Nav: Home

Physicist honored for finding new symmetry in space and time

November 01, 2016

The American Physical Society and the American Institute of Physics this month awarded the 2017 Dannie Heineman Prize for Mathematical Physics to Carl M. Bender of Washington University in St. Louis .

With this prize he joins the illustrious company of Stephen Hawking, Freeman Dyson, Murray Gell-Mann, Roger Penrose, Steven Weinberg and Edward Witten, among others.

Bender, the Wilfred R. and Ann Lee Konneker Distinguished Professor of Physics in Arts & Sciences, was cited "for developing the theory of PT symmetry in quantum systems and sustained seminal contributions that have generated profound and creative new mathematics, impacted broad areas of experimental physics, and inspired generations of mathematical physicists."

"I use physics to generate interesting problems, and then I use mathematics to solve those problems," Bender said. "My approach is to understand what's going on in the real world -- where we live -- by studying the complex world, which includes the real world as a special case."

He explains that everything physicists observe is on the real axis: all the numbers, positive or negative, rational or irrational, that can be found on a number line. But the real axis is just one line in the infinite plane of complex numbers, which includes numbers with "imaginary" parts. "The complex plane helps us to understand what's going on in the real world," he said.

"For example, why are the energy levels in an atom quantized? Why can the atom only have certain energies and not others? We don't understand this because we don't look in the complex plane. In the complex plane, the energy levels are quantized. They are smooth and continuous. But if you take a slice through the complex plane along the real axis, the energy is chopped into disconnected points. It is as though the ramp was removed from a multi-level parking garage, leaving disconnected levels."

How does Bender know which problem to pick, which problems might yield when pushed in this way? "You can smell it," he said. "Usually something is true because there is a clear argument for why it is true, but if it is true because 'everybody knows it is true,' then such a claim is potentially suspect."

Bender tells a charming story to illustrate what he means. Many years ago his father, a high school physics teacher, put Bender's son to bed by telling him the story of the brachistochrone, a well-known physics problem that had been solved 300 years before. But, as Bender listened from another room, he realized the accepted version was wrong.

"My father said, 'This is a classic physics problem; its solution is well known.' But I said, 'That's no longer the right answer.'" Working with an undergraduate eager for a challenge, Bender updated the brachistochrone problem to take into account Einstein's theory of relativity.

So, Bender listens for physics that produces the dull thunk of an unexamined assumption instead of ringing true, but there is more to it than that. He also is unusually good at seeing moveable patterns: in letters, in chess positions, in musical compositions as well as in mathematical functions.

His presentation slides often include anagrams -- he might introduce his name and university as Crab Lender of Washing Nervy Tuitions. He likes to play speed chess and included in his Harvard dissertation a postal chess game that lasted a year and a half. (It was Appendix H, and none of the examiners noticed it.) He also has mastered most of the repertoire for the clarinet and even considered becoming a professional musician.

But theoretical physics isn't a monologue; it is a conversation. And theoretical physicists, like mathematicians, take ideas for a test drive by describing them to their peers, who help by trying as hard as they can to find flaws.

Because there are only a few hundred highly active mathematical physicists in the world, to have these theory-testing conversations, Bender often travels abroad to conferences or on sabbatical. "The interaction and discussions have enriched my productivity immensely," he said.

Bender is currently an International Professor of Physics at the University of Heidelberg, Visiting Professor at King's College London, and Member of the Higgs Center in Edinburgh.

While mathematicians declare success once they've convinced other mathematicians of the rigor of their proofs, physicists -- while encouraged by the agreement of their peers -- are not satisfied until nature also expresses an opinion. They want experimental proof.

And Bender, at heart, is a physicist. "I started out being interested in experimental science and I was good at it," he said. "Built a lab in my house, built my ham rig, ran a radio repair business, etc. But I think experimental science was too slow for me. I preferred to work with pencil and paper at my own pace.

"Physics is something you ultimately know is right or wrong, and mathematics is always right. So that's why physics is tricky, more dangerous," he added.

So "the best thing that ever happened" to Bender was the confirmation by experiment of a daring quantum-mechanical theory he and his former graduate student Stefan Boettcher proposed in 1998.

This is the PT symmetry cited in the Heineman Prize. Characteristically, he arrived at this theory by questioning one of the fundamental assumptions of quantum mechanics.

This axiom states that certain aspects of quantum mechanics must be Hermitian, meaning, among other things, that they must remain in the realm of real numbers. "But insisting that quantum mechanics must be Hermitian," Bender said, "is like saying all numbers must be even."

Bender and Boettcher proposed a new non-Hermitian theory, a complex generalization of quantum mechanics, which they called PT-symmetric (parity-time symmetric) quantum mechanics. Parity is the symmetry operation that turns your left hand into your right. Time reversal just means that time runs backward rather than forward.

In two famous Nobel-winning experiments, other physicists had shown that the universe is neither parity nor time symmetric. A left-handed laboratory can obtain different experimental results from a right-handed laboratory, and a laboratory traveling backward in time can obtain different results from a laboratory traveling forward in time.

What Bender and Boettcher argued is that if you reflect both space and time, everything returns to normal. This is because a parity reflection can be exactly compensated by a time reversal.

Bender and Boetccher also made a prediction based on their theory, so that the theory was falsifiable. The prediction was that PT-symmetric systems can undergo a transition from real to complex energies. PT symmetry would be broken at this transition, and the behavior of the system would change in an interesting -- and observable -- way.

