Friday, July 31, 2015

Allotropy: Why Winter Spells Trouble for the Tin Man

Tin is a commonplace metal that’s used industrially in a thousand different ways. From the solder that holds your computer’s motherboard together to the PVC plumbing under your sink, tin compounds are everywhere. In spite of its versatility, tin possesses an interesting physical property which is responsible for its tendency to wear down over time outdoors. This phenomenon, known as “tin pest”, is certainly not due a biological organism, but is widely mistaken for an oxidation reaction. Instead, tin pest happens thanks to something called allotropy—the metal’s atomic lattice can take on multiple different shapes, depending on the temperature it’s kept at. 

Read the rest of the post . . .

Thursday, July 30, 2015

How Insects' Legs Can Improve Man-Made Materials

In an effort to improve materials used in aviation and medicine, a team of Irish researchers is studying the legs of certain insects. Some features that appear to contribute to the legs' sturdiness don’t actually do so, they found, while others that would be expected to weaken the legs don’t have that effect.

These null results provide fresh insight into the surprising ways that nature works. But the new understanding also has the potential to contribute to applications of engineering materials shaped like the insects’ legs.
David Taylor’s team examined how the insects’ legs, which consist of light, thin, tubelike structures of cuticle material, buckle and bend in response to pressure.
“Many materials in nature have evolved to perform some mechanical purpose. So my research group is looking at insects, crabs, plant stems, eggs, etc.,” explained Taylor, a professor of mechanical engineering at Trinity College, Dublin.
In addition to studying how the natural materials work, said Taylor, engineers must also be sure they understand how they might fail.
Long, thin-walled tubes tend to maintain strength despite weighing less than other types of structures.
That provides an obvious benefit for designers of aircraft parts and hospital equipment such as catheters. But the tubes’ tendency to buckle, in the way that a drinking straw gives when bent, counters that advantage.
Taylor’s team set out to understand how differences in the detailed structure of insects’ legs influence their buckling behavior. They began with locusts, which are large and easy to work with, before moving on to other largish insects that live different lifestyles, including bees, stick insects and cockroaches.
Those insects not only use their legs in different ways in their natural environments; they also have different leg structures.
“The interesting aspect I found [in the Taylor group’s work] was the observation of the different cross-section shapes of the insect legs,” said Ahmer Wadee, a professor of nonlinear mechanics at Imperial College, London, who studies why metals and other materials buckle.
Stick insects have five ridges running down their legs. Bees’ legs have triangular cross-sections, with one large, flat surface used to carry pollen. And the legs of locusts and cockroaches have almost circular cross-sections.
Taylor and his team obtained their subjects locally. “We buy our locusts from a pet shop where they are normally used as food for the snakes. So we feel they get a slightly nicer and longer life with us,” he said. “In our care they live much longer than they normally would, even in the wild. And at the end of our work they are euthanized in a humane way."
To test the buckling behavior of a leg, on a living insect or detached from it, the team fixed one end by putting it in quick-drying polymer cement.
“We held it horizontally and pressed down on the other end using a testing machine which can record the applied force,” Taylor noted. “You can do something similar for yourself with a drinking straw or, better still, those tubes of plastic foam that are used to insulate water pipes.”
Timing was critical. “We needed to test the legs within a few minutes of cutting them off because they quickly dry out and become more stiff and brittle,” Taylor recalled.
The team found that buckling is a complex process that can occur in several different ways. Under a growing force, a leg suddenly becomes unstable, said Taylor, which can quickly lead to deformation and failure. In addition to experiments with the actual legs, they use computer simulations.
The experiments and simulations revealed that two types of buckling occur more or less simultaneously. These are local buckling, which is what happens when you press on the ends of a beer can, and ovalization buckling that occurs when the circular tube becomes oval and bends more easily.
Further investigation showed that different tube shapes confer no apparent advantage or disadvantage on insects’ legs.
“The ridges running along a stick insect’s legs look as if they are there to make the leg stiffer and more resistant to bending; we expected them to make the tubes about two-and-a-half times stronger,” Taylor said. “But we found out that they don’t; the leg would be just as good without them. So those ridges must have evolved for some other purpose that we don’t know about yet.”
The team also expected that pollen baskets might make bees’ legs weaker and more prone to buckling. “But we found they were just as good as if they had been circular,” Taylor said. “This shows that it’s possible to design non-circular cross sections that work well.”
A related piece of research compared the forces that insects’ legs experience with those that predictions indicate will cause the legs to break. Graduate student Eoin Parle found that when locusts jump, their legs experience more than half the failure force.
“That means there is a safety factor of less than two,” Taylor said. “That’s much smaller than you will find in most engineering structures.”
However, locusts have a safety mechanism, according to recent research by Malcolm Burrows, emeritus professor of biology at the University of Cambridge. “This is a specialized region in the tibia which buckles if the leg over-extends, but which contains the elastic protein resilin that returns the leg to its original shape,” Burrows said.
What does the Trinity College team’s research, which it presented at a meeting of the Society for Experimental Biology, suggest for the design of man-made structures?
“We’ve made a small contribution there by showing how certain types of buckling can be predicted using computer programs, and by showing that non-circular cross sections can be effective,” Taylor said. “Certainly a possible future application of this knowledge could be in the development of new designs for aircraft and other fields.”
--Peter Gwynne, Inside Science News Service

