"You may use one side of one sheet of paper for notes."
A relic from my old trig class.
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DEAR READER

tannertan36
Stranger Things
AnasAbdin
he wasn't even looking at me and he found me
NASA
Today's Document

Product Placement

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roma★

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we're not kids anymore.

if i look back, i am lost

⁂
Not today Justin
Sade Olutola
RMH

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PUT YOUR BEARD IN MY MOUTH
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@hunebe
"You may use one side of one sheet of paper for notes."
A relic from my old trig class.
i paid $150 for this textbook
too fucking cool
Van Gogh - Altered Visionary
Dichromatic paintings?
I recently stumbled across a rather stunning idea. After visiting a design exhibit that modeled the visual experience of people with colorblindness, Kazunori Asada noticed that the paintings of Vincent Van Gogh on display had entered a new light, so to speak. Under the chromatically filtered light, Van Gogh’s more striking and curious color choices suddenly became natural and warm. It was if this was how they were meant to be viewed, Asada thought.
Did Vincent Van Gogh have a color vision deficiency?
Those of us with normal vision are able to differentiate the full range of visible wavelengths thanks to three different types of cone cell photoreceptors that, together, cover the range of the spectrum we are accustomed to seeing. Although they are most sensitive to blue, green and yellow-green light, they are termed “blue”, “green” and “red” receptors. This is known as “trichromacy”.
We probably all know someone who is colorblind, right? My dad is. There are three main classes of common “color-blindness”. These are termed “dichromacy”, since they are due to the lack of one photoreceptor. Protanopia is the lack of red receptors (their ROYGBIV rainbow looks like the one above), deuteranopia is the lack of green receptors, and tritanopia (the rarest) is the lack of blue receptors. What’s important is that these aren’t all-or-nothing situations. Someone’s vision can land on a very wide range of those deficiencies.
Asada developed a color vision simulation program that can convert any image to a close approximation of what colorblind people would see. You can play with it here, which I STRONGLY suggest you do. He also developed a free iOS and Android app that can take your photos through the eyes of the colorblind. I’ve played with it, and it’s awesome.
When you look at Van Gogh’s “Starry Night” above, the left side is the unchanged painting and the right side is moderate red receptor loss. Some of the more reddish and orange hues in the “normal” lefthand version become even yellows on the right, as we may expect for stars and moonlight. I think the contrast between the shadows and sky becomes more striking in the filtered version, too.
It’s definitely a matter of opinion, to some degree. Who knows what Van Gogh saw or intended us to see? But some paintings, like his sunflowers series, are even more striking in their differences. SImply put, they look more like actual sunflowers. Go and read Asada’s full analysis, complete with a bunch of side-by-side comparisons, and see for yourself.
Here’s the colorblindness simulator for you to play with your own images at home. Either way it’s the most interesting look at art through the lens of vision science since Monet’s ultraviolet eye.
This is an enlargement of an image just 50x50 micrometres, printed at the highest definition possible.
Images made up of metal-nanostructure pixels could be used for security or optical data storage.
Katherine Bourzac
12 August 2012
The highest possible resolution images — about 100,000 dots per inch — have been achieved, and in full-colour, with a printing method that uses tiny pillars a few tens of nanometres tall. The method, described today in Nature Nanotechnology1, could be used to print tiny watermarks or secret messages for security purposes, and to make high-density data-storage discs.
Each pixel in these ultra-resolution images is made up of four nanoscale posts capped with silver and gold nanodisks. By varying the diameters of the structures (which are tens of nanometres) and the spaces between them, it’s possible to control what colour of light they reflect. Researchers at the Agency for Science, Technology and Research (A*STAR) in Singapore used this effect, called structural colour, to come up with a full palette of colours. As a proof of principle, they printed a 50×50-micrometre version of the ‘Lena’ test image, a richly coloured portrait of a woman that is commonly used as a printing standard.
