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Tuesday, January 7, 2014

Physicists and Archaeologists Tussle Over Long-Lost Lead

David Strumfels:  Even scientists practice inter-disciplinary conflict.
Roman mosaic from the 2nd century AD of a ship displaying similar hull shape to the Madrague de Giens wreck.
Image credit: via wikipedia | http://bit.ly/19mo34m,
Rights information: http://bit.ly/1lavRWo

By Peter Gwynne at http://physicsbuzz.physicscentral.com/2013/12/physicists-and-archaeologists-tussle.html A confrontation among ancient and modern studies is pitting particle physicists seeking concrete evidence of dark matter against marine archaeologists intent on preserving material in centuries-old shipwrecks.

The source of the issue: samples of lead used for anchors and ballast in Roman ships that were sunk up to 2,000 years ago and remain underwater since then.

The ancient lead's purity makes it invaluable today for shielding underground experiments designed to detect evidence of dark matter, the mysterious invisible stuff that, according to physicists, accounts for 85 percent of all the matter in the universe. But some marine archaeologists assert that, as a part of the world's cultural heritage, the lead should stay in place for detailed historical study.

"The use of these objects as stock for experimentation had never been an issue before," wrote Elena Perez-Alvaro, a doctoral candidate in underwater cultural heritage maritime law at England's University of Birmingham, in the university's journal Rosetta. "But now it is beginning to be deemed ethically questionable."

Both sides of the affair cite strong scientific justification for their use of the lead. "Underwater archaeologists and cultural heritage protection policymakers need to evaluate the value of this underwater lead for future generations," Perez-Alvaro explained. But the lead "is an essential element of state-of-the-art dark-matter searches," added Cambridge University physicist Fernando Gonzalez Zalba, who collaborates with Perez-Alvaro on studying the issue. "These experiments could shed light some of the most fundamental properties of the universe."

There's no shortage of the material. "I personally have seen dozens of lead anchor stocks during our expeditions in the Mediterranean and Aegean," recalled Brendan Foley of the Woods Hole Oceanographic Institution's Deep Submergence Laboratory, in Massachusetts.

For archaeologists, studying those stocks has value far beyond understanding ancient metallurgical methods. The pieces of lead "are marked with indicators of where they came from," said James Delgado, director of maritime heritage at the National Oceanic and Atmospheric Administration in the United States. "That helps us to reconstruct ancient economies and global trade."

Physicists have inferred the existence of dark matter by observing its gravitational influence in distant galaxies. But they don't know what it consists of. Among the most popular candidates are entities called weakly interactive massive particles, or WIMPs.

Theorists believe that, although WIMPs are about the size of atomic nuclei, they scarcely interact at all with any other forms of matter. "Very occasionally one of them will bump into a nucleus and rattle it around a bit," explained Daniel Bauer, project manager of the Cryogenic Dark Matter Search, or CDMS. "Our detectors are set up to measure the recoil of the nucleus when that happens," he added.

It doesn't happen often. "Nobody has yet had a completely confirmed sighting," Bauer said. Their detectors are sensitive to a rate of one incident per year.

Because the bumps happen so infrequently, CDMS has designed its experimental setup to minimize false positives. To avoid cosmic rays, the team has buried its detectors half a mile deep in a mine in Minnesota. It also shields them with copper, plastics, water, and, most important, lead.

"Lead is the material of excellence as a shielding material in radiation-rich environments," said Gonzalez Zalba, who does not work directly on dark-matter experiments. "Its low intrinsic radioactivity, good mechanical properties, and reasonable cost make it an excellent shielding material."

However, recently mined lead has one disadvantage. "Uranium and thorium that coexist with lead will leave a fair amount of the radioactive isotope lead-210 in it," Bauer noted. "In our experiments, even tiny amounts of radioactivity can lead to false signals. We want the purest possible material to shield the experiment from radioactivity."

That means lead mined a long time ago and preserved under water. "There's no chance that uranium and thorium are nearby," Bauer continued. "And since its decay half life is about 23 years, its radioactivity has basically gone." The ancient lead has over 1,000 times less radioactivity than modern lead.

The CDMS team bought its ancient lead from French company Lemer Pax, which had salvaged it from a Roman ship sunk off the coast of France. Later, the company "got in trouble with French customs for selling archaeological material," Perez-Alvaro reported.

"We assumed that this company was reputable, and I would believe that to be true," Bauer said. "They're still selling lead. That's the best evidence that everything is in order."

Another underground experiment, the Cryogenic Underground Observatory for Rare Events in Italy, also uses Roman lead. A museum gave it 120 archaeological lead bricks from a ship built more than 2,000 years ago and recovered in the early 1990s off the coast of Sardinia.

Marine archaeologists don't want to deny physicists the use of the ancient lead. But they fear that such use could help to commercialize the salvage of ancient shipwrecks.

"It's another example of something from a shipwreck that has value and will encourage an approach to shipwrecks that won't be available for careful meticulous study. Science and archaeology go out of the window in the quest for profits," Delgado said. "The issue is the salvaging and selling of the lead; that's where archaeologists say 'Wait a minute.'"

The 2001 UNESCO convention for the protection of the underwater cultural heritage preserves the Roman lead and other ancient artifacts from any use that would damage them. "However," Perez-Alvaro explained, "there is no reference anywhere to the use of shipwrecks for the purpose of experimentation – new uses of underwater cultural heritage."

Nevertheless, archaeologists and physicists see opportunities for agreements that would protect the ancient lead's heritage while still benefiting dark-matter searches. "It's all right if it's been documented – like taking a bit of DNA and putting it in the DNA bank," Delgado suggested. "That's a respectable scientific process that benefits all branches of science."

Gonzalez Zalba agreed. "We follow the idea of 'salvage for knowledge and not for the marketplace,'" he said. "Dark-matter searches follow under the idea of research for knowledge. Therefore I believe the resources should be granted if required under the adequate regulation and archaeological supervision."

Perez-Alvaro calls for a formal route to regulation. "There is a need for dialogue between the two fields," she said. "Especially there is a need for a protocol [on the acquisition and use of ancient lead] set up by archaeologists."

"Archaeologists will always view as unethical the outright sale of artifacts recovered from cultural sites," Foley added. "But other creative solutions could be devised which would be win-win for physicists and archaeologists."

- Peter Gwynne, Inside Science News Service

The illiterate of the 21st century will not be those who cannot read and write ...

