is early May, and I have just come home from a walk through Pennypack Park, one of the many lovely natural places which skirt the city where I live, Philadelphia, one of several cities along the eastern edge of North America. I would love one day to walk on the moon or on the red soil of the planet Mars, but what I have just experienced would be utterly lacking in those dead, albeit fascinating places. In the spring in this part of the world, as in many other parts of our planet, every sense is roused to life by the call of the wild. Not only are you surrounded by the verdant green of new buds and flowers and grasses, but also by a cacophony of whistles, chirps, tweets, and other rhythmic sounds which reminds you that you that new life is all about, some of it still rustling itself to full wakefulness after winter but much of it already in the air and alit on the many twigs and branches. And even without vision and sound, you can still smell the musty beginnings of stirrings things, the scents of enticing blossoms and irritating pollens, and you can still feel the grass between your toes and the softness of young leaves on your skin as you brush by the undergrowth.
Here I have spoken of complexity and the appearance of purpose and meaning, and perhaps that is exactly what our scientific mission into the heart and soul of biology requires, but this is one place where, I have to submit, we will never really capture the essence of what we are studying. Life is something that has to be experienced, and only living things themselves have the capacity, as far as we know, to experience anything. So, in a sense, our quest to satisfy our curiosity begins with the admission that, at least for the world of the living, we never can completely satisfy it.
Am I going to give up, then? No, because, as I have maintained up to this point, curiosity combined with imagination and the scientific method can undo any knot, unlock any riddle, however baffling and impervious it may seem. I have even suggested a starting place even, this idea of complexity combined with apparent purposefulness, an idea I hope to build upon and demonstrate just how powerful it is. I think we can agree that it is a good starting place. Biological things, even the simplest of them, are highly complex, we now see, and there does seem to be something to this notion of being imbued with purpose, however that comes about. If we can make some progress on this front, then perhaps in the end we will satisfy our intellects after all, as impossible as that seems looking at things from their beginnings.
* * *
Actually, I would like to strike out first on a different front than is typical in tomes on biology. I would like to retreat back to simple matter, of the kind we started to explore in chapter four, and work up to what I see as an essential question: can the laws of physics and chemistry, as we have come to know them, even provide a platform for the vast complexity of living things? In other words, do atoms, those basic building blocks of all things material, even allow for the enormous intricacies let alone purposefulness of the biological world?
This is a very good question for it turns out, at least for the great majority of atoms that we investigate toward this end, the answer is a clear and resounding No. Try as hard as we can, we find that when we begin assembling most atoms into more and more complicated molecules or other structures, they aren’t very cooperative in this process. No, things fall apart, often violently, even if we can figure out a way of putting them together. For the great majority of the kinds of atoms to be found in nature, constructing an edifice of complexity sufficient for life is a hopeless task. They simply will not stay put and do as they are told.
All that is with one, yes really only one, fortuitous exception, and one that we began to explore in the previous chapter. The carbon atom. Atomic number six on our periodic chart, a chart which now runs to over a hundred if we include the extremely short-lived ones humans have made in laboratories, is truly special. Carbon is what makes it all possible, to the point where we can confidently say that if that if this one lone atom out of the dozens had proved impossible for the universe to produce in any significant quantities, neither you nor I nor any of the myriad millions of species of life we share this planet – on perhaps any planet – with would have any chance at existing. Carbon alone is not sufficient for life, but it is absolutely necessary. Of all the other elements in the biological stew, perhaps substitutes could have been found, but no element, under any conditions imaginable, appears a likely alternative to carbon. This is because no other element yet discovered or made could take its place as the backbone of the sizes and varieties of the molecular components needed to make life, even the simplest forms of life, possible. I will even go as far to say that if an alternative form of life is ever found, if carbon isn’t at its roots than neither is chemistry.
Carbon, indeed, is so important that it is the only element whose existence was predicted by the fact that living things do exist. All of the naturally occurring elements in the universe today come from one of two sources: either they were made in the first few minutes of the universe’s existence, in the Big Bang which we will come to in a later chapter, or they were made in the cores of the many trillions of massive stars that have come and gone since the beginning. The reasons for both is the same: larger, more complex atomic nuclei – the core of protons and neutrons which make up the center of atoms and ultimately determine their respective element’s properties – have to be made from the simpler ones, ultimately from the simplest of them all: hydrogen, atomic number one, a single proton (sometimes combined with one or even two neutrons). This is done by smashing two smaller nuclei together to make the larger one, a process which requires extremely high pressures and temperatures because all nuclei are positively electrically charged and ordinarily repel each other unless they can be brought close enough together to be captured by something called the strong nuclear force. Such conditions existed naturally only in the moments after the Big Bang and today in the hearts of stars, particularly the larger, hotter stars. Essentially, to create a carbon atomic nucleus of six protons and six neutrons, what must happen is that three helium four nuclei, each consisting of two protons and two neutrons apiece, must be welded together in exceedingly short order, within a millionth of a millionth of a second, and then held together until they can relax and become stable. This so-called “triple-alpha” process (an alpha particle is a helium four nucleus) would itself seem to be an insurmountable barrier to carbon and all the elements beyond, but surprisingly that turns out to be not so: the pressures and temperatures which come to exist in large stars – stars large enough to explode or somehow spew their core substances into intergalactic space, making all those large atomic nuclei available to new generations of stars and planets such as our own, not to mention our own existence – are sufficient to guarantee this process will happen enough to account for all the carbon we are going to need.
With one problem. This problem lies in the fact that our newborn carbon nucleus is ringing and pulsing with so much energy that it should almost instantly fragment into smaller pieces. What we need is some kind of stable “resonance” at such high energies, which will allow the newly born nucleus to hang together just long enough to relax by a variety of processes into a lower, energetically stable state. But when the details of Big Bang and stellar nucleosynthesis were being worked out in the 1940’s and 50’s, no such resonance state was known, nor was there any theoretical reason – theoretical from the standpoint of physics at that time that is – to think one should exist.
The problem was solved by the single and to this day to my knowledge lone instance of the so-called Anthropic Principle being used to successfully explain an actual physical fact. If you are not familiar with it, the Anthropic Principle, in its most basic, common-sense form, is simply the statement that since we exist in this universe, the laws governing it must be compatible with our existence (this seems obvious, but there are other versions of the Anthropic Principle which are more controversial). In this case, what the principle insists is straightforward and simple: it insists that since the element carbon does exist in sufficient quantities for our existence, there must be a resonance energy level available for the newly bred nuclei. The Anthropic Principle is not an argument physicists are usually enamored of, but one group was sufficiently impressed by the line of reasoning to take an actual look and see if the resonance level really did exist. Lo and behold, they found that it did. In fact the discovery not only explained the existence of carbon in sufficient quantities in the universe, but also of the many elements that are in turn built up from it: oxygen, neon, silicon, indeed basically the entire periodic zoo of elements we find, to varying degrees of magnitude, present in the universe today.
* * *
So, carbon exists. It isn’t a very common element, and the fraction of it that does reside in our universe in conditions where life can form, is relatively small. But it is enough to account for, not just you and I, but all of the manifestations of biology all about us, almost anywhere you go on this planet, and probably what other worlds or places we may one day find life. The next question is, what is it about carbon that gives it its uniqueness, its specialness, its ability to construct the large and complex and seemingly purposeful phenomena that we call living things? What does carbon have that no other atom seems to possess, however hard we play with them and build castles in the air from them? Why do these carbon-based organisms which are found with such fecundity on Earth and hopefully on at least some other planets or moons or asteroids or places we’ve yet to think of, exist, continue to exist, and have existed for so long? Yes, carbon is special, but special in what ways, so many ways that no other atom has a prayer of filling its role?
The answer to this question is answered by a combination of chemistry and physics, some of which I have already explored in the last chapter. It involves two separate characteristics of carbon, chemical as well as physical characteristics, characteristics which carbon and carbon alone possesses, characteristics which we can never even mock up in any other element, however hard we try.
One of those characteristics is smallness. It is not coincidence that the great majority of the atoms which constitute life are to be found at the top of the periodic table, where the smallest and simplest of atoms resides. One reason for that no doubt is that small atoms are, due to the processes which forge them, simply more common than large ones. But another reason, the key reason, is that smallness means that these atoms can come much closer to each other in the bond-forming process, resulting in bonds that are much stronger and stabler than larger atoms can form. It is, in fact, well accepted, that the small sizes of the first and second rows of the periodic table account for much of the uniqueness of their chemistry, especially in the ways they differ from their heavier cousins, even in the same column. To give an example, sulfur, selenium, and tellurium are much more similar to each other than the first member of their column, oxygen. This is a statement which could be made for nitrogen and boron as well, and even, although to a lesser extent, lithium and fluorine. Small atoms make for short, strong bonds, something necessary if we are to build up to the size and complexity of living things and have them remain stable. Even a structure as small as a bacterium demands a level of complexity which only carbon and other small atoms can provide.
So smallness is important, but it is not sufficient. The reason for this can be found by examining the other elements in the first row, for example hydrogen, which can bond with one and only one other atom; usually another hydrogen atom, making the molecule H2, which is almost entirely what we are dealing with when working with hydrogen on the scale of pressures and temperatures we are accustomed to. Likewise, nitrogen and oxygen, also essential to life, appear to form stable binary molecules, N2 and O2, which do not spontaneously join together into longer, more complicated structures but make up the most common constituents of this planet’s air we breathe, which is about 78% N2 and 21% O2.
Following this line of argument, shouldn’t stable C2 molecules exist also, thereby undermining this theme of small atoms making large, structurally stable molecules, and once again pulling the rug out from underneath our feet in our quest to make the large, complex yet stable molecules and molecular edifices that biological things demand? Here is the interesting part, however; the neat trick by which nature refuses to be obvious but instead manages to provide us with exactly what we were looking for. For it turns out that C2 does not (or only rarely) exist, indeed is not normally stable, and once again we are allowed to proceed in the directions biology calls upon us to follow.
O2 and N2 are stable due to the smallness of oxygen and nitrogen atoms, but there are limits to how large you can build these small, compact molecules. These limits are inherit in the kinds of bonds that atoms can form with one another. In chapter four, I introduced the idea of the molecular orbital as the bond between two atoms created by the combination of the atoms’ atomic orbitals. The strength of the resulting bond depends on how well the atomic orbitals can overlap in space. This is where smallness comes into play. The bond between two hydrogen atoms is very strong because these atoms are very small and can approach each other quite closely, allowing for maximum overlap.
A picture being worth a thousand words, let me recapitulate some of the material for the preceding chapter about molecular bonds. If you’ll remember the case of the H2 molecule, we explained the bond as the overlap of s orbitals, in which two new orbitals came into existence:
one bonding one between the atoms, which strengthens the bond, and one antibonding orbital, which weakens it:



The bonding MO in this case has a name: it is called a sigma, or σ, bond, as chemists call them. This sigma bond, to reemphasize, is formed by the overlap of the s orbitals in the two hydrogen atoms, but more broadly, sigma orbitals / bonds are at highest density between the two orbitals. There is another type of σ bond, however, which can be formed by the overlap of p bonds. If you’ll recall, these bonds have the general shape


 
Here, the lines drawn represent the y (vertical) and z (horizontal) axes, while the x axis orbital would point at straight angles through the page. This is why I say that there are three p orbitals, all perpendicular to each other. Now, if you imagine the pz orbitals of two atoms, lying along the horizontal line above, the z axis, you can see how they too can overlap to form sigma orbitals, just as the s orbitals did. Very nice, and exactly what happens for many elements in the first row of the periodic chart. But now, remembering that there are three p type orbitals, you can see that in the case of two atoms the pz and the py don’t directly overlap, but appear to be parallel to each other. Hang in here. For I think I can make this clear with a few more diagrams and words. The orbital above, which I called py because the lobes are oriented in the y direction along the axis, cannot form σ (sigma) molecular bonding orbitals, because they don’t directly overlap between the atoms. But there are other kinds of bonds, bonds in which the overlap of the atomic orbitals is not so direct and obvious. The py and pz type orbitals possessed by the above atom are a perfect example of this. Still, using our imaginations, we can see that, although these orbitals do not combine headlong, there is nevertheless an overlap, an oblique or sideways overlap, between the lobes of the orbitals, for both the px and pz orbitals, if the atoms involved approach each other closely enough. The overlap is not as strong as with the pz orbitals, which directly overlap in the plane of the paper to form σ bonds, just like the s orbitals do, but it is there nevertheless. It is strong enough that we can construct new molecular orbitals, or bonding orbitals, using these oblique or sideways oriented atomic orbitals. Chemists have a name for these kinds of bonding orbitals as well; they are called π orbitals or pi bonds, again applying our habit of using Greek letters, in this case the letter π which we call pi. An example of this sideways, pi type bond is given below:

 
The nucleus of each atom lying at the center of the two py lobes is shown by the intersection of the x and z axes, while the py orbitals are the areas “smeared out” above and around them. Can you see that there can be sufficient overlap, and hence bond formation, between the two atoms using their py orbitals, shown by the grey regions, provided that they can be brought close enough together? Also, is it clear to the eye that the π bonds are not as strong as sigma (or σ) bonds, composed of either s or px orbitals, which occupy the space directly between the atomic nuclei, and that to have any strength at all the respective atoms must be able to approach each other very closely, which in turn means that only small atoms form stable π bonds? I think yes, just by looking at them, we can see that π bonds will be weaker and easier to break than σ bonds, a disparity that can only increase as we look at larger and larger atoms.