Read the rest of the post . . .

Wednesday, July 29, 2015

Paranormal (AC)tivity

Engineering designer Vic Tandy had just seen a ghost.  That, or he was losing his mind, he thought.


Read the rest of the post . . .

Tuesday, July 28, 2015

Party of Five! Physicists Discover Long-Sought ‘Pentaquark’ In Stroke of Luck

One week ago, an international team of scientists announced that they had discovered the pentaquark, an exotic, short-lived chunk of matter that had long eluded researchers. Its serendipitous discovery fills in one of the remaining gaps in the Standard Model, the prevailing but incomplete theory of particle physics, and it potentially points the way to weird “subatomic molecules” and other exotic forms of matter.

Read the rest of the post . . .

Friday, July 24, 2015

The Aftermath of 'Con

Greetings, science fans!
I know you missed us during our recent hiatus, but we’re back to bring you the latest and most exciting stories from the world of physics!

If you read our last post, you might have guessed that the Physics Central team has been doing some flying lately. A career in physics can take you all over the world (our resident Mathlete just returned from Taiwan) but this month’s adventures took us to beautiful San Diego, for the 46th Comic-Con International!

Asking yourself how on earth a bunch of physicists get sent to a comic book convention? You must not have heard of Spectra, the Laser Superhero! Spectra is an original comic series that follows the exploits of Lucinda Hene as she learns to use the powers of the laser and save the world from villainous plots, with the help of her friends! Written by a PhD physicist on staff here at APS, the comics are shipped to middle schools around the country with the aim of entertaining students, teaching some basic physics, and inspiring a passion for science. Since 2010, we’ve gone to SDCC every summer to talk about science outreach and get the word out about Spectra’s latest showdown against baddies like the evil Miss Alignment, or Lucy's nefarious swim coach Henri Toueaux. You can read all of Spectra’s adventures free online, along with our other PhysicsQuest comics, or order hard copies along with activity kits if you know a budding scientist! Who knows--if they learn to love physics, maybe someday they'll have a job that takes them to such a crazy and magical place!
Enjoy the comics, and check out some of our photos from Comic-Con 2015 below.

How many physicists does it take to put together a booth?
Miss Alignment is back in Spectra 7: High Intensity!
After a nightmare of PVC and duct tape, the Physics Central team is proud of their booth.

Dave, our illustrator, hands out comics to some new fans,
with the help of Emily, APS News' science writer!

Cosplayers abound, as James explains who we are and what we do.
You're never too young to start learning about physics!

The crowd inside the convention hall is pretty intense.

The crowd outside is even worse!

Doctor Yi Suchong shows off his genuine Edison Wax Cylinder record.

Sims love science comics!

So do delivery witches...

...and knights...

...and princesses!


I met a Left Shark...
...and saw some weird recursions...
...along with some folks trying to get their live-action Thundercats movie off the ground.
Becky, the author of Spectra, was on a few panels about science and outreach,
and Dave revealed his superpower to us! What, you think they give Legion rings to just anybody?
Hope you liked the gallery, and we hope to see you next year; same time, same place! (Booth 2207, as all our loyal fans know)





Read the rest of the post . . .

Tuesday, July 21, 2015

Clearing the Air: Why You Get Gassy on the Plane

Surprisingly, it's not just the food.