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Many people use the word "supernatural" without realizing that is an illogical oxymoron.  We don't know all laws about our universe, so what does the term even supposed to mean?  If a phenomenon can't be explained by existing science, then it is existing science that is inadequate, not nature in refusing to accommodate the phenomenon.
 
For me, the classic example is the end of the nineteenth century to the beginning of the twentieth.
Thanks to the work of brilliant scientists over 300 years -- Galileo, Kepler, Newton, Lavoisier, Gauss, Priestly, Faraday, Maxwell, others I've embarrassingly forgotten -- by the end of the 19'th century science seemed to be complete to many people.
 
Not that there weren't unsolved problems.  The heat capacity of polyatomic gasses for one; modeling stable atoms with existing physics; the photoelectric effect; and the quandary of the "ultraviolet catastrophe" in black body radiation.  Worse, try as they could, scientists there simply could not crack these nuts, could not make any progress, using the known (and complete) laws of physics.
 
Imagine that you lived at that time and are a believer in the supernatural.  Why then, there's your answer!  The problems couldn't be solved by natural science because they above and beyond science.  They're the work of God, or some supernatural deity or ... or who knew what, but they must be beyond our comprehension.  Forever.  Bow down and say amen.
 
Fortunately for all of us, any science worth his PhD intuitively understands my first paragraph.  They realized that if the "known" laws of nature couldn't, however much effort, solve some basic physical problems, then the laws were either in some kind error or there must be more laws than we had so far discovered.
 
I'm not going to take us through history of quantum mechanics and relativity.  This is a blog, not a book, after all.  I will say that so much of our technology -- the Internet, computers, other electronic devices, many medical devices, others I can't think of right now -- would not be in our lives.  We would be living pretty much as people live 100 years ago.
 
Supernatural.  The lethal superfallacy of so much of history.  Let's rid ourselves of it as swiftly as possible.

Perovskite solar cells become even more promising with cheaper materials by Lisa Zyga

perovskite solar cells
(A) Cross-section schematic of a perovskite solar cell with copper iodide hole conductor. (B) Image of the complete device. SEM cross-section images of solar cells using (C) copper iodide and (D) spiro-OMeTAD hole conductors
 
(Phys.org) —Due to their rapid improvements in a short amount of time, perovskite solar cells have become one of today's most promising up-and-coming photovoltaic technologies. Currently, the record efficiency for a perovskite solar cell is 15% and expected to improve further. Although the perovskite material itself is relatively inexpensive, the best devices commonly use an expensive organic hole-conducting polymer, called spiro-OMeTAD, which has a commercial price that is more than 10 times that of gold and platinum.

In a new study, Jeffrey A. Christians, Raymond C. M. Fung, and Prashant V. Kamat from the University of Notre Dame in Indiana have found that copper iodide, an inexpensive inorganic hole-conducting material, may serve as a possible alternative to spiro-OMeTAD. Although the efficiency of perovskite solar cells containing copper iodide measured in this study is not quite as high as those containing spiro-OMeTAD, the copper iodide devices exhibit some other advantages that, overall, suggest that they could lead to the development of inexpensive, high-efficiency perovskite solar cells.

"The hole conductor is currently the most expensive part of perovskite solar cells," Christians told Phys.org. "Other organic hole conductor alternatives to spiro-OMeTAD have been investigated, but these alternatives still remain very expensive. This is the first reported inorganic hole conductor for perovskite solar cells, and is much less expensive than previously reported hole conductor materials.

This low-cost hole conductor could further lower the cost of these already inexpensive solar cells."
Perovskite solar cells, as a whole, are attractive because perovskite is a class of materials with a particular crystal structure that is the same as that of calcium titanium dioxide. This structure gives solar cells high charge-carrier mobilities and long diffusion lengths, allowing the photo-generated electrons and holes to travel long distances without energy loss. As a result, the electrons and holes can travel through thicker solar cells, which absorb more light and therefore generate more electricity than thin ones.

Although this study marks the first time that copper iodide has been investigated for use as hole conductors in perovskite solar cells, copper-based hole conductors have previously shown promise for use in dye-sensitized and quantum dot-sensitized solar cells. Part of their appeal is their high conductivity. In fact, copper iodide hole conductors exhibit an electrical conductivity that is two orders of magnitude higher than spiro-OMeTAD, which allows for a higher fill factor, which in turn determines the solar cell's maximum power.

Despite the copper iodide's high conductivity, the results of the current study showed that perovskite solar cells made with copper iodide hole conductors have a power conversion efficiency of 6.0%, lower than the 7.9% measured here for cells with spiro-OMeTAD hole conductors. The researchers attribute this shortcoming to the fact that spiro-OMeTAD solar cells have exceptionally high voltages. In the future, they think that the voltages of copper iodide solar cells can be increased, in particular by reducing the high recombination rate. The researchers calculated that, if they could achieve the highest parameter values observed in this study, the resulting copper iodide solar cell would have an efficiency of 8.3%.

The researchers also observed that the copper iodide solar cells exhibited another surprising advantage, which is good stability. After two hours of continuous illumination, the copper iodide cells showed no decrease in current, while the current of the spiro-OMeTAD cells decreased by about 10%. The researchers plan to further improve the devices in the future.

"We are currently working to understand the cause of the low voltage in copper iodide-based perovskite solar cells," Christians said. "With further work, we aim to increase the stability and improve the efficiency of these solar cells above 10%.

"The biggest challenge facing perovskite solar cells is long-term stability in a wide range of environments. The efficiency of the best perovskite solar cells is competitive with current commercial technologies, and they are potentially much cheaper. However, commercial solar cells must last 20-30 years with minimal degradation, and whether or not perovskite are capable of this type of long-term stability is currently an unanswered question."
Journal reference: Journal of the American Chemical Society

Read more at: http://phys.org/news/2014-01-perovskite-solar-cells-cheaper-materials.html#jCp

Have You Met Fallacy Man? Here’s How to Defeat Him.

David Strumfels -- This was just to precious to let go by.

Have You Met Fallacy Man? Here’s How to Defeat Him.

The following comic, which was first published last Monday, has been reprinted with the author’s permission. For more, check out his site, Existential Comics.
The Adventures of Fallacy Man
The Adventures of Fallacy Man
 
 
 

Paul Ryan’s Own Little Obamacare, By Sam Baker

Republicans’ Medicare plan would be wide open to the same attacks the GOP is aiming at Obamacare.


Paul Ryan's Medicare plan has a lot in common with Obamacare.