Joel Yang, a materials scientist A*STAR, who led the study, first noticed the effect when looking at metal nanoparticles under a light microscope. “We saw that we could control the colours, from red to blue, by controlling the size of the particles,” he says. Depending on its size, a metal nanostructure resonates with a particular wavelength of light — much like a guitar string resonates at a particular frequency depending on its length. Light at the right wavelength causes electrons on the surface of the metal nanostructure to resonate, and this determines the colour the structure reflects. This effect, called plasmon resonance, is well known to physicists. Yang is the first to come up with a way to take advantage of it to print high-resolution, full-colour images, says Jay Guo, an engineer at the University of Michigan in Ann Arbor, who was not involved with the work.
Click title to read more.
Two-Sensor Device Holds Early Detection Potential Researchers have created an ultrasensitive biosensor that could open up new opportunities for early detection of cancer and personalized medicine tailored to the specific biochemistry of individual patients. The device, which could be several hundred times more sensitive than other biosensors, combines the attributes of two distinctly different types of sensors, says Muhammad Alam, a Purdue Univ. professor of electrical and computer engineering. “Individually, both of these types of biosensors have limited sensitivity, but when you combine the two you get something that is better than either,” he says. Read more: http://www.laboratoryequipment.com/news-Biosensor-Hold-Medical-Diagnostic-Potential-051512.aspx
pronunciation | 'shwel-en-ahngst\ submitted by | Why So Serious? [traeumerin] submit words | here
Researchers Using Bio-Engineered Viruses to Power Nano Electronics
The researchers looked to viruses as a new material to work with because they reproduce rapidly and align far better than other materials, making them good candidates to accumulate a charge on one end of the virus.
The researchers then genetically engineered the virus with proteins that enhance the buildup of charge on the ends of the rod-shaped viruses. The viruses only attack other bacteria so are considered benign. The viruses are stacked onto thin films and then several thin films are layered to build up as much voltage as possible.
The Lawrence Berkeley Lab group isn’t the first to pursue viruses as a means for building up electric charge. Researchers at MIT in 2009 said they were able to wire a charge-building virus to a lithium ion battery. The Lawrence Berkeley Lab’s prototype was only able to generate about a quarter of the voltage of a triple A battery, but they believe that their approach to “viral electronics” can scale up.
(via Step on it: Virus could lead to motion-powered gadgets | Cutting Edge - CNET News)
Catalyst Sustainably Splits Hydrogen from Water Hydrogen gas offers one of the most promising sustainable energy alternatives to limited fossil fuels. But traditional methods of producing pure hydrogen face significant challenges in unlocking its full potential, either by releasing harmful carbon dioxide into the atmosphere or requiring rare and expensive chemical elements such as platinum. Now, scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have developed a new electrocatalyst that addresses one of these problems by generating hydrogen gas from water cleanly and with much more affordable materials. The novel form of catalytic nickel-molybdenum-nitride – described in a paper published online May 8, 2012 in the journal Angewandte Chemie International Edition – surprised scientists with its high-performing nanosheet structure, introducing a new model for effective hydrogen catalysis. Read more: http://www.laboratoryequipment.com/news-Catalyst-Sustainably-Splits-Hydrogen-from-Water-051112.aspx
Chinese Researchers Quantum Teleport Photons Over 60 Miles
Since 1997, researchers have been able to quantum teleport photons with a major record being set by researchers at the University of Science and Technology of China in Shanghai. In 2010, that team successfully teleported a photon over 16km. Now that same team has released new findings, in which they claim to have teleported photons nearly 100km, or over 60 miles.
Now, quantum teleportation isn’t quite the same thing as the teleportation in Star Trek. When researchers teleport a photon, they aren’t teleporting the actual photon, but rather the information contained in it through quantum entanglement. In essence, the second photon at the end of the teleport becomes the first one – or at least, it becomes an identical qubit of information. So the information is exchanged without actually travelling through the intervening distance. […]
[read more] [paper]
Recursive Drawing
Drawing programs don’t always have a “point”, even if they are fun. Recursive Drawing, however, aims to use a simple and addictive user-interface to explore how drawings could be translated into programming.