If you've ever gotten unusually bloated on an airplane, you might have chalked it up to the stress of traveling, carbonated drinks, or the fact that you wouldn't really think twice about passing gas if not for the person sitting right next to you. But fasten your seatbelts and lock your tray tables; we're exploring the physics behind the very real phenomenon of airplane flatulence, and by the time we land you'll have an indisputable excuse for your seat-mate. It may ease the social turbulence some to point out the irony of the situation: our increased tendency for in-flight flatulence is largely due to something called the ideal gas law.


Read the rest of the post . . .

Friday, June 26, 2015

Of Mice And Magnets

Image credit:mouse: Baggie Bird 1 http://bit.ly/1LpXV9T, compass: wikimedia commons 
http://bit.ly/1H9va0c, illustration by Michael Greshko
Quantum mechanics governs the quirky, counter-intuitive way the world works at the small scales of atoms and subatomic particles. It might also be important for helping animals understand their place in their surroundings. New research suggests that wood mice, commonly found in Europe, have a built-in compass that exploits quantum processes, the first seen in a wild mammal.

According to a study in Scientific Reports published on April 29, wood mice placed in a container prefer to build their nests in the parts of the container closest to magnetic north and south. When researchers created an artificial magnetic field, the mice nested in line with the new north-south orientation. Scientists suspect that this compass sense comes from electrons dancing around in the mice's eyes.

Read the rest of the post . . .

Wednesday, June 24, 2015

When Science and Entertainment Work Together


“We’re here to inspire filmmakers,” says Rick Loverd, Program Manager of the Science and Entertainment Exchange, a program of the National Academy of Sciences. “We’re here to provide mainstream media content creators with great science.” Launched in 2008, the Exchange works to connect writers, producers, and industry executives with scientists and engineers, both to improve the overall quality of science in mainstream entertainment and to break down negative stereotypes of scientists themselves. On this week’s podcast, we delve into the world of science consulting, exploring what it takes to pull off a successful collaboration. According to Loverd, the key is to put the story first and try to find organic ways to ground it in science. “I don’t think you can steer Hollywood creatives toward something. You can just give them a better idea.”

That’s how the 2011 Marvel blockbuster Thor ended up with a backstory grounded in theoretical physics. When Caltech physicist Sean M. Carroll suggested that the title character travel to Earth via an Einstein-Rosen Bridge — a wormhole — the character of Jane Foster, originally a nurse, became a particle astrophysicist instead. That gave her a plausible reason be out in the desert of New Mexico when Thor arrives, explains UCLA postdoctoral scholar Kevin Peter Hickerson. Thinking through the physics to flesh out the backstory, Hickerson helped Marvel producers construct Jane Foster’s laboratory, which (in the movie) relies on high energy physics to detect signatures of dark matter coming from Thor’s hammer. “That was the sort of way in which, very organically to their creative process, a scientist was able to drop some facts and help the filmmakers make something feel slightly more plausible,” says Loverd.



Read the rest of the post . . .

Friday, June 19, 2015

Wrinkle In Time Divides Quantum World From Everyday Reality

Image credit: Alan Cleaver via flickr | http://bit.ly/1G3bRzX
Rights information: http://bit.ly/NL51dk
The world becomes a fuzzy, surreal place at its smallest levels, according to quantum physics. It has long been a mystery why strange quantum behavior is not seen at larger scales in everyday life. Now researchers find that the way Earth warps time could help explain this division.

One mind-boggling consequence of quantum physics is that atoms and subatomic particles can actually exist in states known as "superpositions," meaning they could literally be located in two or more places at once, for instance, until "observed" — that is, until they interact with surrounding particles in some way. This concept is often illustrated using an analogy called Schrödinger's cat, in which a cat is both dead and alive until beheld.

Superpositions are very fragile. Once disturbed in some way, they collapse or "decohere" to just a single outcome. As such, they often involve objects just a few particles large at most — the bigger an object in superposition is, the more difficult it is to keep it unperturbed. However, it is a mystery at what scale the realm of quantum physics ended and the one of classical physics begins, and why such a boundary exists in the first place.

Now researchers suggest that Einstein's theory of space and time could help explain this shift from quantum to classical physics.

Read the rest of the post . . .

Thursday, June 18, 2015

How to Plan a Physics Party

It's June, the academic year is over, it's time to celebrate! For those of you mad about physics or graduating with a physics degree at any level, how about a physics-themed party? We've compiled a few ideas below, but feel free to get creative and let us know your ideas in the comments. The world has far too few physics parties.


Read the rest of the post . . .