COLLEGE PARK, Md. – Researchers at the University of Maryland have captured the most direct evidence to date of a quantum quirk that allows particles to tunnel through a barrier like it’s not even there. The result, which is featured on the cover of the June 20 issue of Nature, may enable engineers to design more uniform components for future quantum computers, quantum sensors and other devices.
The new experiment is an observation of quantum (Klein) tunneling, a special case of a more ordinary quantum phenomenon. In the quantum world, tunneling allows particles like electrons to pass through a barrier even if they don’t have enough energy to actually climb over it. A taller barrier usually makes this harder and lets fewer particles through.
Klein tunneling occurs when the barrier becomes completely transparent, opening up a portal that particles can traverse regardless of the barrier’s height. Scientists and engineers from the Center for Nanophysics and Advanced Materials(CNAM), the Joint Quantum Institute (JQI) and the Condensed Matter Theory Center (CMTC), with appointments in materials science and engineering, as well as physics, have made the most compelling measurements yet of the effect.
“Klein tunneling was originally a relativistic effect, first predicted almost a hundred years ago,” said Ichiro Takeuchi, a UMD professor of materials science and engineering (MSE) and the senior author of the new study. “Until recently, though, you could not observe it.”
It was nearly impossible to collect evidence for Klein tunneling where it was first predicted—the world of high-energy quantum particles moving close to the speed of light. But in the past several decades, scientists have discovered that some of the rules governing fast-moving quantum particles also apply to the (comparatively) sluggish particles traveling near the surface of some unusual materials.
One such material—which researchers used in the new study—is samarium hexaboride (SmB6), a substance that becomes a topological insulator at low temperatures. In a normal insulator like wood, rubber or air, electrons are trapped, unable to move even when a voltage is applied. Thus, unlike their free-roaming comrades in a metal wire, electrons in an insulator can’t conduct a current.
Topological insulators such as SmB6 behave like hybrid materials. At low enough temperatures, the interior of SmB6 is an insulator, but the surface is metallic and gives electrons some freedom to move around. Additionally, the direction that the electrons move becomes locked to an intrinsic quantum property called spin that can be oriented up or down. Electrons moving to the right will always have their spin pointing up, for example, and electrons moving left will have their spin pointing down.
The metallic surface of SmB6 would not have been enough to spot Klein tunneling, though. It turns out that Takeuchi and colleagues needed to transform the surface of SmB6 into a superconductor—a material that can conduct electrical current without any resistance.
To do this, they put a thin film of SmB6 atop a layer of yttrium hexaboride (YB6). When the whole assembly was cooled to just a few degrees above absolute zero, the YB6 became a superconductor, and, due to its proximity, the metallic surface of SmB6 became a superconductor, too.
It was a “piece of serendipity” that SmB6 and its yttrium-swapped relative shared the same crystal structure, said Johnpierre Paglione, a coauthor of the new paper who is a physics professor at UMD and the director of CNAM. “However, the multidisciplinary team we have was one of the keys to this success,” Paglione said. “Having experts on topological physics, thin-film synthesis, spectroscopy and theoretical understanding really got us to this point.”
The combination proved the right mix to observe Klein tunneling. By bringing a tiny metal tip into contact with the top of the SmB6, the team measured the transport of electrons from the tip into the superconductor. They observed a perfectly doubled conductance—a measure of how the current through a material changes as the voltage across it is varied.
“When we first observed the doubling, I didn’t believe it,” Takeuchi said. “After all, it is an unusual observation, so I asked my postdoc Seunghun Lee and research scientist Xiaohang Zhang to go back and do the experiment again.”
When Takeuchi and his experimental colleagues convinced themselves that the measurements were accurate, they didn’t initially understand the source of the doubled conductance. So they started searching for an explanation. It was Victor Galitski, a JQI Fellow, UMD physics professor and member of CMTC, who suggested that Klein tunneling might be involved. “At first, it was just a hunch,” Galitski said. “But over time we grew more convinced that the Klein scenario may actually be the underlying cause of the observations.”
UMD research scientist Valentin Stanev took Galitski’s hunch and worked out a careful theory of how Klein tunneling could emerge in the SmB6 system—ultimately making predictions that matched the experimental data well.
The theory suggested that Klein tunneling manifests itself in this case as a perfect form of Andreev reflection, an effect present at all metal-superconductor boundaries. Andreev reflection can occur whenever an electron from the metal hops onto a superconductor. Inside the superconductor, electrons are forced to live in pairs, so when an electron hops on, it picks up a buddy.
In order to balance the electric charge before and after the hop, a particle with the opposite charge—which scientists call a hole—must reflect back into the metal. This is the hallmark of Andreev reflection: an electron goes in, a hole comes back out. And since a hole moving in one direction carries the same current as an electron moving in the opposite direction, this whole process doubles the overall conductance—the signature of Klein tunneling through a junction of metal and a topological superconductor
In conventional metal-superconductor junctions, there are always some electrons that don’t hop onto the superconductor. They scatter off the boundary, reducing the amount of Andreev reflection and preventing an exact doubling of the conductance.
But because the electrons in the surface of SmB6 have their direction of motion tied to their spin, electrons near the boundary can’t bounce back—meaning that they will always transit straight into the superconductor.
“Klein tunneling had been seen in graphene as well,” Takeuchi said. “But here, because it’s a superconductor, I would say the effect is more spectacular. You get this exact doubling and a complete cancellation of the scattering, and there is no analog of that in the graphene experiment.”
Junctions between superconductors and other materials are ingredients in some proposed quantum computer architectures, as well as in precision sensing devices. The bane of these components has always been that each junction is slightly different, Takeuchi said, requiring endless tuning and calibration to reach the best performance. But with Klein tunneling in SmB6, researchers might finally have an antidote to that irregularity.
“In electronics, you know, device-to-device spread is the number one enemy,” Takeuchi said. “Here is a phenomenon that gets rid of the variability.”
The paper had 8 authors in addition to Takeuchi, Paglione, Lee, Zhang, Galitski and Stanev: Drew Stasak, a former research assistant in MSE; Jack Flowers, a former graduate student in MSE; Joshua S. Higgins, a research scientist in CNAM and the department of physics; Sheng Dai, a research fellow in the department of chemical engineering and materials science at the University of California, Irvine (UCI); Thomas Blum, a graduate student in physics and astronomy at UCI; Xiaoqing Pan, a professor of chemical engineering and materials science and of physics and astronomy at UCI; Victor M. Yakovenko, a JQI Fellow, professor of physics at UMD and a member of CMTC; and Richard L. Greene, a professor of physics at UMD and a member of CNAM.
This article originally appeared on UMD Right Now.
June 19, 2019
Perfect Quantum Portal Emerges at Exotic Interface
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The University of Maryland partners with NIST on a number of research centers, including the Joint Center for Quantum Information and Computer Science, Joint Quantum Institute, and Institute for Bioscience and Biotechnology Research.