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Saturday, December 28, 2013

Wht Do We Need the SPACE Launch System?

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Why is NASA using its precious, and shrinking, funding to construct a massive, Saturn V (which took Apollo astronauts to the moon) type rocket, the Space Launch System (SLS), when private companies, such as SpaceX and Orbital Sciences Corporation already or soon will have rockets that will accomplish all the functions sooner and cheaper?
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
SpaceX's Falcon 9 rocket is already delivering cargo regularly to the ISS (International Space System) and even to Geosynchronous orbit (22,000 miles high).  It is easily already man-rated in terms of safety, and will be carrying astronauts into orbit within a couple of years.  A more powerful version of the Falcon, the Falcon Heavy, is due for testing in 2014 and will also be ready for missions within the same time span.  While not as powerful as the SLS, the combination of a Falcon Heavy (to carry the needed equipment) and Falcon 9 (to carry a crew) will already have the capacity to send men to the moon or beyond -- even to Mars perhaps -- before the end of this decade, ahead of SLS' schedule.  SpaceX is also working on recoverable rocket stages and other advanced technologies.
 
 
Antares, known during early development as Taurus II, is an expendable launch system developed by Orbital Sciences Corporation. Designed to launch payloads of mass up to 5,000 kg (11,000 lb) into low-Earth orbit, it made its maiden flight on April 21, 2013. Designed to launch the Cygnus spacecraft to the International Space Station as part of NASA's COTS and CRS programs, Antares is the largest rocket operated by Orbital Sciences, and is scheduled to start supplying the ISS early 2014.

NASA awarded to Orbital a Commercial Orbital Transportation Services (COTS) Space Act Agreement (SAA) in 2008 to demonstrate delivery of cargo to the International Space Station. For these COTS missions Orbital intends to use Antares to launch its Cygnus spacecraft. In addition, Antares will compete for small-to-medium missions. On December 12, 2011 Orbital Sciences renamed the launch vehicle "Antares" from the previous designation of Taurus II, after the star of the same name.
 
I cannot see how, between SpaceX and COTS, the two companies and their rockets alone don't invalidate the need for the SLS.  If it were scrubbed (it is an Obama Administration project), large amounts of money could be freed up for more unmanned planetary missions, such as to Europa, Uranus, and Neptune, and to asteroids for mining possibilities.
 
 
Linus Torvalds

Linus Torvalds

On this date in 1969, Linus Torvalds was born in Helsinki, Finland. He started using computers when he was about 10 year old, and soon began designing simple computer programs. Torvalds earned his M.S. in computer science from the University of Helsinki in 1996, where he was introduced to the Unix operating system. In 1991, Torvalds began creating the innovative Linux, an operating system similar to Unix. Later in the year, he released Linux for free as an open source operating system, allowing anyone to edit its source code with Torvalds’ permission. Linux’s open source nature has contributed to its popularity and reliability, since it is regularly updated and improved by dedicated users. For his work with Linux, Torvalds received the 2008 Computer History Fellow Award and the 2005 Vollum Award for Distinguished Accomplishment in Science and Technology. The asteroid 9793 Torvalds was named after him.

After developing Linux, Torvalds worked for Transmeta Corporation from 1997 to 2003. He appeared in the 2001 documentary “Revolution OS,” and authored an autobiography titled Just for Fun: The Story of an Accidental Revolutionary (2001). He is married to Tove Torvalds, who also attended the University of Helsinki for Computer Science. They live in the U.S. and have three daughters, Patricia, born in 1996, Daniela, born in 1998, and Celeste, born in 2000.

In a Nov. 1, 1999 interview with Linux Journal, Torvalds described himself as “completely a-religious” and “atheist.” He explained his reasons for being an atheist: “I find it kind of distasteful having religions that tell you what you can do and what you can’t do.” He also believes in the separation of church and state, telling Linux Journal, “In practice, religion has absolutely nothing to do with everyday life.”
“I find that people seem to think religion brings morals and appreciation of nature. I actually think it detracts from both . . . I think we can have morals without getting religion into it, and a lot of bad things have come from organized religion in particular. I actually fear organized religion because it usually leads to misuses of power.”
—Linus Torvalds, Linux Journal, Nov. 1, 1999.
Compiled by Sabrina Gaylor
© Freedom From Religion Foundation. All rights reserved.

Why Consciousness Can't Keep Up with Fear

by Joseph LeDoux      
December 27, 2013, 6:00 AM
Brain_fear
 
Whenever you encounter some sudden danger out there in the world - let’s say it’s a snake on a path - the information from that stimulus goes into your brain through your visual system. It will then rise through the visual system through the standard pathways.  So every sensory system has this very well organized set of circuits that ultimately leads to a stop in the part of the brain called the thalamus on route to reaching the sensory cortex.  So each sensory system has an area in the cortex.  The cortex is that wrinkled part of the brain that you see whenever you see a picture of the brain.  And that’s where we have our perceptions and thoughts and all of that.  
 
