Corkscrew Photons May Leave Behind a Spontaneous Twist

A new prediction argues that some materials might experience a torque when they are hotter than their surroundings. (Credit: E. Edwards/JQI)

 

Everything radiates. Whether it's a car door, a pair of shoes or the cover of a book, anything hotter than absolute zero (i.e., pretty much everything) is constantly shedding radiation in the form of photons, the quantum particles of light.

A twin process—absorption—is usually also present. As photons carry away energy, passers-by from the environment can be absorbed to replenish it. When absorption and emission occur at the same rate, scientists say that an object is in equilibrium with its environment. This often means that object and environment share the same temperature.

Far away from equilibrium, new behaviors can emerge. In a paper published August 1, 2019 as an Editors’ Suggestion in the journal Physical Review Letters, scientists at JQI and Michigan State University suggest that certain materials may experience a spontaneous twisting force if they are hotter than their surroundings.

"The fact that a material might feel a torque due to a temperature difference with the environment is very unusual," says lead author Mohammad Maghrebi, a former JQI postdoctoral researcher who is now an assistant professor at Michigan State University.

The effect, which hasn't yet been observed in an experiment, is predicted to arise in a thin ribbon of a material called a topological insulator (TI)—something that allows electrical current to flow on its surface but not through its innards.

In this case, the researchers made two additional assumptions about the TI. One is that it is hotter than its environment. And another is that the TI has some magnetic impurities that affect the behavior of electrons on its surface.

These magnetic impurities interact with a quantum property of the electrons called spin. Spin is part of the basic character of an electron, much like electric charge, and it describes the particle’s intrinsic angular momentum—the tendency of an object to continue rotating. Photons, too, can carry angular momentum.

Although electrons don’t physically rotate, they can still gain and lose angular momentum, albeit only in discrete chunks. Each electron has two spin values—up and down—and the magnetic impurities ensure that one value sits at a higher energy than the other. In the presence of these impurities, electrons can flip their spin from up to down and vice versa by emitting or absorbing a photon that carries the right amount of energy and angular momentum.

Maghrebi and two colleagues, JQI Fellows Jay Deep Sau and Alexey Gorshkov, showed that radiation emanating from this kind of TI carries angular momentum skewed in one rotational direction, like a corkscrew that twists clockwise. The material gets left with a deficit of angular momentum, causing it to feel a torque in the opposite direction (in this example, counterclockwise).

The authors say that TIs are ideal for spotting this effect because they play host to the right kind of interaction between electrons and light. TIs already link electron spin with the momentum of their motion, and it's through this motion that electrons in the material ordinarily absorb and emit light.

If an electron on the surface of this particular kind of TI starts with its spin pointing up, it can shed energy and angular momentum by changing its spin from up to down and emitting a photon. Since the TI is hotter than its environment, electrons will flip from up to down more often than the reverse. That’s because the environment has a lower temperature and lacks the energy to replace the radiation coming from the TI. The result of this imbalance is a torque on the thin TI sample, driven by the random emission of radiation.

Future experiments might observe the effect in one of two ways, the authors say. The most likely method is indirect, requiring experimenters to heat up a TI by running a current through it and collecting the emitted light. By measuring the average angular momentum of the radiation, an experiment might detect the asymmetry and confirm one consequence of the new prediction.

A more direct—and likely more difficult—observation would involve actually measuring the torque on the thin film by looking for tiny rotations. Maghrebi says that he's brought up the idea to several experimentalists. "They were not horrified by having to measure something like a torque, but, at the same time, I think it really depends on the setup," he says. "It certainly didn't sound like it was impossible."

Story by Chris Cesare: https://jqi.umd.edu/news/corkscrew-photons-may-leave-behind-spontaneous-twist

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Davoudi, Manucharyan Receive DOE Early Career Research Funding

Zohreh Davoudi and Vladimir Manucharyan are among the 73 scientists selected by the Department of Energy for Early Career funding. Davoudi’s proposal, Analog and Digital Quantum Simulations of Strongly Interacting Theories for Applications in Nuclear Physics was chosen by the Office of Nuclear Physics. Manucharyan’s proposal, Realization of a Quantum Slide Rule for 1+1 Dimensional Quantum Field Theories Using Josephson Superconducting Circuits was selected for funding by the Office of Advanced Scientific Computing Research.

Davoudi and Manucharyan will each receive $750,000 over five years. The list of awardees and their abstracts can be seen here.

 

Alicia Kollár Joins UMD Physics

Alicia KollárAlicia Kollár

Alicia Kollár joins the Department of Physics on August 1, 2019 as the Chesapeake Assistant Professor of Physics.

Kollár holds a bachelor’s degree in physics from Princeton University, and earned her doctorate in applied physics at Stanford University in 2016, working on the design and construction of a multimode cavity-BEC apparatus to study superradiant self-organization. She was a National Defense Science and Engineering Fellow at Stanford, and after graduating continued for one year as a postdoctoral scholar. She then accepted a Princeton Materials Science Postdoctoral Fellowship to work on quantum simulation of solid-state physics using circuit QED lattices; that research was recently featured in Physics World.

At UMD, Kollár will be a Fellow of the Joint Quantum Institute and the newly-formed Quantum Technology Center, a collaborative effort between the A. James Clark School of Engineering and the College of Computer, Mathematical, and Natural Sciences to establish UMD as the nation’s leading center for academic quantum technology research and education.

 

Mirrors on the Moon

Along with Neil Armstrong and Buzz Aldrin, University of Maryland scientists left a lasting mark on the moon when Apollo 11 landed there 50 years ago this week, one that is still imprinting on the world of physics.

That’s because a piece of equipment the astronauts left behind—a small panel of 100 mirrors designed by UMD physicists Doug Currie and the late Carroll Alley and a national team—remains in use for experiments. It may soon get an upgrade, too, thanks to NASA’s new project to send astronauts back to the moon by 2024 and, eventually, to Mars.

Called the lunar laser ranging array, it works in tandem with two others placed by the Apollo 14 and 15 missions in 1971, and provides a target for lasers beamed from telescopes on Earth. The bounce-back from those pulses enables precise measurements of distance that in the past five decades have led to discoveries ranging from the moon’s liquid core to confirming that Earth’s continents are still (slowly) moving.

In fact, the arrays are responsible for “really the only verification” of some aspects of Einstein’s general theory of relativity, said Currie, now a professor emeritus at UMD.

“Science has come out of it remarkably,” he said.

There’s plenty more to learn, as Currie has been working with the National Laboratories of Frascati, Italy, and commercial space company Moon Express to get a new generation of arrays onto the moon. NASA announced earlier this month that the arrays will be one of 12 experiments placed on future payload missions as part of the Artemis lunar program and in partnership with private space companies.

With measurements exponentially more accurate, Currie hopes the new instruments shed light on mysteries like dark energy and dark matter. “The gain we will have with the next generation is significant,” Currie said. “It allows us to chase in the direction of some of the fundamental questions of physics.”

Article by Liam Farrell, reprinted from Maryland Today

Read more about Carroll Alley.

Read more about Doug Currie's new retroreflectors.

Watch an ABC News interview with Doug Currie.about the 50th anniversary of Apollo 11.