Butterflies Inspire Anti-Counterfeit Technology

Image credit: 

Creativity+ Timothy K Hamilton via Flickr

    Rights information: 

http://bit.ly/cGotEb

A Canadian company is fighting counterfeiters by employing one of the most sophisticated structures in nature: a butterfly wing. 

 

To be precise, Nanotech Security Corp. in Vancouver is using the natural structure of the wings of a Morpho butterfly, a South American insect famous for its bright, iridescent blue or green wings, to create a visual image that would be practically impossible to counterfeit. The technology was developed at British Columbia’s Simon Fraser University, and licensed to the company.

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Angry Birds: Furious Forces! Review

Image Credit: National Geographic

With over 1.7 billion downloads, the suite of Angry Birds games has dominated the mobile gaming market for the past few years. During the game's meteoric rise, one science writer has taken a keen interest in the physics behind this game.

Physics professor and Angry Birds aficionado Rhett Allain has been blogging about the physics behind the various angry birds with his motion-tracking software and physics know-how. Now, he's written a book to boot!

But Allain's new book, Angry Birds Furious Forces!, takes a different approach than many of his blog posts. Instead of providing the detailed analysis of his blog posts, Allain incorporates the Angry Birds universe to teach five basic areas of physics: mechanics, sound and light, thermodynamics, electricity and magnetism, and "particle physics and beyond."

Nonetheless, this book only vaguely resembles a physics textbook. It's full of bright graphics, costumed Angry Birds, and a few of National Geographic's iconic photos overlaid with some Angry Bird Photoshop magic. Consequently, I found myself breezing through the five sections of the book fairly quickly.

The heart of each section covers a few basic physics principles such as circular motion, the Doppler effect, and the speed of sound. Nearly every page is also littered with fun facts (e.g. "salted ice can be cold enough to 'burn' your skin) and related experiments you can do at home.

Profile Page for Matilda, the explosive-egg-dropping bird.
Image Credit: National Geographic

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How to Perfectly Swim the Chesapeake Bay

I started this post yesterday thinking this would be a simple, interesting math problem.  Turns out I was wrong.  Here it is, a day late and one equation short.  This past Sunday I participated in the Great Chesapeake Bay Swim.  It's a swim that starts on the western shore of the bay at Sandy Point State Park and ends 4.4 miles later on the eastern shore at Hemingway's Marina.  The rules are simple, get in the water and swim to the other side while staying between the spans of the Chesapeake Bay Bridge.  The Bay Swim is an Annapolis tradition and has been going on for 22 years.  The currents make it a very challenging course, meaning that by the time I'd finished I'd most likely swum farther than the 4.4 miles of the bay.  I also had to constantly change my swimming angle with respect to the shore to make sure I didn't get sucked out to sea.  After recovering from the "race" I wanted to go back and find out 3 things; the angle at which I should have been swimming to go forward but not get swept out,  how far I actually swam,  and if I was doing this perfectly, how long should it have taken me.  So here are my calculations.  Hopefully this will be useful to someone next year!


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PODCAST:The Physics of Vinyl (and other records)

This week on the Physics Central Podcast we're talking about the physics of vinyl records. How do records record sound, and why can't you make a record out of wood or ice or some other material? (A: You CAN! It just might not sound very good!).




One of my favorite bands, the Swedish-based Shout Out Louds, recently released a new album, featuring a song called "Blue Ice." The song is about "fading devotion." As part of their publicity efforts to promote the album, the band sent 10 lucky individuals a kit that allowed them to create a record of the new song out of ice. Here's a video showing how to make an ice record (you need a pre-stamped mold), and a recording of the final product (not great, but still awesome):


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Luis Alvarez: Master Inventor

Luis Alvarez
Image: Dutch National Archives

The physicists of yesteryear were a colorful bunch, often dabbling in one discipline for a time before jumping into something entirely new. To many, the bongo-playing, safe-cracking, Nobel Prize-winning Richard Feynman is the quintessential renaissance-man scientist.

There were others. One of Feynman's contemporaries, Luis Alvarez was the man who could seemingly build anything. He was everywhere and played an important role in a surprising number of the big physics discoveries during the middle of the century. 

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Whistleblowing in Science

Last week, the Guardian published several articles revealing an extensive, intrusive monitoring program hosted by the National Security Administration. Apparently, the NSA has required cell service provider Verizon to hand over huge troves of data covering all of its customers — data including call times, call recipients, and the length of conversations.

Edward Snowden, NSA Whistle Blower.
Image Credit: The Guardian

The source of the top-secret information remained anonymous at first but revealed himself yesterday as Edward Snowden, an IT contractor working for the NSA.

Snowden's revelations has galvanized many U.S. citizens to rally against the NSA's program, and Snowden has surely made some new enemies working for U.S. intelligence agencies. As of yesterday, Snowden's future remained uncertain while he stayed in a luxury hotel in Hong Kong.