So. What has all this got to do with living things and their chemical makeup? As it turns out, plenty. The molecules N2 and O2 are stable only because of the smallness of their atomic sizes, and so can have as many as two (as in N2 or O2) π bonds, in addition to their σ bonds – this, by the way, is why we call them triply-bonded or doubly-bonded molecules.

Still, they would prefer for energetic reasons to exchange these π bonds and create or join in with molecules where all the bonding is of σ character; that is why we find how easily they combine with, for example, hydrogen atoms to make the simple molecules of water (H2O) and ammonia (NH3). Even carbon, which we are reserving as the basis of many manifestations of life, is often found bound up with hydrogen too, in this case to yield the simple molecule of methane (CH4) as seen in the last chapter. I should also mention to make this clearer that this is the same reason why third level elements, even those in the same family of nitrogen and oxygen – phosphorus and sulfur – do not easily form π bonds, as the larger size of these atoms do not allow them to approach each other closely enough; thus, we do no see p2 or s2 molecules, but more complex structures (this is also because these atoms have available 3d orbitals for additional bond forming, but we will not go there).

As we alluded to in chapter 4 carbon’s versatility comes forth even in these most basic of molecules. Using sp3 (again, you may have to refer to the last chapter to refamiliarlize yourself with them) hybrid orbitals, carbon can form as many as four strong, sigma bonds with other atoms, a feat no other atom can boast of. Since up to four of those atoms it can combine with is another carbon, we can imagine a vast network of sigma-bonded carbon atoms, a network that can grow virtually as large, and as complicated, as it likes. Such networks in fact do exist, and as already mentioned we call them diamonds, allegedly the hardest substance in the universe. What is more important for this discussion is that if the simple atom of carbon can yield the hardest of materials in the universe, then the creation of living things would appear to be a natural outflow of this process of bonding one carbon atom to another. Moreover, with each carbon atom having four “hands” or valence electrons to offer any other atoms it may encounter, we should be able to come up with just about any large, complex, stable molecular structure we can imagine.

Indeed we can, and have, and the subject even has been given a special name: organic chemistry. That’s right; carbon is so unique in its abilities to build complex structures and edifices – meaning large, complicated molecules – that it and it alone is awarded the very special prestige of having an entire branch of chemistry constructed around it. As a matter of fact, go to any university’s web site and start checking out the chemistry courses and you will see that the very subject appears to have two major branches: organic and all the rest, some of the rest actually being called inorganic chemistry. No other element even comes close to commanding such respect. So we finally see carbon’s commanding role being due to its unique ability to form the backbone of an almost infinite variety of molecular sculptures. And it is exactly that kind of versatility we are going to need if we are to make any sense of the fantastically complex, seemingly purposeful assemblages of atoms and molecules which comprise the roots and foundations of the vast panoply of biology spread before us. When it comes to satisfying our curiosities, that is one nail we can pound in completely and begin our explorations around. We can now say that basic, straightforward physics and chemistry do allow for biology, though, again this must be stressed, they are nowhere close to explaining it by themselves. The explanation requires something else, something that we have been edging toward, a grand idea or set of ideas that provide the gratification we have been seeking. It is time to fully enmesh ourselves in these ideas, and bask in the glory of what we have been seeking.

* * *

So, the chemistry of carbon, along with a handful of other atoms like oxygen, nitrogen, hydrogen, sulfur, phosphorus, and a smattering of other trace elements gives us all the building blocks we need to create human beings, elm trees, barnacles, tyrannosaurs, and paramecia, but that doesn’t explain how or why the blocks manage to come together in the right ways. Brachiosaurs, which were very large, plant eating dinosaurs, may be built from the same carbon and nitrogen and all the other atoms in our own biological grab-bag of goodies, but no amount of blending, whipping, hurling around, or piling one thing on top of another will never give us that Jurassic eating machine, or anything else that could be even remotely construed as alive in any sense of the word.

Here we are in our quandary, because we know the answer provided by thousands of years of folk-wisdom, occasionally dressed up in full theological garb. God, or some pantheon of gods, or something supernatural and miraculous, conjured up all the millions of species that creep, run, swim, fly, fester, or patiently await for the comings and goings of seasons and suns, so goes the wisdom of the ancients. Most people who have ever lived, and probably most of those alive at this moment, find this answer satisfactory. But if we are to truly gratify our curiosity, we have to accept that this is no answer at all. It is just another waving of the wand of the miraculous, with results unexplained and unexplainable. Or to put it another, yet more devastating, way: if God or some set of gods explains the complexity plus appearance of purpose we find in biology, then what explains Its / their equally perplexing purposeful complexities? It’s an infinite regress, which leads nowhere and satisfies nothing in the end. The only possible way this “explanation” can work is if we can come up with something that is intelligent, intentional, creative, and yet somehow simple. My suspicion is that is exactly the kind of reasoning, at a largely sub-conscious level, the theological inclined are actually all about. To which all I can say is, I cannot dismiss it completely out of hand, because imagination might someday find just such a joker in the deck. My suspicion, however, is that there really are limits on what reality can present us with. Intelligence and intention must be built upon an edifice of complexity, along with the law of physics and chemistry, any way we cut the cards. Five hundred years of science, and five thousand of philosophy, have yet to sniff out any alternatives, and seem unlikely ever to do so.

So the supernatural is a non-starter, at least if we intend to stay true to the themes of this book: curiosity, imagination, and the scientific approach to explaining things. We have to find something, or things, in what we already know, or can reasonably speculate about, if life is to be laid out, dissected, elucidated in some manner that satisfies us. What I experienced during my walk through Pennypack Park begs for explanation as much as, if not more, than anything else one might experience. But where does one begin this journey towards enlightenment? How do we even start to think about it?

* * *

Fortunately, there is a place to start; not a place that makes everything that follows easy or simple, but one that I believe at least parses the subject of life into two separate, somewhat more manageable sub-topics. One sub-topic is the question of the origin: how the atoms and molecules that in early Earth were in arrangements almost entirely non or pre-biological came to be re-assembled – or super-assembled is perhaps the better term – into the most primitive versions of our complexity plus (appearance of) purpose life forms that appear first on this planet between three and a half and four billion years ago.

Is this a separate question? Yes, it clearly is, and for the following reasons: first, all things biological, however large or small, or ephemeral or long-loved, or whatever their form or function, or however they eke out their livings, rely upon a common basis of biochemistry which can be clearly seen in all of them, if you examine them at the level of atoms and molecules. That in itself suggests a common origin, and provides the platform for the other reason: this platform, this origin aside, is what accounts for the overwhelming diversity in livings things that we witness today, billions of years after the beginnings, in the various shapes, colors, sizes, and behaviors of the tens of millions of plants, animals, fungi, and other species which have crawled, flown, walked, swam, or in whatever manner reached practically every corner and niche of remotely inhabitable space that can be found on Earth.

Here, in the early twenty-first century, this cleavage of the problem of life into these two daughter problems is supported by so much evidence that there can be no doubt that it is the proper way to initiate our quest. The chemical evidence from DNA, RNA, proteins, carbohydrates, and other biomolecules has demonstrated their common origin beyond any reasonable doubt. As an example, the viruses which I have mentioned, so tiny that they cannot be seen by any optical microscope however powerful, and whose relative simplicity makes their place in the bower of biology still a disputed issue, can feast upon hosts as disparate as bacteria and human beings and redwood trees only because the molecular machinery underpinning all of these things, including the viruses themselves, is almost identical. The same could be said about the relationship between virulent bacteria and their animal / plant / fungus hosts; for that matter, about the plain, ordinary fact that most living things on this planet make their living by somehow consuming other living things. This is something that couldn’t happen if we weren’t all made up of the same basic, chemical, stuff, underneath all our appearances of diversity.

Of course, it may still prove possible that the same kinds of processes explain both phenomena, the origin of life, and its subsequent diversification. But there is no reason to assume, a priori, that this is true, and in fact it is the position of almost all scientists who tackle these two problems that it is almost certainly not true, or at least not true for the most part though there may be some overlap in some places.

What is true, however, is that we are given a choice, right here and now, at the start of our trek toward understanding. As in Robert Frost’s poem, we are presented a choice of two roads to walk upon, both of which seem equally enticing:
 


Two roads diverged in a yellow wood,


And sorry I could not travel both

And be one traveler, long I stood

And looked down one as far as I could

To where it bent in the undergrowth;



Then took the other, as just as fair,

And having perhaps the better claim,

Because it was grassy and wanted wear;

Though as for that the passing there

Had worn them really about the same,



And both that morning equally lay

In leaves no step had trodden black.

Oh, I kept the first for another day!

Yet knowing how way leads on to way,

I doubted if I should ever come back.



I shall be telling this with a sigh

Somewhere ages and ages hence:

Two roads diverged in a wood, and I—

I took the one less traveled by

And that has made all the difference.