For Republicans, Obamacare is the gift that keeps on giving. Each day brings a fresh batch of horror stories of people losing their plans, getting cut off from their doctors, and shelling out more for premiums.

But had Mitt Romney won in 2012 and let Paul Ryan have his way with Medicare, Republicans would be on the other side of the fence, trying to defend a health care overhaul that produced a nearly identical suite of horror stories.

That's because, despite the political chasm between them—and though neither will admit it—Obama and Ryan are pushing similar policies in the bid to change the U.S. health system. Both rely on private insurance, sold through a competitive exchange, with help from a government subsidy.
And though they apply it to different populations, both programs share a fundamental conceit: They move a big group of people into the private insurance market. Both Obama and Ryan argue their overhaul would improve the country as a whole, but neither can escape the reality that in a shift of that size, some people will lose out.


And each plan's losers would have similar stories to tell.

Some premiums will go up

Insurance companies cut back on coverage or limit provider networks to keep premiums low. Lower premiums also will usually come with higher deductibles. This is pretty much how private insurance works, and that will be the case whether Obama or Ryan is expanding the market for private insurance.

The Congressional Budget Office has said seniors' costs would be higher under Ryan's model, though it has declined to provide a specific estimate, in part because the plan hasn't been introduced as a bill.
A Ryan-like plan that immediately affected current seniors would raise seniors' premiums by an average of 30 percent, and their total spending—including premiums, deductibles, and other cost-sharing—by about 11 percent, according to CBO.

CBO's estimate isn't an exact comparison to the Ryan plan, because it assumes changes would affect current beneficiaries—which Ryan's plan wouldn't. But liberal health care experts pointed to the report as an indication of how the Medicare program would be different once a policy framework similar to Ryan's was fully in place.

The House Budget Committee, which Ryan chairs, did not respond to a request for comment for this story.

Some people can't keep their doctors

Republicans have assailed the Affordable Care Act because many of the plans offered through its exchanges use narrow networks of doctors, hospitals, and other health care providers. Conservatives sharply criticized the White House after Zeke Emanuel, a former health care adviser, said that if you like your doctor, you can pay more to keep your doctor.
But, again, the same basic trade-off applies under the Ryan Medicare plan. The Ryan plan guarantees that seniors will have a subsidy big enough to buy a health care plan. But in most parts of the country, it won't be enough to buy traditional Medicare.
So, in order to choose that program—and its extensive provider network—seniors would have to make up the difference out of their own pocket. They could pay more for the plan that exists today, or they could switch to a cheaper private plan that would likely offer a smaller provider network, meaning they might have to change doctors.
Premiums for traditional Medicare would cost seniors about 56 percent more than they pay today, under the accelerated scenario CBO analyzed. About half of Medicare beneficiaries would buy private plans and half would remain in traditional Medicare, under CBO's model.

Losers, but different losers

Obamacare and the Ryan plan are similar, but it's important to remember their respective starting points. Obamacare is primarily covering people who have never had insurance before, and also requiring some people (no one knows exactly how many, but it's somewhere in the millions) to buy new policies. Ryan, meanwhile, would overhaul an existing program.
"With Medicare, you're talking about the whole 40-plus million beneficiaries who are going to have to make new choices and whose benefits and premiums are likely to be affected," said Paul Van de Water, a senior fellow at the Center on Budget and Policy Priorities, which opposes Ryan's model for Medicare.
From a cost perspective, that means the Ryan plan has one especially big winner: the federal budget. The purpose of Ryan's plan is to cut federal entitlement spending, and it would do that. Overall costs, combining federal spending and seniors' costs, would also fall.
Obamacare launched a new stream of federal health care spending while the Ryan plan would shrink an existing one. That's a big difference. But both options would expand the market for private insurance, and therefore would expose millions more people to narrow networks and the other standard trade-offs of the insurance market. Both would inevitably mean some degree of sticker shock for certain people, and paying a lower price would mean giving up benefits.
"How it all works out is complicated, but that's another point of comparison with health reform," Van de Water said.

This article appears in the January 7, 2014, edition of NJ Daily.

To The Horror Of Global Warming Alarmists, Global Cooling Is Here by Peter Ferrara

English: Ice age Earth at glacial maximum. Bas...

From David Strumfels:

Some notes before reading this article.  Looking into the future is always hazardous, whatever your prediction.  Furthermore, facts are usually messy, and sometimes can be used in opposition to a theory as well as support.  A good example is the very basis of anthropogenic global warming:  the  cyclic but overall warming of 1850-1900 to ~2005 correlates well with the anthropogenic CO2 rise from 280 ppm to almost 400 ppm, which shows no sign of abating (yet, because I believe it will).  But is it cause and effect or mere correlation?  Or some of both?  That CO2 is a greenhouse gas weighs, I believe, towards cause and effect.  But careful study of the data seems to me to show that much of the warming until 1970-1980 was more natural, a combination of effects Earth's climate has always lived with.  Only after the mid-late '70s does another effect exert more serious influence, and the only one I can think of is CO2.

My study of global temperature graphs also made a detail about it clear (although I'm not the first to notice it):  as I've just alluded, the warming is not straight-line, even with random variation making it messy.  Look at the cart below:


 
 
 
 











The lines make the cyclic nature of warming stand out, although by themselves, they do not prove it.  Have we studied earlier historic records to see if they stand up?  Honestly, I don't know -- but it's an important analysis if we can do it. But historical records are based largely on temperature proxies (ice cores, tree rings, etc., which are notoriously prone to scatter) and it may be impossible.

These cycles (they are, of course, not the straight lines as I illustrate them) have met with dismissal by most warming alarmists as statistical massaging, and they may prove to be right about that.  May be proved -- or may not.  As detailed, strongly agreeable temperature proxies don't exist for history or "deep time", such short cycles would never be found whether they are there or not.  My point here is that when it comes to climate predictions, I don't see where we even could have sufficient knowledge or understanding to make solid predictions, like a 95% the temperature will be 4-8 degrees higher than today (if nothing changes is sometimes added, as if nothing will change).

I might have been dismissive of this hypothesis too, if temperatures had kept climbing as they had done since the '70s.  But they didn't.  Starting around the 1997-2005 range (exact numbers vary, but I  lean toward the latter), the warming clearly stopped, leaving us in at least a holding pattern, or even with some mild cooling (a disputable claim).  It may be just a little blip, of course.  But it strongly fits in to the cyclic warming hypothesis, is almost exactly what we would have predicted if that hypothesis is true.  If it is true, expect up to thirty years of cooling before warming (if nothing changes, remember) resumes.  Since much will change, and has already been changing for ~20+ years -- developments in recyclable energy, replacement of natural gas over high carbon fossil fuels, the on-going efficiency improvements in cars, appliances, CO2 reclamation, etc. -- the CO2 trend must flatten out and perhaps even decline, perhaps starting as soon as twenty years from now although as always with making predictions I will not bet my fortune on it.  But by 2050 and later, I would make that bet (though I'll be 94 years old by then and won't have enough money if I lose).