The neat thing about this was that some optical systems obey equations similar to the quantum-mechanical ones that govern atoms. So PT-symmetric systems can be constructed from simple optical components, such as lasers and optical fibers. "The trick," Bender said, "is to couple a component with gain, where energy flows into the system, to a component that exhibits loss, where energy flows out of the system."

The first experiment to confirm the theory was carried out by eight scientists at two universities in the United States and two in Canada, but was physically located at the University of Arkansas. The theory of PT symmetry has since been repeatedly verified by many other experiments.

Bender heard about the first experiment in 2008, nearly 10 years after publishing the theory. Demetrios Christodoulides of the University of Central Florida emailed him to say his group was pretty certain they had seen the PT phase transition. "If everything goes well, with a bit of luck, we may have an experimental explosion in the PT area," Christodoulides wrote.

"I was on cloud nine for weeks," Bender said. "It took me a long time to come down because never in my life did I think that I would ever predict anything that was directly observable in a laboratory experiment, not to mention a very simple experiment."
-end-


Washington University in St. Louis

Related Quantum Mechanics Articles:

New evidence for quantum fluctuations near a quantum critical point in a superconductor
A study has found evidence for quantum fluctuations near a quantum critical point in a superconductor.
Simulating quantum 'time travel' disproves butterfly effect in quantum realm
Using a quantum computer to simulate time travel, researchers have demonstrated that, in the quantum realm, there is no 'butterfly effect.' In the research, information--qubits, or quantum bits--'time travel' into the simulated past.
Orbital engineering of quantum confinement in high-Al-content AlGaN quantum well
Recently, professor Kang's group focus on the limitation of quantum confine band offset model, the hole states delocalization in high-Al-content AlGaN quantum well are understood in terms of orbital intercoupling.
A Metal-like Quantum Gas: A pathbreaking platform for quantum simulation
Coherent and ultrafast laser excitation creates an exotic matter phase with spatially overlapping electronic wave-functions under nanometric control in an artificial micro-crystal of ultracold atoms.
Fluid mechanics mystery solved
An environmental engineering professor has solved a decades-old mystery regarding the behavior of fluids, a field of study with widespread medical, industrial and environmental applications.
Quantum leap: Photon discovery is a major step toward at-scale quantum technologies
A team of physicists at the University of Bristol has developed the first integrated photon source with the potential to deliver large-scale quantum photonics.
Understanding mechanics and materials though evolution and biomaterials
Studying the evolution of bodily processes millions of years ago as well as the properties of today's biomaterials could improve soft robotics design and inform materials science research.
USTC realizes the first quantum-entangling-measurements-enhanced quantum orienteering
Researchers enhanced the performance of quantum orienteering with entangling measurements via photonic quantum walks.
A convex-optimization-based quantum process tomography method for reconstructing quantum channels
Researchers from SJTU have developed a convex-optimization-based quantum process tomography method for reconstructing quantum channels, and have shown the validity to seawater channels and general channels, enabling a more precise and robust estimation of the elements of the process matrix with less demands on preliminary resources.
What a pair! Coupled quantum dots may offer a new way to store quantum information
Researchers at the National Institute of Standards and Technology (NIST) and their colleagues have for the first time created and imaged a novel pair of quantum dots -- tiny islands of confined electric charge that act like interacting artificial atoms.
More Quantum Mechanics News and Quantum Mechanics Current Events

Trending Science News

Current Coronavirus (COVID-19) News

Top Science Podcasts

We have hand picked the top science podcasts of 2020.
Now Playing: TED Radio Hour

Listen Again: The Power Of Spaces
How do spaces shape the human experience? In what ways do our rooms, homes, and buildings give us meaning and purpose? This hour, TED speakers explore the power of the spaces we make and inhabit. Guests include architect Michael Murphy, musician David Byrne, artist Es Devlin, and architect Siamak Hariri.
Now Playing: Science for the People

#576 Science Communication in Creative Places
When you think of science communication, you might think of TED talks or museum talks or video talks, or... people giving lectures. It's a lot of people talking. But there's more to sci comm than that. This week host Bethany Brookshire talks to three people who have looked at science communication in places you might not expect it. We'll speak with Mauna Dasari, a graduate student at Notre Dame, about making mammals into a March Madness match. We'll talk with Sarah Garner, director of the Pathologists Assistant Program at Tulane University School of Medicine, who takes pathology instruction out of...
Now Playing: Radiolab

What If?
There's plenty of speculation about what Donald Trump might do in the wake of the election. Would he dispute the results if he loses? Would he simply refuse to leave office, or even try to use the military to maintain control? Last summer, Rosa Brooks got together a team of experts and political operatives from both sides of the aisle to ask a slightly different question. Rather than arguing about whether he'd do those things, they dug into what exactly would happen if he did. Part war game part choose your own adventure, Rosa's Transition Integrity Project doesn't give us any predictions, and it isn't a referendum on Trump. Instead, it's a deeply illuminating stress test on our laws, our institutions, and on the commitment to democracy written into the constitution. This episode was reported by Bethel Habte, with help from Tracie Hunte, and produced by Bethel Habte. Jeremy Bloom provided original music. Support Radiolab by becoming a member today at Radiolab.org/donate.     You can read The Transition Integrity Project's report here.