In order to have a visual perception, information has to be transmitted from the eye, from the retina, through the optic nerve, into the visual thalamus, and from the visual thalamus to the visual cortex where the processing continues and you can ultimately have the perception.  So, the visual cortex connects directly with the amygdala, and so thats one route by which the information can get in: retina, thalamus, cortex, amygdala.  But one of the first things that I discovered when I started studying fear was that that pathway, the usual pathway that we think about for sensory processing was not the way that fear was elicited, or not the only way.  
 
What we found was that if the cortical pathway was blocked completely, rats could still form a memory about a sound.  We were studying sounds and shocks.  But we’ve also done it with a visual stimulus.  So, what we found was the sound had to go up to the level of the thalamus, but then it didn’t need to go to the auditory cortex or the visual cortex as if it happened to be a visual stimulus. 
Instead, it made an exit from the sensory system and went directly into the amygdala, below the level of the cortex.  That was really important because we generally think that the cortex is required for any kind of conscious experience.  So, this is a way that information was being sent through the brain and triggering emotions unconsciously.  So, the psychoanalysts love this because it vindicated the idea that you could have this unconscious fear that the cortex has no understanding of.  
 
This is important because a lot of people have fears and phobias and anxieties about things they don’t understand.  They don’t know why they’re afraid or anxious in a particular moment.  It may be through various kinds of experiences, the low road gets potentiated in a way that it’s activating fears and phobias outside of conscious awareness and that doesn’t make sense in terms of what the conscious brain is looking at in the world, or hearing in the world because they’ve been separately parsed out.  
 
So, the subcortical pathway, we’ve been able to time all of this very precisely in the rat brain and it takes, in order for a sound to get to the amygdala from the sub cortical pathway takes about 10 or 12 milliseconds.  So, take a second and divide that into 1,000 parts, and after 12 of those little parts, the amygdala was already getting the sound.  For you to be consciously aware of the stimulus, it takes 250-300 milliseconds.  So, the amygdala is being triggered much, much faster than consciousness is processing.  
 
So, the brain ticks in milliseconds, the neurons process information on the level of milliseconds, but the mind is processing things on the order of seconds and half seconds here.  So, if you have a fear response that is being triggered very rapidly like that, consciously you’re going to be interpreting what’s going on, but it’s not going to necessarily match what’s really going on.  
 
In Their Own Words is recorded in Big Think's studio.
Image courtesy of Shutterstock

Lake Vostok: Life in one of the Inhospitable Places on Earth

Posted on December 28, 2013 at 9:00 am
By on Quarks to Quasars

Lake Vostok: Life in one of the most Inhospitable Places on Earth:     

800px-Lake_Vostok_drill_2011
Credit: Nicolle Rager-Fuller / NSF
Credit: Nicolle Rager-Fuller / NSF
 
Located on the seemingly inhospitable continent of Antarctica (a place with the lowest recorded temperature on the Earth at -89 degrees Celsius), lies a subglacial lake that is 160 miles wide and 30 miles across. This lake has been dubbed Lake Vostok. It is believed that the lake formed some 20 million years ago. Isolated from the rest of the world for at LEAST 100 000 years, Lake Vostok was one of the last untouched places on this globe.

The lake presents itself as an analog for the study of both extremophilic microbial life (and possibly larger organisms) and evolutionary isolation. This inhospitable environment parallels some environments that we think might exist elsewhere in the solar system – either in the subsurface of Mars or on icy moons like Enceladus or even Europa. Ultimately, the search for life on other planets could start here on Earth at Lake Vostok.
Drilling is restricted to 3590 meters (2.2 miles) below the surface ice (just a few hundred meters above the lake) as the lake itself is considered inaccessible due to fears of contamination. A number of scientists have examined ice cores taken from above the lake, focusing on the so-called “accretion ice” at the base of these cores. Accretion ice was once lake water that later froze and adhered to the overlying ice sheet—and what’s in that ice might therefore provide clues to what’s in the lake itself.

Radar satellite image of Lake Vostok (Credit: NASA)
Radar satellite image of Lake Vostok (Credit: NASA)

Lake Vostok has made news again because of its most recent published findings  shared recently in PLOS ONE. Scientists led by Yury Shtarkman, a postdoc at Bowling Green State University in Ohio, identified a startlingly diverse array of microbes in the accretion ice—the most diverse suggested yet.