I'll say no more and let Ferrara speak for himself.

Around 1250 A.D., historical records show, ice packs began showing up farther south in the North Atlantic. Glaciers also began expanding on Greenland, soon to threaten Norse settlements on the island. From 1275 to 1300 A.D., glaciers began expanding more broadly, according to radiocarbon dating of plants killed by the glacier growth. The period known today as the Little Ice Age was just starting to poke through.

Summers began cooling in Northern Europe after 1300 A.D., negatively impacting growing seasons, as reflected in the Great Famine of 1315 to 1317. Expanding glaciers and ice cover spreading across Greenland began driving the Norse settlers out. The last, surviving, written records of the Norse Greenland settlements, which had persisted for centuries, concern a marriage in 1408 A.D. in the church of Hvalsey, today the best preserved Norse ruin.

Colder winters began regularly freezing rivers and canals in Great Britain, the Netherlands and Northern France, with both the Thames in London and the Seine in Paris frozen solid annually. The first River Thames Frost Fair was held in 1607. In 1607-1608, early European settlers in North America reported ice persisting on Lake Superior until June. In January, 1658, a Swedish army marched across the ice to invade Copenhagen. By the end of the 17th century, famines had spread from northern France, across Norway and Sweden, to Finland and Estonia.
Reflecting its global scope, evidence of the Little Ice Age appears in the Southern Hemisphere as well. Sediment cores from Lake Malawi in southern Africa show colder weather from 1570 to 1820. A 3,000 year temperature reconstruction based on varying rates of stalagmite growth in a cave in South Africa also indicates a colder period from 1500 to 1800. A 1997 study comparing West Antarctic ice cores with the results of the Greenland Ice Sheet Project Two (GISP2) indicate a global Little Ice Age affecting the two ice sheets in tandem.

The Siple Dome, an ice dome roughly 100 km long and 100 km wide, about 100 km east of the Siple Coast of Antartica, also reflects effects of the Little Ice Age synchronously with the GISP2 record, as do sediment cores from the Bransfield Basin of the Antarctic Peninsula. Oxygen/isotope analysis from the Pacific Islands indicates a 1.5 degree Celsius temperature decline between 1270 and 1475 A.D.

The Franz Josef glacier on the west side of the Southern Alps of New Zealand advanced sharply during the period of the Little Ice Age, actually invading a rain forest at its maximum extent in the early 1700s. The Mueller glacier on the east side of New Zealand’s Southern Alps expanded to its maximum extent at roughly the same time.

Ice cores from the Andeas mountains in South America show a colder period from 1600 to 1800. Tree ring data from Patagonia in South America show cold periods from 1270 to 1380 and from 1520 to 1670. Spanish explorers noted the expansion of the San Rafael Glacier in Chile from 1675 to 1766, which continued into the 19th century.

The height of the Little Ice Age is generally dated as 1650 to 1850 A.D. The American Revolutionary Army under General George Washington shivered at Valley Forge in the winter of 1777-78, and New York harbor was frozen in the winter of 1780. Historic snowstorms struck Lisbon, Portugal in 1665, 1744 and 1886. Glaciers in Glacier National Park in Montana advanced until the late 18th or early 19th centuries. The last River Thames Frost Fair was held in 1814. The Little Ice Age phased out during the middle to late 19th century.

The Little Ice Age, following the historically warm temperatures of the Medieval Warm Period, which lasted from about AD 950 to 1250, has been attributed to natural cycles in solar activity, particularly sunspots. A period of sharply lower sunspot activity known as the Wolf Minimum began in 1280 and persisted for 70 years until 1350. That was followed by a period of even lower sunspot activity that lasted 90 years from 1460 to 1550 known as the Sporer Minimum. During the period 1645 to 1715, the low point of the Little Ice Age, the number of sunspots declined to zero for the entire time. This is known as the Maunder Minimum, named after English astronomer Walter Maunder. That was followed by the Dalton Minimum from 1790 to 1830, another period of well below normal sunspot activity.

The increase in global temperatures since the late 19th century just reflects the end of the Little Ice Age. The global temperature trends since then have followed not rising CO2 trends but the ocean temperature cycles of the Pacific Decadal Oscillation (PDO) and the Atlantic Multidecadal Oscillation (AMO). Every 20 to 30 years, the much colder water near the bottom of the oceans cycles up to the top, where it has a slight cooling effect on global temperatures until the sun warms that water. That warmed water then contributes to slightly warmer global temperatures, until the next churning cycle.

Those ocean temperature cycles, and the continued recovery from the Little Ice Age, are primarily why global temperatures rose from 1915 until 1945, when CO2 emissions were much lower than in recent years. The change to a cold ocean temperature cycle, primarily the PDO, is the main reason that global temperatures declined from 1945 until the late 1970s, despite the soaring CO2 emissions during that time from the postwar industrialization spreading across the globe.

The 20 to 30 year ocean temperature cycles turned back to warm from the late 1970s until the late 1990s, which is the primary reason that global temperatures warmed during this period. But that warming ended 15 years ago, and global temperatures have stopped increasing since then, if not actually cooled, even though global CO2 emissions have soared over this period. As The Economist magazine reported in March, “The world added roughly 100 billion tonnes of carbon to the atmosphere between 2000 and 2010. That is about a quarter of all the CO2 put there by humanity since 1750.” Yet, still no warming during that time. That is because the CO2 greenhouse effect is weak and marginal compared to natural causes of global temperature changes.

At first the current stall out of global warming was due to the ocean cycles turning back to cold. But something much more ominous has developed over this period. Sunspots run in 11 year short term cycles, with longer cyclical trends of 90 and even 200 years. The number of sunspots declined substantially in the last 11 year cycle, after flattening out over the previous 20 years. But in the current cycle, sunspot activity has collapsed. NASA’s Science News report for January 8, 2013 states,
“Indeed, the sun could be on the threshold of a mini-Maunder event right now. Ongoing Solar Cycle 24 [the current short term 11 year cycle] is the weakest in more than 50 years. Moreover, there is (controversial) evidence of a long-term weakening trend in the magnetic field strength of sunspots. Matt Penn and William Livingston of the National Solar Observatory predict that by the time Solar Cycle 25 arrives, magnetic fields on the sun will be so weak that few if any sunspots will be formed. Independent lines of research involving helioseismology and surface polar fields tend to support their conclusion.”