Unlike Frost’s poem, the two roads we are faced with look very unequal even before we take the first step on either of them. Again, beginning with our vantage point at the start of the twenty-first century, we can say that one of these roads really is well-worn, although there do remain many thickets and tangles and vines and thorns to be waded through; while the other, superficially the more straightforward of the two, is actually much more mired in undergrowth and mystery, one on which many faltering first steps have been made or attempted still with no clear path in sight. That seemingly-clearer road is the problem of the origins of life; a surprise only as long as we overlook the one, real, overwhelming obstacle in our path: which is that, however it happened, it did so either billions of years ago on this planet, or trillions of miles away on other possible worlds as discussed in chapter two, and then transported here; either of which leaves us exceedingly short of useful data upon which we can build testable theories. Both of which leave us prey to the purveyors of miracles, a shortage of which is seemingly never found; as long as, however, we forget that if miracles are answers, then science would never have explained anything, and curiosity and imagination would be pointless. Even if we do never solve some particular problem, this is no cause for capitulation; we are, after all, mere human beings with human abilities, and it shouldn’t surprise anyone that some questions remain forever unanswered, no matter how much of those abilities are applied to them for how long. It is quite possible that the origin of life, or its different possible origins, remains a nut we never quite crack. Disappointing as that would be, it is no cause for dismay or futility or some kind of existential malaise; besides which, we will no doubt discover many amazing things in our endeavors to solve this problem. Indeed, this has already happened, with examples of amazing self-organizing complexity in various chemical systems being the most obvious examples. This is actually one of the most amazing things about science, at least as I have experienced it: that our attempts to hammer out a solution to one problem ends up leading us completely unexpected paths, stumbling upon unknown veins of gold.
* * *

The problem of the origin(s) of life is a fascinating and of course commanding one, one in which many books can and have been written on and which careers have been dedicated to. However, I have deliberately chosen to leave it out of this book because meandering down so long a path with so many thickets and brambles is likely to end up with ourselves just scratching ourselves all over, and mending and binding the many wounds which we will receive, with no clear end in sight as our reward. Actually, even Darwin himself knew this. In all his tomes on evolution, he persistently avoids and evades the question of life’s origins, leaving it in backwaters to be treaded by the minds that were to come after him. If possible, he doesn’t even mention or allude to it. He had the foresight and, in our hindsight, the wisdom, to know that mucking around in those waters would only muddy the tale he was bent on weaving, a tale with enough problems of its own. Fittingly, it is a problem he only alights upon to let us know that he too will have nothing of the supernatural in solving it. Just as Newton was wise enough to know to let the cause of the gravity he so deftly described be a problem left to his successors, so Darwin also avoids this slippery trap and leaves the question of origins to minds to come after him.
There is one last point I would like to make here. It was well accepted by the late eighteen hundreds that one of the most important characteristics of livings things today is that all of them had parents, of one form or another. That fact, so obvious to us now, was finally nailed down by Louis Pasteur in a series of famous experiments, thereby separating the problem of biology into its two great sub-problems, its origins and its subsequent evolution. What Pasteur showed was that wherever even the simplest of living things came from, whether they be mice or maggots, they didn’t just burst into existence out of inorganic or simple organic beginnings. No, all of them, without exception, were begat in some manner; moms and dads, or at least a parent of some sort, were involved, even if no one knew in any detail how the begetting was done. You could breed billions of bacteria from one bacterium, but not a one from zero, however hard you tried. That clear and indisputable truth was a beginning into everything the twentieth century contributed about the fundamentals of biology: Everything comes from something, nothing comes from nothing. At least not on this planet, at this point in its history.

* * *

It would appear that we at least have a beginning here in our wonderings about ourselves, about life, that we can summarize. A quartet of beginnings, actually. First is that it displays levels of complexity, organization, and seeming purpose which would appear to defy explanation. Second, at its most fundamental level, life and its origins are based on nothing more than physics and chemistry, most crucially on the amazing properties of that amazing element carbon, although a plethora of other elements play essential roles as well. In addition, we and our ancestors all share a common biochemistry, a biochemistry built on DNA, proteins, and so forth, and have certainly done so going back a good three billion plus years in Earth’s history.
The third beginning is an inevitable consequence of the first two, that of procreation being the only way nature has now of producing new organisms, from bacteria to human beings, that living things are simply too complicated and organized to assemble by chance. Not only that, but offspring resemble their parent(s) (although, of course this is not always immediately obvious, as we all know from the example of a caterpillar hatching from a butterfly’s egg), a resemblance which will be passed on to future generations, albeit with occasional mutations.
As for the fourth beginning, evolution, that it occurs and has been occurring for a vastly long time, that it explains the many forms and functions and niches life has found on our world, and that, most importantly, we possess the fundamental understanding of how and why it occurs, underlays biology just as physics underlays chemistry and mathematics underlays physics. Furthermore, just as our third beginning derived from its predecessors, the fourth emerges inevitably from the third. It is the beginning that took two English naturalists, Charles Darwin and Alfred Russell Wallace, and these Victorian gentlemen’s elegant and brilliant reasoning which derive from the observation of two natural phenomena: the inheritance of physical and behavioral traits from parent to offspring, and competition for scarce resources among those offspring to survive and repeat the process: natural selection. What to me makes their accomplishments all the more remarkable is that how heredity works was something neither man had a clear concept of (even though this was the same time that Gregor Mendel was doing his experiments with peas which would have helped both of them immensely – experiments which remained in obscurity until the early 1900s); indeed, some of Darwin’s concepts in this field actually made his theory harder to defend. Still, they convinced the scientific establishment of their day within a short period of time.

* * *

It is natural selection and random mutation that have conspired together over millions of years to wire our brains into the relentless curious, pattern hunting, story weaving machines I spoke of in chapter one. This unconscious conspiracy has been so successful that we imagine that we see people and animals among the stars and, if like most of us who have ever lived do not know better, believe tales of how they came to be there. It is also of course one of the main wellsprings of all art and literature, from the Mona Lisa and War and Peace to the Campbell’s soup label and idle gossip. It is, ironically, the reason that I used the word conspiracy and all it implies without a second thought, and probably the reason you may not have questioned my doing so.
The obvious downside to this marvelous, compelling faculty of our brains is that the patterns and stories are often unsuspicious products of it. When this happens, then they, like magic, only sidetrack and mislead us too, perhaps disastrously so. In fact, neither our brains nor the rest of our bodies are the culmination of any kind of conspiracy, but only one of many possible, logical outcomes of nature’s blind laws.
So we tread carefully when we look at the universe about and within us and try to make sense of its workings and history. Each step has the potential to take us either into deeper understanding or shallower error. If we place too much trust in this part of what nature has wired into us, we seriously risk the latter. We must always be prepared to pull back to reexamine what we think we see, to be skeptical, to consider other possibilities, and to use another gift we have been given by those same blind laws, that of our ability to reason. If we tread the path carefully enough, our prospects for success, I believe, are promising.
Why do I begin a discussion of evolution this way? The best answer I can offer is to return to the beginning of this chapter: “One of themes of this book is that if we are to satisfy our curiosity about the universe around us, we will need to use our imaginations, because the universe as we perceive it simply doesn’t get us very far.”
Yet imagination stripped of pattern seeking and story telling would be a moribund faculty of our minds, if indeed our minds could have it at all. It surely would be nowhere close to the task of fleshing out and filling in our understanding of things. Not that it would it matter though for our curiosity would be almost severely crippled as well, probably to no more than an animal instinct serving few goals greater than finding food and mates and avoiding predators.
Nowhere is this shown better than in the work on the structure and workings of the DNA molecule, the beating heart of heredity, a heart that, perhaps more than anything else science has discovered before or since, would never have been found without that combination of imagination, pattern seeking and story telling, skepticism, and reason which make us such unique organisms that we may indeed be alone (although I hope not) in the universe.
As with so many other parts of my scientific education, I was first exposed to DNA and its workings one of the Time-Life books (or maybe it was one of Isaac Asimov’s many books on science). I was then too young to understand it in much detail, but I do recall being profoundly impressed with how important it was to all life on this planet, and at least the rudiments of why. The deeper comprehension was something that has taken a fair part of my life to even begin to grasp, and even today I know that comprehension is nowhere near as deep as it could be – not that I feel embarrassed or ashamed about that for even the most brilliant minds in the world have spent both this and a large part of the last century yet still have many mysteries arrayed against them.

* * *

I cannot resist a recapitulation here. It has been almost six months since I took the stroll through Pennypack Park I described earlier in this chapter, but right now, thinking of these issues, I find myself irresistibly drawn back to that day. Doing so, I find that my senses are as enthralled now as they were then. Once again I see and hear and smell the many living things surrounding me, almost making me feel as though I have been transported to some kind of paradise. For here I am, surrounded by the oaks and the maples and the sycamores and occasional pine trees, and admittedly many others I do not recognize. The branches and twigs of bushes, both low and high, brush against my body, and my shoes swish over the uncut grass. Birds circle in the air, dart between the trees, then settle on their branches and study the world around them. If I close my eyes, not only do I hear their many languages, I am greeted by a cacophony of other noises: insects of all kinds, the rustling of just opening leaves in the spring breeze, the splashing of fish breaking the surface of the still cold water, the dabbling and occasional quacking of ducks, the distant, patient calls of bull frogs toward potential mates, the scratching of squirrels racing up and down the trees, and others which I cannot with any certainty place or, to be honest, remember now. I am also of course aware of the humans around me and their myriad tongues with their myriad emotions and hopes, not to mention the clopping of those fortunate enough to be riding horses. Dogs bark from time to time, also reminding me of our presence. Opening my eyes again, I look for the other, more silent or better concealed creatures I know to be about, from mice and ground hogs and snakes, to ones like skunks, raccoons, opossums, and others that only come out at night. I see no deer, but don’t doubt they are about, that it is only a matter of time and attention. Stroking my fingers on a stone wall I feel the velvet of new moss against my fingertips. It is too early for mushrooms and most other fungi, but they too hide in dark places, waiting for warmer weather and longer days to coax them out. The insects I heard swirl around me now, and spiders lurk in cracks in the stone walls or hang from fresh webs, waiting for victims. Taking it all in, it is difficult to imagine how nature could have been more creative in her choice of forms and functions for her productions. Humans have nowhere near such power, and perhaps never will.
Yet I have only just brushed up against the most amazing thing about all this splendor. Which is that, were we to take samples of all of it, and place it under an instrument powerful enough to see that deeply into the structure of life, they would all reveal the spirals of DNA at the very core of their beings, spirals which account for that amazing creativity. In no case would the spirals be exactly the same – they would differ in their lengths and, in most places, their specific nucleotide sequences – but the similarities would vastly outweigh the differences in even the most distantly related organisms. Walking through the park, we are inescapably aware of the diversity which infinitely impresses us, yet it is only when we look closer, much closer, do we see – probably the most profound paradox of life on this world – the foundation which is shared by all of it.
Which is why of course I began by speaking of patterns and stories, and the double-edged sword in our minds which compels us to see and create them. If you will recall the beginning of this chapter, I dared the reader to define what life actually is, and gave some examples of how our forebears answered it. The important point about our forebears is that the answers they did come up, as persuasive as they were to them, could not have been more mistaken. The patterns they perceived in life, and the stories they told to explain them and their origins, however compelling and reasonable they seemed at the time, have turned out to be wrong, dead wrong, in retrospect absurdly wrong. What accounts for all living things is the laws of physics and chemistry, working within the forces of evolution by natural selection.
But if we stop there we fail to appreciate the power of the other edge of the sword. The discovery of DNA and the other molecules of heredity, the probing into and teasing out how they work, would not have been possible without our ability and willingness to use this edge as well as all the other facets of imagination, in combination with the hardest of scientific acumen. For what pattern in nature could be more arresting than the DNA spiral? And what story could be more captivating than the story that led to its discovery and unraveling – except, perhaps, the story that DNA, and the millions of years it has been evolving in so many directions, itself tells?

* * *

We take it as common knowledge today that DNA (or, in some cases, its brother molecule RNA) forms the hereditary basis for almost all living things on this planet, but Darwin and Wallace died long before it was discovered. Yet neither man could have failed to grasp the power of this one molecule to fulfill its dual responsibilities as the instruction set for both developing biological things and maintaining so many of their essential functions. They would no doubt have been equally impressed – no, elated – with its additional ability to create new information via mutation, information to be tested in the living, breathing, real world of life and death. Natural selection could not have a greater ally.
I have been emphasizing the almost incomprehensible complexity of living things, but in describing DNA we are surprisingly impressed, at least at first sight, by its simplicity. The simplicity is such that Crick and Watson, who revealed its structure to the world a little over fifty years ago (without, alas, giving Rosalind Franklin her due credit), were able to deduce how it replicates itself – something it must do every time a cell divides – without a single additional observation or experiment to back their deduction up (although they were rather cagey in how they mentioned it in their paper). And although there are still much research to be done, we have since that time been able to elucidate what DNA does and how it does it with impressive detail.
Simplicity does not mean lack of sophistication, however. DNA, comprised of two strands of sugar phosphate backbones, twirled together and held that way by pairs of small, interlocking “base pair” molecules, may not sound promising as genetic material; it would probably not even be the first choice of an engineer looking for an efficient molecule for storing information. But remember the discussion earlier of the power of the carbon atom to assemble stable molecules of very large size. As large as, for example, the Hope diamond. The DNA contained in chromosome one of the forty-six chromosomes of a single cell of your body would, if teased out to its full length, be approximately three inches long and contain over two hundred million base pairs (I can’t resist the calculation that if all the DNA in all our cells were laid end to end, they would stretch from here to the moon and back some twelve thousand times!). Given that the four bases can have any potential sequence, yielding 4200000000 or over 10100000000 possible arrangements in just that one chromosome, perhaps our engineer should take a second look. Incidentally, don’t try: that is a number no amount of imagination will make real in your mind; even all the atoms in the entire known universe only sum up to less than a paltry 1080.
Actually, on third thought, if anything we seem to be dealing with such an overkill of information storage capacity that we wonder why nature chose to employ DNA at all. Would wonder, that is, if nature truly were an intelligent engineer that could choose anything.
So DNA, its deceptive initial simplicity aside, is easily – way easily – more than up to the task of encoding all the information needed to create and maintain not only ourselves, but also any living organism we can conceive of, however strange and wondrous; more than all the organisms that have ever lived on this planet, or might live in the future. Or that might have or will live anywhere else in our universe, assuming they use DNA as their genetic code. Or in a billion billion universes (if they exist) spanning a billion billion years.
Information … but of what nature? And how is it encoded in the DNA spiral? And how does our biological machinery and processes extract it, and turn it into the raw material of our beings? And how has it allowed the combination of random mutation and natural selection to drive life from its simplest beginnings over three billion years ago to the incredible diversity of much more complex forms, including ourselves, that we see today – a diversity my walk through Pennypack Park only revealed only the tiniest fraction of?
It is time to talk about protein.

