Scientists find twisting 3D Raceway for Electrons in Nanoscale Crystal Slices

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Scientists find twisting 3D Raceway for Electrons in Nanoscale Crystal Slices

Scientists find twisting 3D Raceway for Electrons in Nanoscale Crystal Slices

Mysterious quantum properties in material point to new applications in electronics. Researchers have created an exotic 3D racetrack for electrons in ultrathin slices of a nanomaterial they fabricated at the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) The international team of scientists from Berkeley Lab, UC Berkeley, and Germany observed, for the first time, a unique behavior in which electrons rotate around one surface, then through the bulk of the material to its opposite surface and back.

The possibility of developing “topological matter” that can carry electrical current on its surface without loss at room temperature has attracted significant interest in the research community. The ultimate goal is to approach the lossless conduction of another class of materials, superconductors, but without the need for the extreme, freezing temperatures that superconductors require.

“Microchips lose so much energy through heat dissipation that it’s a limiting factor,” said James Analytis, a staff scientist at Berkeley Lab and assistant professor of physics at UC Berkeley who led the study, published in Nature. “The smaller they become, the more they heat up.”

The studied material, an inorganic semimetal called cadmium arsenide (Cd3As2), exhibits quantum properties – which are not explained by the classical laws of physics – that offer a new approach to reducing waste energy in microchips. In 2014, scientists discovered that cadmium arsenide shares some electronic properties withg raphene. “What’s exciting about these phenomena is that, in theory, they are not affected by temperature, and the fact they exist in three dimensions possibly makes fabrication of new devices easier,” Analytis said.

The cadmium arsenide samples displayed a quantum property known as “chirality” that couples an electron’s fundamental property of spin to its momentum, essentially giving it left- or right-handed traits. The experiment provided a first step toward the goal of using chirality for transporting charge and energy through a material without loss.

In the experiment, researchers manufactured and studied how electric current travels in slices of a cadmium arsenic crystal just 150nm thick when subjected to a high magnetic field. The crystal samples were crafted at Berkeley Lab’s Molecular Foundry and their 3D structure was detailed using Xrays at Berkeley Lab’s Advanced Light Source. As a next step researchers are seeking other fabrication techniques to build a similar material with built-in magnetic properties, so no external magnetic field is required. “This isn’t the right material for an application, but it tells us we’re on the right track,” Analytis said.

If researchers are successful in their modifications, such a material could conceivably be used for constructing interconnects between multiple computer chips, eg for next-generation computers that rely on an electron’s spin to process data (known as “spintronics”), and for building thermoelectric devices that convert waste heat to electric current.

“We wanted to measure the surface states of electrons in the material. But this 3D material also conducts electricity in the bulk — it’s central region – as well as at the surface,” he said. As a result, when you measure the electric current, the signal is swamped by what is going on in the bulk so you never see the surface contribution.” So they shrunk the sample from millionths of a meter to the nanoscale to give them more surface area and ensure that the surface signal would be the dominant one in an experiment. “We decided to do this by shaping samples into smaller structures using a focused beam of charged particles,” he said. “But this ion beam is known to be a rough way to treat the material – it is typically intrinsically damaging to surfaces, and we thought it was never going to work.”

But Philip J.W. Moll found a way to minimize this damage and provide finely polished surfaces in the tiny slices using tools at the Molecular Foundry. “Cutting something and at the same time not damaging it are natural opposites. Our team had to push the ion beam fabrication to its limits of low energy and tight beam focus to make this possible.”

When researchers applied an electric current to the samples, they found that electrons race around in circles similar to how they orbit around an atom’s nucleus, but their path passes through both the surface and the bulk of the material. The applied magnetic field pushes the electrons around the surface. When they reach the same energy and momentum of the bulk electrons, they get pulled by the chirality of the bulk and pushed through to the other surface, repeating this oddly twisting path until they are scattered by material defects. The two surfaces of the material ‘talk’ to each other over large distances due to their chiral nature.

Researchers also learned that disorder in the patterning of the material’s crystal surface doesn’t seem to affect the behavior of electrons there, though disorder in the central material does have an impact on whether the electrons move across the material from one surface to the other. The motion of the electrons exhibits a dual handedness, with some electrons traveling around the material in one direction and others looping around in an opposite direction.

Researchers are now building on this work in designing new materials for ongoing studies, Analytis said. “We are using techniques normally restricted to the semiconductor industry to make prototype devices from quantum materials.” http://newscenter.lbl.gov/2016/09/23/3-d-nanoscale-raceway-electrons/