That is even more significant because NASA’s climate science has been controlled for years by global warming hysteric James Hansen, who recently announced his retirement.

But this same concern is increasingly being echoed worldwide. The Voice of Russia reported on April 22, 2013,

“Global warming which has been the subject of so many discussions in recent years, may give way to global cooling. According to scientists from the Pulkovo Observatory in St.Petersburg, solar activity is waning, so the average yearly temperature will begin to decline as well. Scientists from Britain and the US chime in saying that forecasts for global cooling are far from groundless.”

That report quoted Yuri Nagovitsyn of the Pulkovo Observatory saying, “Evidently, solar activity is on the decrease. The 11-year cycle doesn’t bring about considerable climate change – only 1-2%. The impact of the 200-year cycle is greater – up to 50%. In this respect, we could be in for a cooling period that lasts 200-250 years.” In other words, another Little Ice Age.

Faith in Global Warming is collapsing in formerly staunch Europe following increasingly severe winters which have now started continuing into spring. Christopher Booker explained in The Sunday Telegraph on April 27, 2013,

“Here in Britain, where we had our fifth freezing winter in a row, the Central England Temperature record – according to an expert analysis on the US science blog Watts Up With That – shows that in this century, average winter temperatures have dropped by 1.45C, more than twice as much as their rise between 1850 and 1999, and twice as much as the entire net rise in global temperatures recorded in the 20th century.”
A news report from India (The Hindu April 22, 2013) stated, “March in Russia saw the harshest frosts in 50 years, with temperatures dropping to –25° Celsius in central parts of the country and –45° in the north. It was the coldest spring month in Moscow in half a century….Weathermen say spring is a full month behind schedule in Russia.” The news report summarized,

“Russia is famous for its biting frosts but this year, abnormally icy weather also hit much of Europe, the United States, China and India. Record snowfalls brought Kiev, capital of Ukraine, to a standstill for several days in late March, closed roads across many parts of Britain, buried thousands of sheep beneath six-metre deep snowdrifts in Northern Ireland, and left more than 1,000,000 homes without electricity in Poland. British authorities said March was the second coldest in its records dating back to 1910. China experienced the severest winter weather in 30 years and New Delhi in January recorded the lowest temperature in 44 years.”

Booker adds, “Last week it was reported that 3,318 places in the USA had recorded their lowest temperatures for this time of year since records began. Similar record cold was experienced by places in every province of Canada. So cold has the Russian winter been that Moscow had its deepest snowfall in 134 years of observations.”

Britain’s Met Office, an international cheerleading headquarters for global warming hysteria, did concede last December that there would be no further warming at least through 2017, which would make 20 years with no global warming. That reflects grudging recognition of the newly developing trends. But that reflects as well growing divergence between the reality of real world temperatures and the projections of the climate models at the foundation of the global warming alarmism of the UN’s Intergovernmental Panel on Climate Change (IPCC). Since those models have never been validated, they are not science at this point, but just made up fantasies. That is why, “In the 12 years to 2011, 11 out of 12 [global temperature]forecasts [of the Met Office] were too high — and… none were colder than [resulted],” as BBC climate correspondent Paul Hudson wrote in January.

Global warming was never going to be the problem that the Lysenkoists who have brought down western science made it out to be. Human emissions of CO2 are only 4 to 5% of total global emissions, counting natural causes. Much was made of the total atmospheric concentration of CO2 exceeding 400 parts per million. But if you asked the daffy NBC correspondent who hysterically reported on that what portion of the atmosphere 400 parts per million is, she transparently wouldn’t be able to tell you. One percent of the atmosphere would be 10,000 parts per million. The atmospheric concentrations of CO2 deep in the geologic past were much, much greater than today, yet life survived, and we have no record of any of the catastrophes the hysterics have claimed. Maybe that is because the temperature impact of increased concentrations of CO2 declines logarithmically. That means there is a natural limit to how much increased CO2 can effectively warm the planet, which would be well before any of the supposed climate catastrophes the warming hysterics have tried to use to shut down capitalist prosperity.

Monday, January 6, 2014

Science Is Not Your Enemy An impassioned plea to neglected novelists, embattled professors, and tenure-less historians by Steven Pinker


The great thinkers of the Age of Reason and the Enlightenment were scientists. Not only did many of them contribute to mathematics, physics, and physiology, but all of them were avid theorists in the sciences of human nature. They were cognitive neuroscientists, who tried to explain thought and emotion in terms of physical mechanisms of the nervous system. They were evolutionary psychologists, who speculated on life in a state of nature and on animal instincts that are “infused into our bosoms.” And they were social psychologists, who wrote of the moral sentiments that draw us together, the selfish passions that inflame us, and the foibles of shortsightedness that frustrate our best-laid plans.
 
These thinkers—Descartes, Spinoza, Hobbes, Locke, Hume, Rousseau, Leibniz, Kant, Smith—are all the more remarkable for having crafted their ideas in the absence of formal theory and empirical data.
The mathematical theories of information, computation, and games had yet to be invented. The words “neuron,” “hormone,” and “gene” meant nothing to them. When reading these thinkers, I often long to travel back in time and offer them some bit of twenty-first-century freshman science that would fill a gap in their arguments or guide them around a stumbling block. What would these Fausts have given for such knowledge? What could they have done with it?
 
We don’t have to fantasize about this scenario, because we are living it. We have the works of the great thinkers and their heirs, and we have scientific knowledge they could not have dreamed of. This is an extraordinary time for the understanding of the human condition. Intellectual problems from antiquity are being illuminated by insights from the sciences of mind, brain, genes, and evolution.
Powerful tools have been developed to explore them, from genetically engineered neurons that can be controlled with pinpoints of light to the mining of “big data” as a means of understanding how ideas propagate.
 