In light of Snowden's actions, I decided to look back at two curious whistleblowing cases from the world of science: one involving a clandestine nuclear program and the other surrounding biotechnology price-fixing.
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A Post of Ice and Fire, but Mostly Fire

Daenerys and her dragon.  (Photo: HBO)

Sunday's Game of Thrones episode, "The Rains of Castamere," sent everyone who hadn't read the books into a tailspin.  There won't be any spoilers from Sunday in this post because if the great wide internet can keep a secret for 13 years, its not going to be spoiled here.  Since no one can seem to get this recent episode out of their minds, might as well add some physics.  There have already been great  articles about the "ice" part of A Song of Ice and Fire, but not many about the fire. Particularly the mythical Dragonfire.  We learned this season that "dragon glass" can kill White Walkers.  In previous seasons it was revealed that Harrenhal is in ruins because of dragonfire.  How hot does dragon fire have to be?  What makes dragon glass so special?  Could Daenerys's dragons attack the Red Keep of Kings Landing now even though they are small?


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Black Hole Cores May Not Be Infinitely Dense

The cores of black holes may not hold points of infinite density as currently thought, but portals to elsewhere in the universe, theoretical physicists say.

Artist's concept of a supermassive black hole

Image credit: NASA/JPL-Caltech

 A black hole possesses a gravitational field so powerful that not even light can escape. A black hole generally forms after a star dies in a titanic explosion known as a supernova, which crushes the remaining core into dense lumps.

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PODCAST: Tornado Physics

NOAA Photo Library, NOAA Central Library;
OAR/ERL/National Severe Storms Laboratory (NSSL) 

Last week, the Oklahoma City area was hit with a tornado that claimed 18 lives, including those of two veteran storm chasers. The tornado came only a few weeks after 24 people were killed by a tornado that hit Moore, Oklahoma on May 20th. Tornados are more common in the central part of the United States than anywhere else in the world. How do these natural monsters form, and what do scientists need to know to keep people safe from them? This week on the Physics Central podcast we talk to Harold Brooks, a research meteorologist at the National Oceanic and Atmospheric Administration (NOAA) National Severe Storms Laboratory in Norman, Oklahoma. Brooks shares with us the physics behind tornado formation, the many ways that scientists try to gather data on these rare and unpredictable events, and what they hope to learn about them in the future.
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Quantum Banking Comes To New York

At 1:00pm on Tuesday, June 11, 2013.
20 Rockefeller Plaza, New York NY.
Basement Level.

20 Rockefeller Plaza, New York, NY
Image Credit: Brad Holt

The Quantum Bank will open for business.

The installation is the brainchild of the conceptual artist Jonathon Keats. For Keats, whose previous work includes: copyrighting his brain and auctioning futures contracts on his 6 billion neurons; a stint in extra-dimensional real estate -- in one day he sold 172 extra-dimensional Bay Area plots in the multidimensional space-time proposed by string theory; photosynthetic gastronomy that looks more like a plant watching television;  and an attempt to engineer God (or, rather, something more God-like) starting with cyanobacteria and the fruit fly -- the quantum bank plays the market with the science of uncertainty.

Keats's theoretical foundation for quantum banking comes from Schrödinger's cat.

In 1935, Edwin Schrödinger proposed a thought experiment to illustrate the apparent conflict he saw in the theory quantum mechanical superposition.  In his famous thought experiment, Schrödinger proposes a cat is trapped in a steel box with a vial of poison and a tiny sample of radioactive material. If an atom of radioactive material decays (a quantum mechanical process), the poison will be released and the cat dies. One could assume that if no radioactive atom decays, the cat is still alive.

The quantum theory of superposition stipulates that quantum events have definite values only when they are observed. Schrödinger argued that if at any moment it were equally probable that an atom had decayed and had not decayed, then the cat too would be in a superposition of alive and dead so long as the box remained closed.

Jonathon Keats's quantum banking extrapolates Schrödinger's cat to Schrödinger cash.

Accessed by the Quantum ATM, the Quantum Bank will open with seven billion accounts. One for every person on the planet, according to Keats. Anyone will be able to deposit any amount of any currency in the Quantum Bank.

Inside the Quantum ATM, a tiny uranium glass sphere is imbedded in a grid of seven billion boxes. Each box corresponds to one of seven billion quantum bank accounts uniquely identified by their coordinates.

When one dollar is deposited, the uranium will emit an alpha particle. The dollar is deposited into whichever box the alpha particle passes through and there is now one dollar in that account at the Quantum Bank.

However, Keats isn't planning on counting his pennies. Much like putting the cat in a metal box, Keats is encasing the ATM in metal and preventing any measurements. If no measurement is made as to which box the alpha particle passes through, the quantum regime prevails: the particle will pass through all seven billion boxes. All seven billion accounts will be credited -- in a quantum superposition of cash, and no-cash.

As Keats writes, "Anyone will be able to claim a free account, sharing as much of their wealth as they wish or simply living off others' quantum deposits."

Bam. Free money.

Of course, all withdrawals will be in quantum banknotes -- a currency that can be used anywhere, provided they are accepted.

 "Crucially," Keats writes, "[the Quantum Bank] will be a paragon of ethical business. Unlike most banks which are backed by faith, the Quantum Bank will be backed by physics. And the new economy that the Quantum Bank facilitates will subsist in a quantum-economic superposition."

Though Keats's installation may not be an economy to bank on, his project provokes current ideological economic questions.

Seated in the heart of the financial industry, the Quantum Bank will be open to the public until June 14th asking those who dare deposit, what is the reality of the dollar in our post-recession bitcoin-banking world?


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Quark Twain would like to thank her colleagues at APS and Physics Central for a lovely tenure writing for the Physics Buzz Blog. For more, follow Quark Twain's tweets!

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