On the surface, it’s a purely fun tool (which you can, and should, play with!) to draw crazy-awesome things like Fibonacci trees (like in the video). But deep down, it’s an experiment in translating visual objects into programming commands. That’s called a spatial or visual programming environment, and it’s a way to disconnect the syntax of programming from the logic and math.
Environments like these also let non-English speakers and young people get introduced to programming skills without having to master the language itself. But if you don’t want to pay attention to all that, it’s just really FUN!
Previously: A dangerously addictive online fluid dynamics simulator and a particle/gravity simulator that really looks more like fireworks.
20 Things You Didn’t Know About Fire
1 Fire is an event, not a thing. Heating wood or other fuel releases volatile vapors that can rapidly combust with oxygen in the air; the resulting incandescent bloom of gas further heats the fuel, releasing more vapors and perpetuating the cycle.
2 Most of the fuels we use derive their energy from trapped solar rays. In photosynthesis, sunlight and heat make chemical energy (in the form of wood or fossil fuel); fire uses chemical energy to produce light and heat.
3 So a bonfire is basically a tree running in reverse.
4 Assuming stable fuel, heat, and oxygen levels, a typical house fire will double in size every minute.
5 Earth is the only known planet where fire can burn. Everywhere else: Not enough oxygen.
6 Conversely, the more oxygen, the hotter the fire. Air is 21 percent oxygen; combine pure oxygen with acetylene, a chemical relative of methane, and you get an oxyacetylene welding torch that burns at over 5,500 degrees Fahrenheit—the hottest fire you are likely to encounter.
7 Oxygen supply influences the color of the flame. A low-oxygen fire contains lots of uncombusted fuel particles and will give off a yellow glow. A high-oxygen fire burns blue.
8 So candle flames are blue at the bottom because that’s where they take up fresh air, and yellow at the top because the rising fumes from below partly suffocate the upper part of the flame.
9 Fire makes water? It’s true. Place a cold spoon over a candle and you will observe the water vapor condense on the metal…
10 …because wax—like most organic materials, including wood and gasoline—contains hydrogen, which bonds with oxygen to make H2O when it burns. Water comes out your car’s tailpipe, too.
11 We’ve been at this a long time: Charred bones and wood ash indicate that early hominids were tending thefirst intentional fires more than 400,000 years ago.
12 Nature’s been at it awhile, too. A coal seam about 140 miles north of Sydney, Australia, has been burning by some estimates for 500,000 years.
13 The ancient Greeks started fire with concentrated sunlight. A parabolic mirror that focuses solar rays is still used to ignite the Olympic torch.
14 Every 52 years, when their calendar completed a cycle, the Aztecs would extinguish every flame in the empire. The high priest would start a new fire on the ripped-open chest of a sacrificial victim. Fires fed from this flame would be distributed throughout the land.
15 Good burn: The 1666 Great Fire of London destroyed 80 percent of the city but also ended an outbreak of bubonic plague that had killed more than 65,000 people the previous year. The fire fried the rats and fleas that carried Yersinia pestis, the plague-causing bacterium.
16 The Peshtigo Fire in Wisconsin was the second deadliest blaze in United States history, taking 1,200 lives—four times as many as the Great Chicago Fire. Both conflagrations broke out on the same day: October 8, 1871.
17 America’s deadliest fire took place April 27, 1865, aboard the steamship Sultana. Among other passengers were 1,500 recently released Union prisoners traveling home up the Mississippi when the boilers exploded. The ship was six times over capacity, which helps explain the death toll of 1,547.
18 The Black Dragon Fire of 1987, the largest wildfire in modern times, burned some 20 million acres across China and the Soviet Union, an area about the size of South Carolina.
19 Spontaneous combustion is real. Some fuel sources can generate their own heat—by rotting, for instance. Pistachios have so much natural oil and are so prone to heat-generating fat decomposition that the International Maritime Dangerous Goods Code regards them as dangerous.
20 Haystacks, compost heaps, and even piles of old newspapers and magazines can also burst into flame. A good reason to recycle DISCOVER when you are done.
Impressive Examples of Infrared Photography
So what is infrared photography? Infrared Photography is capturing invisible light that shows incredible after effects. The infrared wavelengths usually ranges from 750-900nm. Your naked eye sees things as they naturally are, but just like radio waves, ultraviolet rays, gamma rays, and microscopic germs you eyes are blind to infrared. Basically speaking you are simply blocking out visible light while letting the invisible light come inside the camera lens.