One would think that writers in the humanities would be delighted and energized by the efflorescence of new ideas from the sciences. But one would be wrong. Though everyone endorses science when it can cure disease, monitor the environment, or bash political opponents, the intrusion of science into the territories of the humanities has been deeply resented. Just as reviled is the application of scientific reasoning to religion; many writers without a trace of a belief in God maintain that there is something unseemly about scientists weighing in on the biggest questions. In the major journals of opinion, scientific carpetbaggers are regularly accused of determinism, reductionism, essentialism, positivism, and worst of all, something called “scientism.” The past couple years have seen four denunciations of scientism in this magazine alone, together with attacks in Bookforum, The Claremont Review of Books, The Huffington Post, The Nation, National Review OnlineThe New Atlantis, The New York Times, and Standpoint.
 
The eclectic politics of these publications reflects the bipartisan nature of the resentment. This passage, from a 2011 review in The Nation of three books by Sam Harris by the historian Jackson Lears, makes the standard case for the prosecution by the left:
Positivist assumptions provided the epistemological foundations for Social Darwinism and pop-evolutionary notions of progress, as well as for scientific racism and imperialism. These tendencies coalesced in eugenics, the doctrine that human well-being could be improved and eventually perfected through the selective breeding of the "fit" and the sterilization or elimination of the "unfit." ... Every schoolkid knows about what happened next: the catastrophic twentieth century. Two world wars, the systematic slaughter of innocents on an unprecedented scale, the proliferation of unimaginable destructive weapons, brushfire wars on the periphery of empire—all these events involved, in various degrees, the application of sceintific research to advanced technology. 
The case from the right, captured in this 2007 speech from Leon Kass, George W. Bush’s bioethics adviser, is just as measured:
Scientific ideas and discoveries about living nature and man, perfectly welcome and harmless in themselves, are being enlisted to do battle against our traditional religious and moral teachings, and even our self-understanding as creatures with freedom and dignity. A quasi-religious faith has sprung up among us—let me call it "soul-less scientism"—which believes that our new biology, eliminating all mystery, can give a complete account of human life, giving purely scientific explanations of human thought, love, creativity, moral judgment, and even why we believe in God. ... Make no mistake. The stakes in this contest are high: at issue are the moral and spiritual health of our nation, the continued vitality of science, and our own self-understanding as human beings and as children of the West. 
These are zealous prosecutors indeed. But their cases are weak. The mindset of science cannot be blamed for genocide and war and does not threaten the moral and spiritual health of our nation. It is, rather, indispensable in all areas of human concern, including politics, the arts, and the search for meaning, purpose, and morality.
 
The term “scientism” is anything but clear, more of a boo-word than a label for any coherent doctrine. Sometimes it is equated with lunatic positions, such as that “science is all that matters” or that “scientists should be entrusted to solve all problems.” Sometimes it is clarified with adjectives like “simplistic,” “naïve,” and “vulgar.” The definitional vacuum allows me to replicate gay activists’ flaunting of “queer” and appropriate the pejorative for a position I am prepared to defend.
 
Scientism, in this good sense, is not the belief that members of the occupational guild called “science” are particularly wise or noble. On the contrary, the defining practices of science, including open debate, peer review, and double-blind methods, are explicitly designed to circumvent the errors and sins to which scientists, being human, are vulnerable. Scientism does not mean that all current scientific hypotheses are true; most new ones are not, since the cycle of conjecture and refutation is the lifeblood of science. It is not an imperialistic drive to occupy the humanities; the promise of science is to enrich and diversify the intellectual tools of humanistic scholarship, not to obliterate them. And it is not the dogma that physical stuff is the only thing that exists. Scientists themselves are immersed in the ethereal medium of information, including the truths of mathematics, the logic of their theories, and the values that guide their enterprise. In this conception, science is of a piece with philosophy, reason, and Enlightenment humanism. It is distinguished by an explicit commitment to two ideals, and it is these that scientism seeks to export to the rest of intellectual life.

The Linder Gallery, c.1622-1629, Cordover Collection, LLC
 
The first is that the world is intelligible. The phenomena we experience may be explained by principles that are more general than the phenomena themselves. These principles may in turn be explained by more fundamental principles, and so on. In making sense of our world, there should be few occasions in which we are forced to concede “It just is” or “It’s magic” or “Because I said so.”
The commitment to intelligibility is not a matter of brute faith, but gradually validates itself as more and more of the world becomes explicable in scientific terms. The processes of life, for example, used to be attributed to a mysterious élan vital; now we know they are powered by chemical and physical reactions among complex molecules.
 
Demonizers of scientism often confuse intelligibility with a sin called reductionism. But to explain a complex happening in terms of deeper principles is not to discard its richness. No sane thinker would try to explain World War I in the language of physics, chemistry, and biology as opposed to the more perspicuous language of the perceptions and goals of leaders in 1914 Europe. At the same time, a curious person can legitimately ask why human minds are apt to have such perceptions and goals, including the tribalism, overconfidence, and sense of honor that fell into a deadly combination at that historical moment.
Many of our cultural institutions cultivate a philistine indifference to science.
 
The second ideal is that the acquisition of knowledge is hard. The world does not go out of its way to reveal its workings, and even if it did, our minds are prone to illusions, fallacies, and super- stitions. Most of the traditional causes of belief—faith, revelation, dogma, authority, charisma, conventional wisdom, the invigorating glow of subjective certainty—are generators of error and should be dismissed as sources of knowledge. To understand the world, we must cultivate work-arounds for our cognitive limitations, including skepticism, open debate, formal precision, and empirical tests, often requiring feats of ingenuity. Any movement that calls itself “scientific” but fails to nurture opportunities for the falsification of its own beliefs (most obviously when it murders or imprisons the people who disagree with it) is not a scientific movement.
 
In which ways, then, does science illuminate human affairs? Let me start with the most ambitious: the deepest questions about who we are, where we came from, and how we define the meaning and purpose of our lives. This is the traditional territory of religion, and its defenders tend to be the most excitable critics of scientism. They are apt to endorse the partition plan proposed by Stephen Jay
Gould in his worst book, Rocks of Ages, according to which the proper concerns of science and religion belong to “non-overlapping magisteria.” Science gets the empirical universe; religion gets the questions of moral meaning and value.
 
Unfortunately, this entente unravels as soon as you begin to examine it. The moral worldview of any scientifically literate person—one who is not blinkered by fundamentalism—requires a radical break from religious conceptions of meaning and value.
 