* * *

Here is a subject we are all at least somewhat familiar with. Who doesn’t remember as a child being cajoled, coaxed, and badgered into making sure we ate enough protein to grow strong and tall? Go into any health food store and you will find rows of large containers of protein supplements, each promising to build stronger muscles in absurdly short times.
Proteins are large organic molecules (though nowhere near as large as DNA) which, when we consume them, are broken down by digestive processes into small molecular units called amino acids. There are some twenty kinds of amino acids in living things, and different combinations and numbers of them link together to make all the proteins nature produces. Having broken down the proteins we eat, we then reassemble the freed amino acids to construct the many new different proteins our own bodies need. And our bodies need them for many different purposes.
What makes proteins so important and so versatile is the fact that they are not merely random strings of amino acids, like glass beads on a thread. Instead, because of the intramolecular forces in them, they coil, wrap around each other, form plate-like structures, and then fold up into specific, detailed shapes which are determined by their specific sequences. That is why the glutinous, translucent “white” of an egg becomes firm and truly white when we cook it, for heat, as well as other physical and chemical assaults, unravels the globular shape of the albumin proteins and make them lay flat against each other.
The myriad sizes and shapes of proteins are employed by bodies to perform all kinds of functions. For example, proteins studding the surface of a cell control the rate at which water and other molecules and ions (electrically charged atoms and molecules) enter and leave. They are employed in such diverse roles as construction material for hair and nails and cartilage, and as essential components of important biological molecules such as the hemoglobin in your blood, which carries oxygen from your lungs to every cell in your body and carries away the carbon dioxide waste to be exhaled. Numerous different types are critical to cell metabolism, in particular those that serve as enzymes, which catalyze chemical reactions in your cells to produce other important molecules. The elasticity of proteins in muscle cells allow those cells to expand and contract, allowing your heart to beat and you to use your arms and legs. They are also important in cell signaling and the proper functioning of your immune system. Your parents were indeed wise to exhort you to get enough of them in your diet, even if they did not know why.
Curiosity ought to be provoking a question in your mind right about now. Digestion breaks down the proteins we eat into their component amino acids. The amino acids are then transported by the blood to all the cells in the body. It is in our cells that all the proteins we need are constructed. Yet proteins contain from hundreds to tens of thousands of amino acids, all joined together in the specified orders they require to perform their functions. The greatest engineer in the world would be running out of his factory screaming if handed a task this monumental. How do our cells handle it with such aplomb?
The molecular machinery which assembles proteins in the cell is a subject which, if I were an expert on it, I could easily fill the rest of this chapter and more describing. Fortunately, I’m not an expert on that particular topic, which means I can segue back to DNA without further ado. The point in this discussion on proteins is that DNA is the template which is used to build them. A gene is a section of DNA serving as the template for a specific protein. More specifically, the sequence of DNA bases determine the sequence of amino acids, the correspondence between base and amino acid being three to one: each amino acid corresponds to, is encoded by, three nucleotide bases in succession. As there are four such bases, this gives us 4 × 4 × 4 = 64 possible amino acids we could code for, well more than the twenty that are actually used in nature.
Actually, this is worth elaborating on to some detail, due to another digression I feel is worth making. If we represent the four nucleotide bases in DNA, adenine, thymine, guanine, and cytosine, by their initial letters, A, T, G, and C, we find that we have an excellent “quaternary” coding system to work with. I use the word quaternary here in the same way the word “binary” is used when discussing computer code. When you run your favorite computer program, or even much less than favorite program, the code your computer is executing is essentially nothing more than a series of (electronic) 0s and 1s. This series of 0s and 1s tell the computer’s processing chip(s) and all the associated electronics and other gizmos what to do (some of which you saw in chapter two); bear in mind that with enough 0s and 1s we can create a computer program as sophisticated as we like; if my understanding of computer science is correct, given enough 0s and 1s we could create a program that simulated the entire universe and its history, though whether this universe includes the program and the computer it is running on is still unclear to me.
The three to one correspondence between bases and amino acids modifies the coding system of DNA but does not alter the analogy with computer programming code, an analogy I would like to continue with. It means that if we were to read the amino acid sequence of a section of DNA by “unzipping” it and looking at the base sequence, instead of looking at it one base at a time we would have to read it in groups of three: e. g., TTA, CAG, CTG, GCA, and so on, each group of three coding for one acid. As noted, that is well more than enough for the twenty amino acids nature uses in living things.
Computer programming. Like one of the individuals who have inspired this book, I too have had considerable experience in the field and so too am drawn to the comparison of DNA to programming code. It is a powerful and compelling comparison – the idea of DNA as digital information, to be molded in any direction the blind but non-random forces of evolution wield – has, for me at least, as much appeal to imagination and useful insight as any other idea in biology over the last quarter century or so. Now, with the digital age fully upon us, the comparison, or analogy, is even more forceful to the mind. Personally, as a (very) part-time science fiction writer it conjures up images of artificial living beings, of synthetic organs and tissues to prolong our lives, perhaps indefinitely, of expanding the already impressive capacities of our brains with biochips, and even such cybernetic ideas as an Internet composed of human minds directly connected to and communicating with each other and with sentient computers. Given that I honestly expect to see some of this happen at least in my lifetime not to mention my children’s, the digital view of biology is perhaps too seductive.

* * *

After everything I have said about imagination and our need to use it to answer our questions about ourselves and our universe, the word seductive alone ought to suggest I am about to pull back, at least somewhat. So I am. Not that I don’t truly believe that many if not all of the above mentioned wonders of coming technology will happen someday. But the emphasis on the digital nature of DNA can potentially mislead us as well as inform.
The reason for this is that our digital DNA codes, serves as a template for, the highly analog proteins that are the actual machinery of our bodies. By analog I simply mean the opposite of digital: continuous in change as opposed to changing in discrete steps. (A hopefully not too outdated example of the difference would be the analog dial on old radio sets which, as you turned it, changed the tuning of the receiver continuously from one frequency to another, as opposed to digital push-button radios today which jump instantly to a specific frequency.) In calling proteins analog, I do not mean the sequence of amino acids which comprise them; that is still as digital as DNA in that an amino acid change in the sequence is discrete – you can’t continuously change between one acid and another.
Hang on, for I am getting to the reason for this digression. It is true that the amino acid sequence in a protein is digital, but what matters for proteins, what they do and how they work, is largely their specific size and shape, qualities that usually can be varied more or less continuously by changes in the amino acid sequence which comprises them. That is, if we replace one amino acid in a protein consisting of hundreds or thousands with another, the most likely outcome is a small, perhaps even insignificant, change in its shape – resulting in a proportionately tiny change in how the protein does its job. For example, if the protein is an enzyme, a slight change in its shape would cause the rate at which it catalyzes its specific reaction to be somewhat faster or slower. Or if the protein controls the rate at which a certain molecule or ion enters or leaves cells, that could be modified slightly. Furthermore, additional amino acid changes are likely to lead to similar small, cumulative changes in the protein’s function.
Small, cumulative changes. We are practically talking about the heart and soul of Darwinian evolution. But what would cause these single amino acid changes in a protein’s make-up? Recall that it is a particular sequence of three consecutive nucleotide bases on DNA which correspond to the amino acid at a particular location in a protein. Any number of agents have the potential to alter, or “mutate” a base in DNA: radiation and various kinds of chemical assaults. Such mutations (there are others) even has a name: point mutations. Point mutations are surprisingly common. Most are caught and corrected by molecular machinery in the cell designed for the purpose, but they occasionally slip through the defenses. In doing so they can lead to the amino acid changes in proteins which often (not always: sickle-cell anemia is caused by just such a single change on one of the globin proteins in hemoglobin) cause those proteins’ functioning to alter slightly, causing somewhat higher or lower production of another chemical or modifying cell membrane permeability to a molecule / ion, leading to … well, for example, if the protein is involved in embryological development, a modest change in the physiology or behavior of the organism. The point is, when talking about natural selection, modest changes, such as those that lead to slightly longer or shorter legs, have a better chance of being advantageous than large changes, which are almost certain to be disastrous. And given that changes can accumulate over geological time, constantly being molded and “directed” by natural selection, I hope it is by now clear that the entire edifice of DNA / proteins / form and function, though completely unknown in Darwin’s and Wallace’s time, could hardly have been better tailored to the revolutionary ideas they unleashed upon the world.

* * *

Wondering about ourselves is, of course, an endeavor that never ends, and no such pretense will be made here. On the contrary, the territory covered in this chapter is only a tiny fraction of the vast subject of life, what it is and how it has come to be. Alas, curiosity demands more, far more much more, than I could hope to deliver even in an entire book, assuming I was well versed enough in the subject for such an undertaking. But I do hope that certain basics about life, in general, have been laid down: its utterly improbable complexity, seeming design and purposefulness (what I have called intentionality); the underlying chemistry, particularly of carbon, that makes it possible (on our planet); the continuity, in that all living organisms are in some way descended from a parent or parents, going back to the beginnings of life on Earth some three and a half or more billion years ago; the basics of Darwinian / Wallician evolution, which explains how life today came from its much simpler beginnings; and the interworkings of the tapestry of DNA with the working machinery of proteins which are essential to both life’s functioning and its evolution. I hope you feel that we have not made a bad start.
But there is another aspect to our self exploration, one that can’t be, and won’t be, ignored. That is our wondering about ourselves as individuals. How is it, each of us asks at least from time to time, that I came to be; what and why am I; what is my place and destiny, if any, in the scheme of things, whatever that scheme is assuming; what does it mean to be human and what else could I have been? The reason I have excluded this aspect from this chapter is that the sciences that answer it, if any, are necessarily more speculative, to the point where it is questionable in many cases to call them sciences at all. But that doesn’t stop our asking the questions. It doesn’t quench our curiosity, or make it go away. And we can still use our imaginations – gingerly, for we tread on unknown territories – in our quest to come up with answers that just might make some degree of sense. Or so we hope.



 
 

 
 

 
 

 

How Unconscious Thought and Perception Affect Our Every Waking Moment: Scientific American

How Unconscious Thought and Perception Affect Our Every Waking Moment: Scientific American


Cover Image: January 2014 Scientific American Magazine

How Unconscious Thought and Perception Affect Our Every Waking Moment [Preview]

Unconscious impulses and desires impel what we think and do in ways Freud never dreamed of


In Brief
  • Decision making often occurs without people giving much conscious thought to how they vote, what they buy, where they go on vacation or the way they negotiate a myriad of other life choices.
  • Unconscious processes underlie the way we deliberate and plan our lives—and for good reason. Automatic judgments, for one, are essential for dodging an oncoming car or bus.
  • Behaviors governed by the unconscious go beyond looking both ways at the corner. Embedded attitudes below the level of awareness shape many of our attitudes toward others.
  • Sigmund Freud meditated on the meaning of the unconscious throughout his career. These newer studies provide a more pragmatic perspective on how we relate to a boss or spouse.
 