By cultivating and sequencing nucleic acids found in the ice, they identified more than 3500 unique genetic sequences (mostly from bacteria, but there were some multicellular eukaryotes). And those were similar to those of creatures found in all sorts of habitats on the planet: lakes, marine environments, deep-sea sediments, thermal vents, and, of course, icy environments.

Overall, researchers have generally observed low concentrations of such microbes relative to most environments on Earth. But they found the POTENTIAL for a complex microbial ecosystem of bacteria and fungi, and genetic sequences from crustaceans, mollusks, sea anemones, and fish. Note that Lake Vostok was in contact with the atmosphere millions of years ago, so a complex network of organisms likely populated the lake during that time. The team also found bacteria sequences that are common symbionts (organisms that live in symbiosis of each other) of larger species. There could be the poFEussibility of distinct ecological zones. As they are just studying accretion ice, the idea of fish actually living in the lake remains unclear.

A scientist traversing above the ice miles above the ice of Lake Vostok (Credit: M. Studinger, 2001)
A scientist traversing above the ice miles above the ice of Lake Vostok (Credit: M. Studinger, 2001)

Either way, this lake is far from being devoid of life. This does not conclusively lead us to the conclusion that life exists on other planets and moons in our solar system. But if abiogenesis is correct (still repudiated, but evidence is starting to suggest it is), it makes the case that much stronger for those seeking life beyond our planet.

Fractals and Scale Invariance















 
Fractals are plots of non-linear equations (equations in the result is used as the next input) which can build up to astonishingly complex and beautiful designs.  Typical of fractals is their scale invariance, which means that no matter how you view them, zoom in or zoom out, you will find self-similar and repeating geometric patterns.  This distinguishes from most natural patterns (though some are fractal-like, such as mountains or the branches of a tree, stars in the sky), in which as you zoom in or out completely changes what you see -- e.g., galaxies to stars down to atoms and sub-atomic nuclei and so forth).  Nevertheless, what is most (to me) fascinating about fractals is that they allow us to simulate reality in so many ways.

The Mandelbrot set shown above is the most famous example of fractal design known. 
The Mandelbrot set is a mathematical set of points whose boundary is a distinctive and easily recognizable two-dimensional fractal shape. The set is closely related to Julia sets (which include similarly complex shapes), and is named after the mathematician Benoit Mandelbrot, who studied and popularized it.

Mandelbrot set images are made by sampling complex numbers and determining for each whether the result tends towards infinity when a particular mathematical operation is iterated on it. Treating the real and imaginary parts of each number as image coordinates, pixels are colored according to how rapidly the sequence diverges, if at all.

More precisely, the Mandelbrot set is the set of values of c in the complex plane for which the orbit of 0 under iteration of the complex quadratic polynomial
z n+1 =z n squared +c
remains bounded.[1] That is, a complex number c is part of the Mandelbrot set if, when starting with z0 = 0 and applying the iteration repeatedly, the absolute value of zn remains bounded however large n gets.

In general, a fractal is a mathematical set that typically displays self-similar patterns, which means they are "the same from near as from far".[1] Often, they have an "irregular" and "fractured" appearance, but not always. Fractals may be exactly the same at every scale, or they may be nearly the same at different scales.[2][3][4][5] The definition of fractal goes beyond self-similarity per se to exclude trivial self-similarity and include the idea of a detailed pattern repeating itself.[2]:166; 18[3][6]

One feature of fractals that distinguishes them from "regular" shapes is the amount their spatial content scales, which is the concept of fractal dimension. If the edge lengths of a square are all doubled, the area is scaled by four because squares are two dimensional, similarly if the radius of a sphere is doubled, its volume scales by eight because spheres are three dimensional. In the case of fractals, if all one-dimensional lengths are doubled, the spatial content of the fractal scales by a number which is not an integer. A fractal has a fractal dimension that usually exceeds its topological dimension[7] and may fall between the integers.[2]

As mathematical equations, fractals are usually nowhere differentiable.[2][5][8] An infinite fractal curve can be perceived of as winding through space differently from an ordinary line, still being a 1-dimensional line yet having a fractal dimension indicating it also resembles a surface.[7]:48[2]:15

The mathematical roots of the idea of fractals have been traced through a formal path of published works, starting in the 17th century with notions of recursion, then moving through increasingly rigorous mathematical treatment of the concept to the study of continuous but not differentiable functions in the 19th century, and on to the coining of the word fractal in the 20th century with a subsequent burgeoning of interest in fractals and computer-based modelling in the 21st century.[9][10] The term "fractal" was first used by mathematician Benoît Mandelbrot in 1975. Mandelbrot based it on the Latin frāctus meaning "broken" or "fractured", and used it to extend the concept of theoretical fractional dimensions to geometric patterns in nature.[2]:405[6]

There is some disagreement amongst authorities about how the concept of a fractal should be formally defined. Mandelbrot himself summarized it as "beautiful, damn hard, increasingly useful. That's fractals."[11] The general consensus is that theoretical fractals are infinitely self-similar, iterated, and detailed mathematical constructs having fractal dimensions, of which many examples have been formulated and studied in great depth.[2][3][4] Fractals are not limited to geometric patterns, but can also describe processes in time.[1][5][12] Fractal patterns with various degrees of self-similarity have been rendered or studied in images, structures and sounds[13] and found in nature, technology, art, and law.