To begin with, the findings of science entail that the belief systems of all the world’s traditional religions and cultures—their theories of the origins of life, humans, and societies—are factually mistaken. We know, but our ancestors did not, that humans belong to a single species of African primate that developed agriculture, government, and writing late in its history. We know that our species is a tiny twig of a genealogical tree that embraces all living things and that emerged from prebiotic chemicals almost four billion years ago. We know that we live on a planet that revolves around one of a hundred billion stars in our galaxy, which is one of a hundred billion galaxies in a 13.8-billion-year-old universe, possibly one of a vast number of universes. We know that our intuitions about space, time, matter, and causation are incommensurable with the nature of reality on scales that are very large and very small. We know that the laws governing the physical world (including accidents, disease, and other misfortunes) have no goals that pertain to human well-being.
There is no such thing as fate, providence, karma, spells, curses, augury, divine retribution, or answered prayers—though the discrepancy between the laws of probability and the workings of cognition may explain why people believe there are. And we know that we did not always know these things, that the beloved convictions of every time and culture may be decisively falsified, doubtless including some we hold today.
 
In other words, the worldview that guides the moral and spiritual values of an educated person today is the worldview given to us by science. Though the scientific facts do not by themselves dictate values, they certainly hem in the possibilities. By stripping ecclesiastical authority of its credibility on factual matters, they cast doubt on its claims to certitude in matters of morality. The scientific refutation of the theory of vengeful gods and occult forces undermines practices such as human sacrifice, witch hunts, faith healing, trial by ordeal, and the persecution of heretics. The facts of science, by exposing the absence of purpose in the laws governing the universe, force us to take responsibility for the welfare of ourselves, our species, and our planet. For the same reason, they undercut any moral or political system based on mystical forces, quests, destinies, dialectics, struggles, or messianic ages. And in combination with a few unexceptionable convictions— that all of us value our own welfare and that we are social beings who impinge on each other and can negotiate codes of conduct—the scientific facts militate toward a defensible morality, namely adhering to principles that maximize the flourishing of humans and other sentient beings. This humanism, which is inextricable from a scientific understanding of the world, is becoming the de facto morality of modern democracies, international organizations, and liberalizing religions, and its unfulfilled promises define the moral imperatives we face today.
 
Moreover, science has contributed—directly and enormously—to the fulfillment of these values. If one were to list the proudest accomplishments of our species (setting aside the removal of obstacles we set in our own path, such as the abolition of slavery and the defeat of fascism), many would be gifts bestowed by science.
 
The most obvious is the exhilarating achievement of scientific knowledge itself. We can say much about the history of the universe, the forces that make it tick, the stuff we’re made of, the origin of living things, and the machinery of life, including our own mental life. Better still, this understanding consists not in a mere listing of facts, but in deep and elegant principles, like the insight that life depends on a molecule that carries information, directs metabolism, and replicates itself.
 
Science has also provided the world with images of sublime beauty: stroboscopically frozen motion, exotic organisms, distant galaxies and outer planets, fluorescing neural circuitry, and a luminous planet Earth rising above the moon’s horizon into the blackness of space. Like great works of art, these are not just pretty pictures but prods to contemplation, which deepen our understanding of what it means to be human and of our place in nature.
 
And contrary to the widespread canard that technology has created a dystopia of deprivation and violence, every global measure of human flourishing is on the rise. The numbers show that after millennia of near-universal poverty, a steadily growing proportion of humanity is surviving the first year of life, going to school, voting in democracies, living in peace, communicating on cell phones, enjoying small luxuries, and surviving to old age. The Green Revolution in agronomy alone saved a billion people from starvation. And if you want examples of true moral greatness, go to Wikipedia and look up the entries for “smallpox” and “rinderpest” (cattle plague). The definitions are in the past tense, indicating that human ingenuity has eradicated two of the cruelest causes of suffering in the history of our kind. 
 
Though science is beneficially embedded in our material, moral, and intellectual lives, many of our cultural institutions, including the liberal arts programs of many universities, cultivate a philistine indifference to science that shades into contempt. Students can graduate from elite colleges with a trifling exposure to science. They are commonly misinformed that scientists no longer care about truth but merely chase the fashions of shifting paradigms. A demonization campaign anachronistically impugns science for crimes that are as old as civilization, including racism, slavery, conquest, and genocide.
 
Just as common, and as historically illiterate, is the blaming of science for political movements with a pseudoscientific patina, particularly Social Darwinism and eugenics. Social Darwinism was the misnamed laissez-faire philosophy of Herbert Spencer. It was inspired not by Darwin’s theory of natural selection, but by Spencer’s Victorian-era conception of a mysterious natural force for progress, which was best left unimpeded. Today the term is often used to smear any application of evolution to the understanding of human beings. Eugenics was the campaign, popular among leftists and progressives in the early decades of the twentieth century, for the ultimate form of social progress, improving the genetic stock of humanity. Today the term is commonly used to assail behavioral genetics, the study of the genetic contributions to individual differences.
 
I can testify that this recrimination is not a relic of the 1990s science wars. When Harvard reformed its general education requirement in 2006 to 2007, the preliminary task force report introduced the teaching of science without any mention of its place in human knowledge: “Science and technology directly affect our students in many ways, both positive and negative: they have led to life-saving medicines, the internet, more efficient energy storage, and digital entertainment; they also have shepherded nuclear weapons, biological warfare agents, electronic eavesdropping, and damage to the environment.” This strange equivocation between the utilitarian and the nefarious was not applied to other disciplines. (Just imagine motivating the study of classical music by noting that it both generates economic activity and inspired the Nazis.) And there was no acknowledgment that we might have good reasons to prefer science and know-how over ignorance and superstition.
 
At a 2011 conference, another colleague summed up what she thought was the mixed legacy of science: the eradication of smallpox on the one hand; the Tuskegee syphilis study on the other. (In that study, another bloody shirt in the standard narrative about the evils of science, public-health researchers beginning in 1932 tracked the progression of untreated, latent syphilis in a sample of impoverished African Americans.) The comparison is obtuse. It assumes that the study was the unavoidable dark side of scientific progress as opposed to a universally deplored breach, and it compares a one-time failure to prevent harm to a few dozen people with the prevention of hundreds of millions of deaths per century, in perpetuity.
 
A major goad for the recent denunciations of scientism has been the application of neuroscience, evolution, and genetics to human affairs. Certainly many of these applications are glib or wrong, and they are fair game for criticism: scanning the brains of voters as they look at politicians’ faces, attributing war to a gene for aggression, explaining religion as an evolutionary adaptation to bond the group. Yet it’s not unheard of for intellectuals who are innocent of science to advance ideas that are glib or wrong, and no one is calling for humanities scholars to go back to their carrels and stay out of discussions of things that matter. It is a mistake to use a few wrongheaded examples as an excuse to quarantine the sciences of human nature from our attempt to understand the human condition.
To simplify is not to be simplistic. 
 