When psychologists try to understand the way our mind works, they frequently come to a conclusion that may seem startling: people often make decisions without having given them much thought—or, more precisely, before they have thought about them consciously. When we decide how to vote, what to buy, where to go on vacation and myriad other things, unconscious thoughts that we are not even aware of typically play a big role. Research has recently brought to light just how profoundly our unconscious mind shapes our day-to-day interactions.

One of the best-known studies to illustrate the power of the unconscious focused on the process of deciding whether a candidate was fit to hold public office. A group of mock voters were given a split second to inspect portrait photographs from the Internet of U.S. gubernatorial and senatorial candidates from states other than where the voters lived. Then, based on their fleeting glimpses of each portrait, they were asked to judge the candidates. Remarkably, the straw poll served as an accurate proxy for the later choices of actual voters in those states. Competency ratings based on seeing the candidates' faces for less time than it takes to blink an eye predicted the outcome of two out of three elections.
 

A Panoply of Elements

On the Nature of Substances

Look around you. I do not know about your environment, but I can describe mine in considerable detail; actually, in more detail than you would probably be willing to slog your way even if I were to write it down. A computer, a lamp, a desk, television … the objects in my environment are (at the moment) pretty mundane, or so they seem at first sight. I’ll bet that your environment is much the same way. Instead of focusing on the objects in our environments however, consider instead the substances they are composed of. These substances too are quite likely fairly common, and chances are there is a great overlap between your environment and mine. Wood, glass, living flesh, plastic, metal, paint, cardboard … or, if you are outside, plant and animal life, clouds, sunlight (or starlight or moonlight), dirt, rock, air, water … the list would appear to go on and on, with no end in sight.

 Or would it? This is an interesting point to ponder. There could be an infinite number of substances that things are composed of; or there could be a limited number, perhaps even a rather small number, of basic substances that combine in innumerable, different ways to make up the objects in our lives and in our universe.

The latter option – a limited number of basic substances of which everything is composed – seems preferable, if only because it makes figuring out the world around us a much simpler task. And indeed, there appears to be good evidence that this is so. Take the substance water, for example: we find it in all kinds of things, from milk to soda pop to our own bodies, to the great oceans of our home planet and even elsewhere in the universe. Reflecting on it, water is found in a great variety of things. Perhaps this means that water is one of these basic, or fundamental, substances, that we are trying to classify.

 Taking stock of things, we notice that water is not the only possibly basic substance. What about air? Although it is invisible, we are constantly aware of the existence of air merely by the act of breathing it in and out, or feeling a breeze on our face, or by watching it make the leaves of a tree rustle and sway as we walk through a park on a spring day. Noticing all this, we might want to classify air as one of our fundamental substances too, just like water.

 What about the earth beneath our feet? If we dig our fingers into the soil and pull some of it up, we see that earth is a substance as well. A fundamental substance? Well, we do find that it is almost always there, wherever we go, although it is not always of the same quality. Sometimes our digging will pull up sand, or rock, or clay, materials of different color and hardness and other attributes. Yet all of these things may simply be variations on the main theme, that of earth. So we will, at least for the time being, call earth a fundamental substance, adding it to water and air.

 Clearly, there are many directions we can take in all this classifying of substances. What about fire? This is a very interesting substance, one reason being because it can turn one substance into another. For example, it can boil the substance water, converting into the substance air, or what we call steam. It can also, when quite hot, be used extract metals like copper and tin and iron from certain rocks, which is how we have most of these materials. Quite an amazing substance, isn’t this fire? Perhaps we should list it among our fundamental substances too.

 Let us stop here and recapitulate our findings. We have selected four substances, water, air, earth, and fire, and labeled them as fundamental substances. Before we proceed, I would like to introduce another term for fundamental substances. The term I am proposing is elements. An element is a fundamental substance in the sense that it cannot be broken down into, or reduced to, other elements. Each element stands on its own, composed of nothing but itself. If this is true, then all substances and objects that we perceive in the world are a combination, in one form or another, of these four elements we have identified.

 Using this kind of analysis, we seem to have made some progress in understanding the world around us. We have reduced all things into a combination of four elements. If indeed, this is how the world works, we are very fortunate to have stumbled upon its basic constitution. Using the right combination of the four elements, perhaps tempered in the right way by the element fire, we should be able to create any object or substance we desire, from gold and diamonds, to modern computers and all the other electronics which have made the Information Age possible. Amazing!

The question is, are our elements truly elements by our definition – fundamental substances which themselves cannot be broken down or reduced to any other elements? If not, then our quest is not finished. Furthermore, how can we make the determination whether they are or aren’t, and if not, what are these elements that we seek?

 For an example, let us take our earth element, weigh it carefully in some kind of container such as a flask, and mix it with our water element, also carefully weighed in another flask, and stir the resulting mixture very thoroughly so that they are as completely blended together as possible. We then take this mixture, which we all recognize from our childhoods as plain old mud, and pass it through a filter, collecting the resulting filtrate, which is the liquid that passes through the filter, in yet a third flask; preferably we use a scientific filter designed for such purposes but a simple coffee filter should be very effective as well. If the filter is good enough, meaning if the holes are small enough only to pass the water plus anything dissolved (this is a suggestive concept in and of itself) in the water and not the entire mixture, something very interesting will happen. We will notice that the residue that remains behind in the filter after all the water has passed through it probably looks essentially the same as the earth we originally placed in its flask, with the exception that this residue is wet, or muddy, looking; while the watery filtrate, at the bottom of the flask we collected it in also still resembles ordinary water, though it too maybe somewhat colored, probably a color much like our muddied earth.

Now here is the interesting part. If we take the water filtrate out of its flask and set it in the sun, or heat it over a kitchen stove – it’s amazing how much science you can do in a kitchen – unlike plain ordinary water once all the water has been evaporated there will be a remaining dry sediment left behind. Or at least I will bet there will be. This sediment might be white, or one of a number of different colors, or even the same brown or other hue like the earth it was extracted from.

 Wait a minute, you say. Extracted? What exactly does that mean? How do I know that? Thinking about this, it would seem to be that, at the very least, we have separated the earth into at least two simpler substances: the filtrate, which passed through the filter, and whatever remains in the filter. But how can that be if earth itself truly is an element? By our definition of the word element, it can’t be.

 There is something else highly suggestive about this experiment, which is the concept of filtration. The whole idea of a filter is that it presents a solid barrier with very small holes, or perhaps passages is the better term, in it which allow particles smaller than the passage to go through, while blocking all larger particles. What’s suggestive is that the earth + water mixture, or mud, is composed of small particles of varying size, such that they can be separated by filtration. This whole idea, the particulate concept of matter, is of course not at all surprising to us because this is the twenty-first century and we all know about atoms, but what I want to emphasize is that the idea of atoms is not as obvious as it might seem. It only seems obvious to us because we have gone to school where we were taught the atomic theory of matter; but if we hadn’t been so taught, or indoctrinated is perhaps the better term, then like most people throughout history and even today we wouldn’t know about atoms at all and probably wouldn’t stumble upon this explanation of filtration and how it works. I won’t mention more about this idea here, the particulate nature of matter, because I am going to return to it in force fairly soon; but I hope you can see how it relates to the idea of elements and how they answer the riddle of matter. Our experiment with filtering earth + water mixtures gives us a small window of insight into this powerful idea.

 There is a great deal more to our filtration experiment and how it might be interpreted. For example, in addition to the process of separation, maybe what I am looking at is a result of a reaction between the two original elements, earth and water, when I mixed them together. The filtrate, as well the residue in the filter, may very well be the result of such a reaction. How can I determine the difference among the various possibilities?

 One way of going about this would be to weigh the original earth, the dried residue in the filter, and the dried filtrate in its flask, and add the various weights together. When we do this, and assuming that we have been very accurate and precise in our weighings, we discover that, as if magic ran the universe instead of blind physical laws – no, actually the reverse – the combined weights exactly equal the weight of the original earth we started out with. This is very revealing, for if there had been a reaction with the water, that would have increased the weight by the amount of water consumed, or perhaps decreased by some fraction perhaps. But this has not happened. To clinch the issue, if instead of allowing it to go free we have instead been diligently collecting all the evaporated water during our experiment and weigh it with the remaining liquid form, again we are chagrined – well, perhaps not too chagrined by now – to find that it too matches the mass of the original water.

 Even so, having done all these additional measurements turn out we can be certain that we have taken one of our original elements, earth, and broken it down it into at least two new substances, one that passed through the filter and one that does not. That being so, we can hardly call earth an element any longer! And yet, contemplate this fact: should this really surprise us? After all, we never did have good reason for saying earth was an element in the first place. We just assumed it because earth is so ubiquitous that it seemed reasonable to call it an element; we followed common sense and our intuitions instead of investigating nature closely and clearly and methodically, as science teaches us we must do. So perhaps, in retrospect, we shouldn’t be surprised at all.

 The next question is, how about the water? Unfortunately, this turns out to be a little trickier. It was certainly not separated into different substances by the filter, so at first sight we might be justified in calling it one of the elements we are searching for. In fact, water passes a lot of tests to determine elementhood, and so it is easy to conclude that it is an element. But there is a very well known experiment that will show elsewise: the electrolysis of water. This experiment is not as easy to set up as the filtration experiment, and we require some special materials and equipment. But it is still not that complicated. What is needed is two glass test tubes, filled with water and connected near their tops – their open ends – by a glass tube or corridor. At the very top of each tube is a water tight cork or rubber stopper, through which has been inserted an electrode of platinum or other suitably chemically inert, electrically conducting, metal (even graphite, a form of carbon that conducts electricity, can be used). The connected tubes are filled with water – this of course is done before the electrode containing stoppers have been inserted. It is critical, for reasons I won’t go into right now but are also suggestive, that the water be slightly salty, or into which some other substance which helps its electrical conductivity has been dissolved. The entire apparatus is then turned upside down. The wires now coming down from the electrodes / bottoms of the stoppers are then connected to a source of direct current electricity, usually a battery or a set of batteries wired in series, one that can provide sufficient current and voltage. The final apparatus looks like this:
 
 
 
 Here the “tops” (remember are actually the bottoms) of the test tubes also have tubular holes in them, and collection balloons have been placed, tightly, around the holes. When the wires from the electrodes are connected to the anode and cathode of the battery, something very interesting starts to happen at the surfaces of the electrodes, also shown in the drawing. Bubbles of gas start to form around them, bubbles which, when they have grown large enough to break their adherence to the electrode, rise up and collect in the balloons. This process continues as long as the water level is high enough to reach the electrodes and the connecting tube. At this point the gasses stop forming.

 At the end of the experiment, we weigh the collected gasses (again, not an easy thing to do), and the remaining water, and again we find that the summed weights equal the original weight of water placed in the apparatus. This is because we have taken our “element” water and broken it down into two new substances, which I will now admit are the gasses hydrogen and oxygen. Oh, and incidentally, if you mix the hydrogen and oxygen and burn them together, the product is … one guess … that’s right, water. Voila! Water is no more an element than earth.

 Air suffers the same fate. If we take a weighed volume of air and burn a weighed quantity of something – anything flammable, say paper – in it, we find that after the burning that the air has gained some weight while the burned material has not only changed appearance but is also now lighter, by exactly the same weight; that is, the air plus paper is the same weight after the burning as before. Something in the paper has been transferred to the air somehow.

 Not only thus, but if you liquefy air, again not an easy process, you find you can distill – that is, boil out fractions at different temperatures – from it a number of separate liquefied gasses, mostly nitrogen and oxygen, with a little argon and other gasses.