Much of this was taken from Wikipedia Mandelbrot Set and Fractal.

Green Technology Depends on Metals with Weird Names

Cover Image: January 2014 Scientific American Magazine
A supply of clean, affordable energy depends on little-known substances
Gold bar surronded by halo of hands
Image: Ross MacDonald
 
There's one problem with the silicon age: its magic depends on elements that are far scarcer than beach sand. Some aren't merely in limited supply: many people have never even heard of them. And yet those elements have become essential to the green economy. Alien-sounding elements such as yttrium, neodymium, europium, terbium and dysprosium are key components of energy-saving lights, powerful permanent magnets and other technologies. And then there are gallium, indium and tellurium, which create the thin-film photovoltaics needed in solar panels. The U.S. Department of Energy now counts those first five elements as “critical materials” crucial to new technology but whose supply is at risk of disruption. The department's experts are closely monitoring global production of the last three and likewise the lithium that provides batteries for pocket flashlights and hybrid cars.

Earlier this year the DoE took a major step by launching the Critical Materials Institute, a $120-million program to avert a supply shortage. Led by the Ames Laboratory in Iowa, with backing from 17 other government laboratories, universities and industry partners, the institute represents a welcome investment in new research. Unfortunately—like the original Manhattan Project—the program is driven more by the threat of international conflict than by ideals of scientific cooperation.
The appropriation made it through Congress almost certainly because of legislators' fear of China's dominance in many critical elements and Bolivia's ambition to become “the Saudi Arabia of lithium.”
The worries are probably inevitable. China—historically a prickly partner at best to the U.S.—effectively has much of the world's critical-materials market at its mercy. Take the rare earth elements neodymium, europium, terbium and dysprosium. Despite their name, rare earths are many times more common than gold or platinum and can be found in deposits around the world. In recent years, however, cheap labor and lax environmental regulation have enabled China to corner the global market, mining and refining well over 90 percent of rare earths.

At the same time, China has consistently fallen short of its own production quotas. In 2012 the U.S., the European Union and Japan, suspecting China was manipulating the market, filed a formal complaint with the World Trade Organization (WTO). China argues that production cutbacks were necessary for environmental cleanup. At press time, a preliminary ruling in October 2013 against China will likely be appealed. Meanwhile Japan has announced discovery of vast undersea deposits of rare earths, and the Americans, among others, are working to restart their own disused facilities. The shortages won't last.

Bolivia's lithium is a different story. The impoverished, landlocked country needs no artificial shortages to boost the market. As the lightest metal, lithium has unmatched ability to form compounds that can store electricity in a minimal weight and volume. At least half the world's known reserves are located in a relatively small stretch of the Andes Mountains, where Bolivia and Argentina share a border with Chile.

There's more at stake here than fancy gadgets for the rich. The point of critical materials is to use energy more efficiently. One fifth of the world still lives without access to clean, affordable electricity, a problem that unimpeded supplies of rare earths and lithium could eventually remedy. The hard part will be to prevent old international feuds from getting in the way of that goal. The U.S. can help by embracing the spirit of international development and cooperation. A start could be with the U.S. National Science Foundation, which already maintains an active office in Beijing. We need more such channels to encourage collaborative research on rare earths. Similarly, the strained relations between Washington and La Paz could benefit from signs of sincere U.S. willingness to assist Bolivia in developing the Uyuni salt flats, where a pilot processing plant began operating early in 2013.

Similar modest gestures could bring the world closer to a full-scale treaty on global mineral-supply security. A foundation of sorts has already been laid by efforts such as the Minamata Convention on Mercury, the recently adopted international pact to reduce emissions and use of the toxic metal.
Humanity's health and prosperity depend on the wise harnessing of natural resources. Narrow national interests and rivalries can only obstruct that process, ultimately leaving us all just that much poorer. The need for critical materials should catalyze international cooperation. After all, those materials can enlighten the world—literally.

Delayed-choice quantum eraser

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Delayed-choice_quantum_eraser A delayed-cho...