Take our understanding of politics. “What is government itself,” asked James Madison, “but the greatest of all reflections on human nature?” The new sciences of the mind are reexamining the connections between politics and human nature, which were avidly discussed in Madison’s time but submerged during a long interlude in which humans were assumed to be blank slates or rational actors. Humans, we are increasingly appreciating, are moralistic actors, guided by norms and taboos about authority, tribe, and purity, and driven by conflicting inclinations toward revenge and reconciliation. These impulses ordinarily operate beneath our conscious awareness, but in some circumstances they can be turned around by reason and debate. We are starting to grasp why these moralistic impulses evolved; how they are implemented in the brain; how they differ among individuals, cultures, and sub- cultures; and which conditions turn them on and off.
 
The application of science to politics not only enriches our stock of ideas, but also offers the means to ascertain which of them are likely to be correct. Political debates have traditionally been deliberated through case studies, rhetoric, and what software engineers call HiPPO (highest-paid person’s opinion). Not surprisingly, the controversies have careened without resolution. Do democracies fight each other? What about trading partners? Do neighboring ethnic groups inevitably play out ancient hatreds in bloody conflict? Do peacekeeping forces really keep the peace? Do terrorist organizations get what they want? How about Gandhian nonviolent movements? Are post-conflict reconciliation rituals effective at preventing the renewal of conflict?
 
History nerds can adduce examples that support either answer, but that does not mean the questions are irresolvable. Political events are buffeted by many forces, so it’s possible that a given force is potent in general but submerged in a particular instance. With the advent of data science—the analysis of large, open-access data sets of numbers or text—signals can be extracted from the noise and debates in history and political science resolved more objectively. As best we can tell at present, the answers to the questions listed above are (on average, and all things being equal) no, no, no, yes, no, yes, and yes.
 
The humanities are the domain in which the intrusion of science has produced the strongest recoil. Yet it is just that domain that would seem to be most in need of an infusion of new ideas. By most accounts, the humanities are in trouble. University programs are downsizing, the next generation of scholars is un- or underemployed, morale is sinking, students are staying away in droves. No thinking person should be indifferent to our society’s disinvestment from the humanities, which are indispensable to a civilized democracy.
 
Diagnoses of the malaise of the humanities rightly point to anti-intellectual trends in our culture and to the commercialization of our universities. But an honest appraisal would have to acknowledge that some of the damage is self-inflicted. The humanities have yet to recover from the disaster of postmodernism, with its defiant obscurantism, dogmatic relativism, and suffocating political correctness. And they have failed to define a progressive agenda. Several university presidents and provosts have lamented to me that when a scientist comes into their office, it’s to announce some exciting new research opportunity and demand the resources to pursue it. When a humanities scholar drops by, it’s to plead for respect for the way things have always been done.
 
Those ways do deserve respect, and there can be no replacement for the varieties of close reading, thick description, and deep immersion that erudite scholars can apply to individual works. But must these be the only paths to understanding? A consilience with science offers the humanities countless possibilities for innovation in understanding. Art, culture, and society are products of human brains.
They originate in our faculties of perception, thought, and emotion, and they cumulate and spread through the epidemiological dynamics by which one person affects others. Shouldn’t we be curious to understand these connections? Both sides would win. The humanities would enjoy more of the explanatory depth of the sciences, to say nothing of the kind of a progressive agenda that appeals to deans and donors. The sciences could challenge their theories with the natural experiments and ecologically valid phenomena that have been so richly characterized by humanists.
 
In some disciplines, this consilience is a fait accompli. Archeology has grown from a branch of art history to a high-tech science. Linguistics and the philosophy of mind shade into cognitive science and neuroscience.
 
Similar opportunities are there for the exploring. The visual arts could avail themselves of the explosion of knowledge in vision science, including the perception of color, shape, texture, and lighting, and the evolutionary aesthetics of faces and landscapes. Music scholars have much to discuss with the scientists who study the perception of speech and the brain’s analysis of the auditory world.
 
As for literary scholarship, where to begin? John Dryden wrote that a work of fiction is “a just and lively image of human nature, representing its passions and humours, and the changes of fortune to which it is subject, for the delight and instruction of mankind.” Linguistics can illuminate the resources of grammar and discourse that allow authors to manipulate a reader’s imaginary experience. Cognitive psychology can provide insight about readers’ ability to reconcile their own consciousness with those of the author and characters. Behavioral genetics can update folk theories of parental influence with discoveries about the effects of genes, peers, and chance, which have profound implications for the interpretation of biography and memoir—an endeavor that also has much to learn from the cognitive psychology of memory and the social psychology of self-presentation. Evolutionary psychologists can distinguish the obsessions that are universal from those that are exaggerated by a particular culture and can lay out the inherent conflicts and confluences of interest within families, couples, friendships, and rivalries that are the drivers of plot.
And as with politics, the advent of data science applied to books, periodicals, correspondence, and musical scores holds the promise for an expansive new “digital humanities.” The possibilities for theory and discovery are limited only by the imagination and include the origin and spread of ideas, networks of intellectual and artistic influence, the persistence of historical memory, the waxing and waning of themes in literature, and patterns of unofficial censorship and taboo.
 
Nonetheless, many humanities scholars have reacted to these opportunities like the protagonist of the grammar-book example of the volitional future tense: “I will drown; no one shall save me.” Noting that these analyses flatten the richness of individual works, they reach for the usual adjectives: simplistic, reductionist, naïve, vulgar, and of course, scientistic.
 
The complaint about simplification is misbegotten. To explain something is to subsume it under more general principles, which always entails a degree of simplification. Yet to simplify is not to be simplistic. An appreciation of the particulars of a work can co-exist with explanations at many other levels, from the personality of an author to the cultural milieu, the faculties of human nature, and the laws governing social beings. The rejection of a search for general trends and principles calls to mind Jorge Luis Borges’s fictitious empire in which “the Cartographers Guild drew a map of the Empire whose size was that of the Empire, coinciding point for point with it. The following Generations ... saw the vast Map to be Useless and permitted it to decay and fray under the Sun and winters.”
And the critics should be careful with the adjectives. If anything is naïve and simplistic, it is the conviction that the legacy silos of academia should be fortified and that we should be forever content with current ways of making sense of the world. Surely our conceptions of politics, culture, and morality have much to learn from our best understanding of the physical universe and of our makeup as a species.

Entropy (statistical thermodynamics)

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