 So air is not an element either. As is neither water, or earth. As for fire, how can something that appears and then vanishes, into thin air one might say, be an element? It isn’t even clear that fire can be called a substance; or if so, it is certainly a very mysterious one.

 After all this discussion, we seem to have come full circle with the most fundamental question: just what, precisely, is an element, and how do we determine it?

 One part of our definition is that it is a substance that cannot be broken down into other substances by ordinary physical or chemical means. If you take a chunk of gold, for example, no matter how you heat it, combine it with other materials, chop it up, or otherwise afflict it, you cannot reduce it to anything simpler. You can make more complicated substances from it, like the various alloys and compounds of gold, but not something simpler. All of this is not obvious, of course. It requires a great deal of careful experimentation to show that it is true. But chemists have been working with gold long enough that they can call it an element with great confidence. Of course, that’s the way science usually works; a lot of time and people and material, and many, many experiments done over many years by people just to come to a firm conclusion. And even then we are not absolutely certain beyond any doubt, just adequately sure beyond any reasonable ones.

 I said that an element cannot be reduced to simpler substances by ordinary physical or chemical means. By that I meant we could heat it, freeze it, mix it with other substances (and then heat or freeze it) – all the things chemists do in their laboratories – and though you might yield materials with interesting properties, the gold or other elements it contains can still be extracted; the processes we put it through have not transformed it. Using other physical and/or chemical means we can restore the same gold, in its original condition.

 This leads me to another interesting subject, not just about gold but any physical substance: we can take a piece of it, divide that into two pieces, divide each of those pieces so that we have four, and divide again and again and again in this manner, each division yielding progressively smaller pieces of the substance. Actually, we are aware of course that we can only take this process so far; eventually we will reach a point where we cannot find a knife, or whatever we’re cutting the substance with, small enough to continue. But assuming you could, just how far can we go with this division and sub-division process? Could we go on forever? What exactly would happen?

 It is possible with modern scientific instruments to divide a piece of gold into many very tiny pieces. And lo and behold, each piece is still gold. But “very tiny” is a relative term. At some point, if we are somehow able to sub-divide it enough times, we may yet find gold to be composed of simpler things. Fortunately, there are ways of probing well beyond our method of divisions. But a brief discussion on the subject of radioactivity is necessary first.


Radioactivity and the Discovery of Sub-Atomic Particles

 By the end of the nineteenth century / beginning of the twentieth, a number of scientists had discovered an interesting property of certain kinds of substances. They appeared to be unstable at some very fundamental level, decomposing into other substances and emitting a variety of “rays” or radioactive emissions while doing so. The Curies, Marie and Pierre, are the most historically famous contributors in this field of work, although others were involved as well. Altogether, three main kinds of rays were initially discovered and labeled, using the first three letters in the Greek alphabet: alpha rays, beta rays, and gamma rays. Other kinds of rays were to be discovered later, but this is where the story begins. It was also not until later that the nature of these rays were determined: it turned out that alpha rays were actually particles, now known to be composed of two protons and two other particles, the latter of which we today we call neutrons; beta rays were also particles, in fact what we now know as electrons, albeit moving at high velocities from the radioactive atomic nuclei emitting them; and gamma rays were electromagnetic radiation, like light but of very high energy, even higher than X-rays, which can easily penetrate flesh and show the bones in our bodies.

 One of the interesting things about these rays, or particles, or both, are their penetrating powers. Alpha rays, although being the most massive of the three, have the least penetrating ability; a simple sheet of paper can stop (most of) them cold in their tracks. Beta rays / particles, are more penetrating and can get past your skin and well into the underlying flesh. Gamma rays are, as just noted, the most penetrating of all, even more so than X-rays. Alas, these penetrating power of the radioactive emissions and what they do to living tissues make them extremely hazardous to living organisms such as ourselves, a fact which tragically was not really recognized for several decades after their discoveries, resulting in many unnecessary terrible diseases and deaths due to the handling radioactive substances (Marie Curie, for one example, died of leukemia).

 Back to the beginning of the twentieth century. In 1911 the physicist Earnest Rutherford and his scientific team performed a remarkable experiment using alpha particles on a very thin sheet of gold, which can be beaten very thin. The sheet was so thin that they expected the alpha particles to pass through it with very few if any deflections, in much the same manner as a hard thrown baseball will go through tissue paper with virtually no resistance. I say “expected” with some reservation; if they were certain that this would happen they of course would never have bothered to do the experiment. In science you always start with some doubt or incomplete knowledge, and hope to be surprised, at least once in a while.

 Rutherford and his team were very much surprised by the results of their experiment. To their utter incredulity, although most of the particles did, as predicted, pass through the gold sheet without hindrance, a very small number of them were instead deflected; and not just deflected but by very large angles at that. It was as though, to paraphrase Rutherford’s description of the phenomenon at the time, a cannon ball had bounced off something in the gold sheet, to come straight back at the experimenter and strike him on the nose!

 Such behavior was very hard to explain unless one assumed that almost all of the mass of the gold was concentrated in a very large number of very tiny regions, regions spread throughout the sheet like raisons in a pudding. But if this were true then gold clearly is not infinitely divisible into ever smaller and smaller pieces. There is a smallest piece which may or may not be subdivisible into other things.

 My guess is that none of this really surprises you, because you live in the year 2010 and almost everyone has heard about atoms by now. What those few alpha particles were bouncing off of were the tiny but quite massive nuclei of the gold atoms, while the rest of them blasted through the extremely light electrons circling, or doing whatever electrons do, around the nuclei. In fact, Rutherford’s experiment is usually considered the proof of the basic structure of atoms. At the time it was groundbreaking work however, because only recently had the truth of the existence of atoms been established beyond a reasonable doubt by men like Einstein and J. J. Thompson (who discovered the electron), although John Dalton, a century earlier, is usually given credit for the modern version of the atom.

 All this returns us to answer the question of whether gold should be regarded as an element, in the modern chemical sense. As the protons and neutrons of the gold nucleus cannot be subdivided by an ordinary physical or chemical means, and gold is composed solely of gold atoms, the answer is a clear yes; gold is an element. But what I want to emphasize is that this answer is not at all obvious; it took many people many years and enormous amounts of work to establish this, what seems to us today so straightforward elementary school a fact that we take it for granted.

 At this point there are many more, although not necessarily easy, experiments we can do on, say, the hydrogen and oxygen generated by breaking down water, which shows these two gasses to be elements as well. We could also work on our various pieces of earth and show that they too are composed of simpler elements, such as silicon, aluminum, oxygen, iron, magnesium, and others. The nitrogen and oxygen and argon in air are also elements (though other minor gasses in it, such as water vapor and carbon dioxide, or CO2, are not). As for fire, it too is a mixture of elements, or compounds of elements, all undergoing a number of chemical reactions with each other and with oxygen in the air at high temperature, reactions which gives fire its various colors.


The Modern Conception of Elements

 I hope you are asking the next logical question in this lecture. Gold is an element; nitrogen and oxygen and hydrogen are elements; silicon and aluminum are elements; and so on. In fact, there are some ninety elements in nature, and about two dozen manmade ones as of this writing. The question is, what makes them all different from each other? And, more to the point of this book, are their differences and similarities organized in any way?

 To answer these questions, we must look at the nuclei of the atoms which compose each element, remembering that in doing so we are jumping over the enormous amount of scientific work that had to be done to establish, not only the very existence of atoms, but also the fact that they have nuclei. In doing so, we find that each element is characterized, no, defined, by the specific number of protons – relatively massive, positively charged particles – in the nucleus. Hydrogen has one proton, helium two, oxygen eight, iron twenty-six, and so on. This is called the element’s atomic number. To maintain electrical neutrality, an equal number of electrons surround the nucleus: one electron for hydrogen, twenty-six for iron, ninety-two for uranium, the most massive naturally occurring element, and also so on. As mentioned, a second kind of particle also resides in the nucleus, approximately the same mass as the proton but electrically neutral: the neutron, discovered by James Chadwick in 1932 and earning him the 1935 Nobel prize in physics. The total number of protons and neutrons in the nucleus is what is called the atomic mass of the element.

 I mentioned John Dalton a few moments ago as the author of the modern concept of the atom in the early 1800s. Yet what we see is that, despite Dalton’s elegant reasoning for his atomic theory, it took an entire century for scientists and philosophers to fully accept atoms as real things, not merely some bookkeeper’s way of keeping track of quantities in chemical reactions. Part of the reason for this lack of acceptance is that the scientific instrumentation capable of probing matter at the atomic level didn’t exist in Dalton’s time. Another part is that the concept of atoms didn’t fit neatly with either the edifice of Newtonian physics or the laws of thermodynamics as they unfolded in the 1700s and 1800s.

 Yet if atoms and the atomic theory of elements (an element is characterized by one and one only type of atom) had to wait until the twentieth century to be fully accepted, the modern concept of the chemical element was the offspring of work done in the late 1700s / early 1800s, by men like Lavoisier and LaPlace and Scheele and Priestly, among others. Hundreds of years of (failed) experiments in alchemy plus the Enlightenment and Scientific Revolution had driven home the idea that there were certain substances which simply could not be broken down into simpler ones, or turned into other ones, by any known chemical or physical processes. Thus, the main dream of alchemy – to turn “base” metals into gold – was finally seen as a delusion, even if the greatest minds of the day still did not know why. Yet some substances that had been thought of as elements, water being the prime example used in this chapter, were shown to be chemically reducible to simpler substances, in this case hydrogen and oxygen, which in turn proved to be elemental in character. The element fire, as already mentioned, which had been thought of as the release of a mysterious substance called phlogiston, was shown in fact to be the chemical breakdown or reassembly of a variety of substances, followed by their reaction with atmospheric oxygen in the vapor phase. And so on, with most of the original substances believed to be elements.

 Throughout the nineteenth century, as scientific instruments and theory became better and better honed, many new elements came to be added to the list, while some substances, like carbon and sulfur and iron and copper, which had been known since antiquity, also found their way in. The net result of all this innovation and exploration was that by the latter half of the nineteenth century a veritable zoo of elements had been identified and characterized. So large was this zoo, in fact, that scientists began to wonder if there were an underlying order to them, some schemata which naturally organized them according to their properties, both chemical and physical.


The Periodic Table
  Enter the brilliant Russian chemist Dmitri Ivanovich Mendeleev. Although others before him had noticed periodical trends in the elements, and even attempted to create tables of them, in which each column represented a series of similar elements, it wasn’t until 1869 that Mendeleev, via his own independent work, presented a table both complete and sophisticated enough that it was accepted by the scientific community. What was probably the most powerful feature of Mendeleev’s table, and what set it apart from others, was that it provided a means of testing it. It did this by predicting the existence of new, hitherto undiscovered elements to fill gaps in it. Specifically, he predicted the existence of what he called ekaaluminium and ekasilicon, amongst several others, and the properties these elements would have. When the elements gallium (Ga) and germanium (Ge) were found in 1875 and 1886, with properties that almost perfectly matched those predicted for ekaaluminum and ekasilicon, Mendeleev’s periodic table and his fame were secured. There were still more gaps to be filled, but over the next half century or so scientists teased them out from minerals in Earth’s crust (or in the case of helium, discovered it via spectroscopic lines in the sun’s atmosphere), to the point where today the aptly named periodic table of elements is now complete:

As noted, there are ninety naturally occurring elements, the rest having been man-made through nuclear transmutation of existing elements. Some terminology is in order. The table is called periodic because each row is a period, one that begins at an “alkali” metal (Li, Na, K, etc.) and ends at a “noble” gas (He, Ne, Ar, Kr, etc.). Incidentally, hydrogen (H), while sitting atop the alkali metals, doesn’t fit neatly anywhere, for reasons we shall come to. Complementary to this designation, each column is dubbed a group. In modern terminology there are eighteen groups, numbered in order from left to right; thus, the greatest length a period can be is eighteen members.

 So: we have made a little headway into understanding the elements, and their relationships to each other. Just a little, however; I still need to explain what these groups and periods actually mean, in both the physical and chemical senses. What exactly was Mendeleev’s brilliance, that has made him one of the most important scientists in history?

 Go back and study the modern periodic table as just presented. In particular, single out groups 1 and 2 (known as the alkali metals and alkaline earths) as well as groups 17 and 18 (the halogens and the noble gasses). Remember to exclude hydrogen, as it doesn’t neatly fit into any group. If you specifically examine group 1, the alkali metals, the similarity in their properties as you go up and down the group is remarkable: not only are they all highly metallic, they are also soft and malleable (becoming more so as you go down the group), react strongly with oxygen (O2) and water (H2 O) to form highly basic oxides and hydroxides in which the ratio of metal to oxide (O2-) and hydroxide (OH-) is exactly the same, react with other elements and compounds in very similar ways as well, and so on. The same can be said for the other groups I mentioned, the alkali earths, the halogens, and the noble gasses; as you go up and down the group/column, the physical and chemical properties bear a strong resemblance.

 These resemblances are the rational basis – no, the heart and soul – of the periodic table’s structure. Of equal if not greater importance is the way that the groups repeat themselves to form the rows, or periods; notice that although the groups are numbered 1 to 18, only the fourth through sixth periods actually have eighteen members (period seven would, and will, have them once we synthesize all of its elements; they are too radioactive to exist in nature). Period one has only two members, hydrogen and helium, while periods two and three have eight. If you look at periods six and seven, you will notice a break after the first two groups, filled in by the detached “sub”-periods beneath them known as the lanthanides and actinides, each of which having fourteen members. Believe it or not, if the number of elements were extended far enough, by artificial transmutations as they don’t exist in nature, the number and types of these sub-periods would continue to grow (as would their lengths – the next one would hold eighteen members). Indeed, theoretically there is no end to the table and how far it can be built; it goes on indefinitely. We should thank nature that there are only ninety naturally occurring and (as of this writing) around twenty man-made elements!

 It should go without saying that there is a good reason, founded in chemistry and physics, why the periodic table is built up this way, that it is not merely the way it is in order to baffle and befuddle poor students of chemistry. There is, and we shall get to it, but first we should note some other interesting aspects about the table. The one that should be staring you in the face is that, to demonstrate the family resemblances in groups/columns, I specifically singled out only the two left-most and two right-most ones. You might wonder why I was so persnickety about my choices, and you would be right to do so.

 The reason is that only in groups 1, 2, 17, and 18 do the resemblances of group members remain strong as you go all the way up and down the group. For the middle groups, 3 through 16, the top two series (He and Li through Ne) show distinct differences from their heavier brethren beneath. Specifically, boron, carbon, nitrogen, and oxygen, or B, C, N, and O, appear quite set apart in their properties than the elements beneath them, Al, Si, P, and S, or aluminum, silicon, phosphorus, and sulfur. As one example, carbon dioxide (CO2), which makes soda water fizzy and is a waste material we dispose of every time we exhale (as well as the main culprit behind global warming), is a colorless, essentially odorless gas at ordinary temperatures and pressures, while silicon dioxide (SiO2) is a hard, crystalline, more or less transparent solid under the same conditions. Likewise, water (H2O) is an almost colorless (it is actually slightly blue, as the color of the oceans attest), odorless, and tasteless liquid with a number of important and remarkable properties – life on this planet would not exist without copious amounts of it, in both liquid and gaseous form – while its sulfur analog, hydrogen sulfide (H2S), is a foul-smelling, highly toxic gas, as are H2Se and H2Te.

 Why the first two periods should display such differences from the periods beneath them is another topic we shall come to soon enough. First, however, let’s return to atoms.


The Idea of the Atom

 When Mendeleev created his first periodic table in 1869, atoms were not widely believed to exist, at least not as real physical entities, that is. Moreover, scientists had yet to discover the components of atoms, of which we are so familiar today: protons, neutrons, and electrons. Given this ignorance, based on what feature, or features, of the elements did Mendeleev and others base their tables from?

 If I were to answer that the feature were their atomic masses, your first response should be to object that that number is also derived from an atomic view of nature: it is, just as I said earlier, simply the combined mass of the protons and neutrons and binding energy (this is what holds them together) that characterize each element, averaged out over the percentages of each the element’s isotopes (different isotopes of an element have different numbers of neutrons in their nuclei).

 However, even though I told you this, it is not exactly true. There is another definition of atomic mass, one that doesn’t require any mention of sub-atomic particles. This definition is that it is the mass, in grams, of an Avagadro’s number of atoms – or elemental particles, if we do not know about atoms – of the element in question. Avagadro’s number is slap in the face enormous, being approximately 6.022 × 1023, although nobody knows its exact value. Note that it is just a number, or constant; one can have an Avagadro’s number of anything, from atoms to sand grains to basketballs to Ford model T’s to galaxies – anything you like. To give you a rough idea of just how large a number it is, if we are talking about sand grains, then by my estimate it is on the order of a hundred billion to a trillion beaches worth of sand or so – far, far more than all the grains on all the beaches and deserts on our Earth. Yet, large as it is, it is a very convenient number for dealing with things as small as atoms; an Avagadro’s number of atoms of any element is a quite manageable quantity of it, weighing from grams to hundreds of grams, depending on the element we are dealing with.

 One thing, however, that is a problem with talking about an Avagadro’s number of something is that it is a long, fumbling mouthful of syllables which would leave us needing a glass of water everytime we invoked it. Fortunately, chemists have come up with a short hand way of saying it, which is the word mole. A mole of something is simply an Avagadro’s number of the something, and again we can talk about a mole of atoms or sand grains or anything else. Whatever it is, I’m sure you’ll agree is a lot easier on the tongue. More to the point, using this much easier word the definition of atomic mass of an element is simply the mass, in grams, of a mole’s amount of it. In the case of the element carbon this is 12.011 grams/mole, and of the element gold is 196.97 grams/mole.

 Mendeleev did not know about the reality of atoms or anything about their sub-atomic components, and so his initial periodic table could only use atomic mass as a guide to where to place the various elements – a fact that made his construction of a workable table that much more difficult and his success in doing so that much more remarkable. Today we not only know about the reality of atoms but also all of their constituents, down to electrons, protons, and neutrons, the latter two of which can be furthered sub-divided into various quarks, as well as the various force particles which hold them together. This is important, because the true, modern, correct version of the table uses atomic numbers, the number of protons in the atomic nucleus (and the number of electrons swirling about that nucleus if it is an electrically neutral atom). None of this should be surprising, by the way; for as I keep emphasizing and re-emphasizing, science rarely if ever proceeds from zero knowledge to 100% understanding in one all-encompassing leap but largely from simpler, cruder models of reality to gradually more sophisticated, complete ones. The fact that we can make progress this way is one of the most fascinating features of science, not to mention one of the most curious features of reality; there is no reason, a priori, that we know of why this should be so. Why shouldn’t it be that to understand anything, you must understand everything first? Why should we be so fortunate that this is so? Feel free to speculate on that little philosophical conundrum.

 But first finish reading this book. As I noted, the modern periodic table is divided into columns or groups of similar elements, each repeating themselves in ever increasing sizes of periods; excepting that, as I have said, the first two periods are really not all that similar to those beneath them. The first period has only two members, hydrogen and helium, the second and third periods have eight members, the fourth and fifth eighteen members, the sixth and seventh thirty-two members (if you add in the lanthanides and actinides, that is), and so on.

 I can’t resist talking about this in more detail, as it fascinated me as a child who didn’t understand the reasons why nature is organized this way. It turns out that it takes a while to tease out the pattern to the increases, but it works out to be: (first period) = two protons/electrons; (second / third) = eight; (fourth / fifth) = eighteen; (six / seventh) = thirty-two. Putting it in tabular form, these increases go as the following:

2 = 2
2 + 6 = 8
2 + 6 + 10 = 18
2 + 6 + 10 + 14 = 32
2 + 6 + 10 + 14 + 18 = 50

 The pattern is, I hope, clear: each new row in this table adds an additional column, which is equal to the previous row’s last column entry plus four. A rather strange pattern, one must admit; but we must also be grateful for it, for all patterns in nature are the evidence of underlying structures or principles, and so are keys to understanding those structures/principles. The patterns in the periodic table are no different in this regard, as we shall come to see.

 The title of this book, The Third Row, refers to the third period in the periodic table, which has a total of eight elements. As I have already mentioned, without explanation, that the first two periods possess substantially different properties from those beneath them, not to mention the first significantly different from the second, this period is the first in which the strong similarities up and down the group become more apparent for all of the groups. For example, once again, hydrogen sulfide (H2S), hydrogen selenide (H2Se), and hydrogen telluride (H2Te), are much more alike to each other than they are to hydrogen oxide, or water (H2O).

 I think a natural question which arises here is: just why are there so many elements – or, to be more precise, atomic nuclei – in nature, and how did they come to exist?

 Where do the Elements come from? Why are There so Many of Them?

 To answer this question, we must segue from chemistry to, first, nuclear physics, and then to astrophysics and cosmology. The first segue, nuclear physics, is necessary because the elements, or again more specifically their atomic nuclei, are created by the joining together, or fusing, of smaller nuclei. To use the most common example of this, four hydrogen nuclei or protons (1H, where the 1 superscript indicates the total number of protons and neutrons in the nucleus, one proton in the case of hydrogen) are fused together, in one of a number of pathways, to make a helium four nucleus, or 4He, containing two protons and two neutrons. The overall reaction can be written, with some simplification, as:

 1H + 1H + 1H + 1H = 4He + 2e+ + 2νe

 The last two particles in this reaction, e+ and νe, are called the positron, or anti-electron, and the so-called electron anti-neutrino (neutrinos are particles with very small mass and no charge, which travel very close to the speed of light). Their emission is needed to turn two of the 1H nuclei, which are protons, into the two neutrons in the 4He nucleus. Another example of a fusion reaction is the so-called “triple alpha” process, in which three 4He nuclei, which are also the alpha particles mentioned earlier, are fused together to make one 12C nucleus:

 4He + 4He + 4He = 12C

 These and many other fusion reactions are employed by nature to build up the complement of chemical elements she has so generously provided to us. However, even the simplest of these reactions, hydrogen to helium, can happen only under very specific, and hence uncommon, conditions. To answer why this is so, stand back and take a better look at what we are doing. Remember how in school you learned that unlike electric charges attract each other while like charges repel? Well, atomic nuclei are composed of protons and neutrons, and while the neutrons are electrically neutral the protons carry a very strong positive electric charge and so should, and in fact do, repel each other, even in atomic nuclei. So what then even holds them together in the nucleus, let alone allowing them to fuse together into even larger nuclei? Why don’t atomic nuclei go around exploding like miniature firecrackers as a result of these mutual like charges in their nuclei, leaving us with an atom free universe?

 This turns out to be a very good question, and one again that took many years to answer, by scientists incessantly scratching their heads and trying innumerable experiments. You might attempt, as a first approach to solving this conundrum, to speculate that there might be other forces in nature which provide us with the solution to it. What about gravity, for example? We know a good deal about gravity; for example, that it causes all mass objects, regardless of their electric charge or any other factor, to be attracted to each other, via the relationship:

 F = G(m1m2)/(r*r)

In this equation, F is the gravitational force, m1m2 the product of the objects’ masses, r2 the square of the distance between the objects (and so the factor which shows how quickly the force between the objects diminishes with distance), and G the proportionality constant in the equation, being equal to 6.673×10−11 N m2 kg−2 if you are interested. Gravity would, indeed, seem to be a good candidate for holding atomic nuclei together; after all, it is what holds our Earth, not to mention the sun and all the other planets and most of their moons, together, keeps us secure on the surface of our planet instead of being hurled out into space from the centrifugal force its spin generates, keeps the moon revolving about Earth, and Earth and all the other planets in our solar system in their orbits about the sun. In fact, we are much more aware of gravity than of the electric force, and so can be excused for thinking it to be the stronger of the two, and by a considerable ratio.

 Not only could we be excused for thinking this way, we would have to be excused, because reality is in the opposite direction, and by a very large factor at that. In truth, the electromagnetic force of attraction or repulsion is approximately one thousand trillion trillion trillion (1039) stronger than gravity! The equation of this force is:

F = ke(q1q2)/(r*r)

 where now, instead of m1m2 we have q1q2, the product of the electric charges on the objects (whether attractive or repulsive), and ke as the proportionality constant. As with gravity, we also see that the force diminishes as the square of the distance between the objects.

 The fact that the electromagnetic force can be either attractive or repulsive, whereas gravity is always attractive, is the cause of our error in thinking gravity the stronger of the two. When matter is accumulated on the scales we are accustomed to, and larger, there are almost always as many negative as positive charges, and the net effect of this equality is to mutually cancel these charges out so that at most only a very, very small excess exists in either direction, if indeed there is any excess at all. As for gravity, however, this force is always cumulative, so that massive objects can build up an appreciable attractive charge, the larger the accumulation resulting in the greater the charge. Build up enough mass in a small enough volume in fact, and you will have yourself a something called a black hole, which is an object whose gravity is so intense that not even light can escape its clutches.

 So much for gravity, then; it has no chance of solving our dilemma. What then does hold the protons together in the nucleus and, more to our point, allows them to be fused together into ever increasingly larger nuclei? The answer, as Hamlet says to Horatio, involves realizing that “There are more things in heaven and earth than are dreamt of in your philosophy.” Just because gravity and electricity (more correctly, electromagnetism) are the only fundamental forces in the universe that we are directly aware of, thanks to their squared distance attenuation, so there are other forces we are rarely cognizant of solely because they diminish over much shorter distances. Physicists call these forces nuclear forces precisely because they drop to virtually zero over distances of even a small amount greater than atomic nuclei. There are two such forces, named, perhaps unimaginatively, the strong nuclear force and the weak nuclear force. The weak nuclear force comes into play in certain kinds of nuclear decay and will not be discussed further here. The strong nuclear force is what catches our interest because it is both attractive only (but only to protons and neutrons and other particles collectively known as hadrons) and is some one hundred times as strong as the electromagnetic force. Again, the reason we almost never directly encounter it is its extremely short range, approximately that of several protons and/or neutrons or the atomic nucleus at most; beyond that distance, it rapidly diminishes to essentially nothing.


How Does Nature Build Elements Beyond Hydrogen?

 Let us return to the simplest fusion reaction, that of hydrogen to helium:

1H + 1H + 1H + 1H = 4He + 2e+ + 2νe

 We can now see that what holds the two protons and two neutrons in the resulting helium nucleus must be the strong nuclear force. This is how nature creates, not just in helium but in all of the elements larger than hydrogen, by fusing together smaller nuclei. This present us with a problem, however. The four hydrogen nuclei, or protons, start out at a distance from one another much larger than the strong force’s range, while at the same time they are close enough to feel the electromagnetic force keeping them apart, a force which still immensely powerful. Somehow, some way, we must push the protons closer and closer together until they start feeling the strong force more strongly than their mutual electric repulsion and so stick together to form a two plus particle nucleus. (What happens after this in the creation of helium and other small nuclei, if you are interested, is that the weak nuclear force causes one or more protons to decay into neutrons, in the process emitting positrons and anti-neutrinos as we saw in the 41H → 4He reaction.)

 There are only two ways of forcing the protons close enough to overcome their repulsion, and that is either by pressing them together under extremely high density and/or raising by their temperature very high, generally in the millions of degrees, so that they will be moving fast enough to overcome their repulsion and fuse. In practice, one usually has to do both. In nature, there are only two places/times that these conditions exist: one is in the first few minutes of the Big Bang, the primordial beginning to our universe, while the other is in the extremely hot, dense cores of stars like our sun, both active today and in the past. The reason these conditions existed during the Big Bang is that it was the way our universe began, as either a singularity (single point in space-time) or a volume very close to it, so that the density and temperature must have passed through a time near its beginning when such fantastic conditions existed. The reason they exist now in the cores of stars is due to the massive gravitational compression and heating existing there; the so-called “proton – proton nucleosynthesis” fusion reaction to helium is in fact the primary source of most stars’ prodigious energy outputs, including our own sun. However, although there have been many quadrillions of stars in our universe carrying out this reaction since stars first started to form some thirteen billion years ago, most of the helium in the cosmos today is in fact the result of Big Bang nucleosynthesis – this is actually one of the facts that have been used to prove the Big Bang theory correct. The Big Bang is also responsible for most of the trace amounts of lithium, beryllium, and, I believe, boron, atomic numbers three through five, in the present cosmos.


Creation of Elements Beyond Helium

What about the other elements, including the ones in the third period we will be discussing? I’ve already shown one fusion reaction, the triple-alpha process, that yields carbon. This reaction requires much higher densities/temperatures than the proton-proton reaction however, and it should be by now pretty obvious why. Helium nuclei contain twice the number of protons as hydrogen, and so the electromagnetic repulsion between them is proportionately higher, at least twice as high – while the fact that the strong force is also one hundred times as strong does not help us here because of its very short range. Another reason is that now we are trying to fuse three nuclei into one, meaning you have to start by fusing two and hoping this nuclei will last long enough to be struck by the third 4He. This intermediate nucleus 8Be, however, is extraordinarily unstable, fissioning or breaking back down into two 4He in a fraction of a trillionth of a second.

 The triple-alpha process couldn’t happen during Big Bang nucleosynthesis because by the time enough helium had been created to do so, the temperature and density of the expanding universe had dropped to below what is needed for this reaction. The only place it can still happen, and still does happen, like the proton-proton process, is in the cores of stars; not just any stars, however, but only those significantly more massive than our sun. The reason for this is straightforward: hydrogen fusion in stars creates a helium “ash” which, as it is both heaver than hydrogen and has no energy source itself, collects in the center of the star. This core of helium grows throughout the star’s lifetime, in doing so raising the temperature of the core by its unchecked gravitational compression. As the core’s temperature thereby rises, the hydrogen fusion surrounding it becomes more intense; this leads to more helium accumulation, leading to still higher temperatures from gravitational compression in their cores, higher rates of proton-proton fusion, and so on, in a positive feedback mechanism that causes even sunlike stars like the sun to grow steadily hotter and brighter throughout this part of their evolution. The end result of this positive feedback loop is the creation of a “red giant” phase, in which stars like our sun become hundreds of times brighter than during their “Main Sequence” phase, their outer regions expanding to some hundred times their current diameters or more, while their surface temperatures cause a drop in color from yellow/white to red as these expanded atmospheres cools.

 For a sun-like star, that is pretty much it (and it’s about five billion years in our future for our sun, so don’t worry about it). The greatly increased radiation pressure from the red giant’s core eventually blows away most of its atmosphere and other outer regions into interstellar space. In doing so, the remnant central region, exhausted now of hydrogen fuel to fuse, shrinks until it is approximately the size of Earth or smaller. It’s surface is still white hot from the core, hence the name “white dwarf”, but it gradually cools over billions of years back down to red and then infrared invisibility. Finally it is cold as space itself.

 This is the fate of most stars, but not, as I have said, those significantly more massive than the sun. In massive stars the hydrogen fusion is much more profligate, as it must be to generate the enormous radiation pressure needed to hold the star up against gravitational collapse. This means the core temperature is much higher than our sun’s, and by the star’s red giant phase will be in the hundreds of millions to billions of degrees (instead of a “modest” fifteen million degrees C in the sun). At these temperatures the triple alpha process can and does occur. This “helium flash” in the core will consume most of its helium (and quite quickly), converting it not only into carbon but also turning some of that carbon further into oxygen, neon, and magnesium as additional 4He nuclei are fused in. Other elements are also created by the fusion of protons, neutrons, and other small nuclei.

 All these processes, in the most massive of stars, can continue to build heavier nuclei all the way up to iron and nickel. However, to create nuclei larger than iron and nickel requires an input of energy rather than its release, as the most stable nuclei (those having the smallest binding energies) end with these metals; all the heavier elements, up to uranium and beyond, are created mainly by neutron capture, a process that absorbs energy rather than releasing it (thereby hastening the end of the star’s life). Using this process, however, even the most massive stars can create nuclei only up to a certain number of protons, to between roughly ninety and one hundred. The reason for this is that most of these larger nuclei (some of the thorium and uranium nuclei are exceptions) are intensely radioactive and decay to smaller ones in short periods of times.

 All this of course only says how the elements are created; it does not tell us how they then found their way into other stars and their planets, including Earth, the compositions of which they primarily constitute. What completes the tale is also told by the most massive stars; for not only do they build these heavy elements, they then blast them into interstellar space via the supernova explosions which ends their brief lives, leaving them as either neutron stars or black holes. Newer generation stars and their planetary entourages then sweep these elements up during their formation. This also explains why the lighter elements, essentially the first two rows of the periodic table and to a lesser extent the third, make up the bulk of the matter in our universe, for, as we have seen, as you progress to heavier elements they become increasingly challenging to create.


Summary

So. We have explained what the chemical elements are, as well as how they are organized, how they were created, and why there are as many of them as there are. Excuse me, I should say how their atomic nuclei were created; talking about the elements themselves means talking about their constituent atoms, which includes their electrons, how the electrons are organized about the nucleus, and how they behave. This finally is the subject of chemistry, and we will make our first inroads into it in the next chapter.

From Quarks to Quasars » The Center of a Black Hole: Infinitely Massive Singularity or Portal into another Universe?

From Quarks to Quasars » The Center of a Black Hole: Infinitely Massive Singularity or Portal into another Universe?

Black holes are one of the most naggingly peculiar objects in the universe. Beyond the event horizon of a black hole, our equations are turned upside down; they also get turned inside out when we attempt to fathom the singularity at its center when using the equations given to us by Einstein. To make life simpler, what if we removed the singularity all together? There is some math for that.

Quantum gravity is an attempt in theoretical physics to explain gravity and the behavior of gravitational fields at the quantum scale. In other words, quantum gravity is one possible ‘Theory of Everything’ scientists are considering. When you apply the framework of quantum gravity to a black hole, some very interesting things happen, among the most interesting is the vanishing singularity.


Instead of a singularity, quantum gravity replaces the center of a black hole with science-fiction’s best friend – a portal to another universe. How many times have we seen our hero (or the villain) fall into a black hole and avoid a crushing death by being transported to another universe? That might not be so far from the truth. Disregarding the fact that our favorite sci-fi movies get a boost of scientific accuracy, such a model immediately helps physicists resolve the black hole information paradox.

The paradox basically addresses two parts of scientific theory that are butting heads with each other. On one hand, general relativity combined with quantum mechanics seems to suggest that information can permanently vanish when it’s devoured by a black hole. In contrast, a common tenet of science states that information cannot be permanently destroyed.

OK, back to the singularity, or lack thereof. As most of you are aware, flying into a black hole is a very poor life choice. According to relativity, tidal forces from the black hole will elongate you in a process affectionately called ‘spaghettification’ – and all of this happens before you cross the event horizon. After you pass the point of no return, you’ll continue to fall to the singularity (the point at the center of the black hole where gravity is infinitely strong and all matter is crushed into an infinitely dense point–fun times). What happens next? We have no idea. General relativity simply stops working and breaks down when trying to describe the singularity.

Singularities aren’t the only thing relativity has problems with. Einstein’s crowning achievement also breaks down when describing the big bang. In 2006, a team of physicists used loop quantum gravity in an attempt to explain the big bang; their results were very interesting. Again, the singularity commonly thought to exist at the start of the universe disappeared and was replaced with something the team described as a “quantum bridge” that brought the team into an older universe that existed before ours.

Relativity is a fascinating theory that is nothing short of remarkable, but maybe it’s playing with an incomplete deck when it comes to black holes and their inner singularities. Perhaps a comprehensive theory of everything will reveal hidden portals within one of nature’s most fearsome creations.

Entropy (statistical thermodynamics)

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Entropy_(statistical_thermody...