Discovering a 'rule-breaking' quantum material

Boston College physicists’ research could aid in further studies of exotic quantum phases and electromagnetism

Dual topological phases have been discovered in an intrinsic monolayer crystal, a finding that reveals new and unique rule-bending properties in a quantum material, an international team of scientists led by Boston College physicists have reported in the online version of the journal Nature.

The discovery of a dual topological insulator introduces a new method for creating topological flat minibands through electron interactions, which offer a promising platform for exploring exotic quantum phases and electromagnetism, the team reported.

January 10, 2022 -- Qiong Ma, Assistant Professor of Physics, and recent recipient of a National Science Foundation (NSF) Career award. Photographed in Higgins 160 for the 1/20/22 issue of Chronicle.

Assistant Professor of Physics Qiong Ma

“We have experimentally produced high-quality, atomically-thin samples of TaIrTe4 and developed corresponding electronic devices,” Boston College Assistant Professor of Physics Qiong Ma, the lead author of the report. “What's particularly intriguing is our discovery of not just one, but two topological insulating states, beyond the predictions of theory.”

The findings introduce a novel effect that the team calls the dual topological insulator or the dual quantum spin Hall insulator, Ma said.

Exceptionally thin, two-dimensional layers of a crystalline material called TaIrTe4, created from tantalum, iridium, and tellurium, were the focus of the team of scientists from ýapp, MIT, Harvard University, UCLA, Texas A&M, the University of Tennessee, Singapore’s Nanyang Technological University,  the Chinese Academy of Sciences, and Japan’s National Institute for Materials Science.

Each layer is less than 1 nanometer thick—that's over 100,000 times thinner than a strand of human hair. These layers, or "flakes," were carefully peeled off from a larger crystal using a simple method involving clear adhesive tape, a Nobel Prize-honored technique used widely in materials science.

“Our investigation aimed to understand how these materials conduct electricity,” Ma said. “Given the minuscule size of these materials, we employed advanced nanofabrication techniques, including photolithography and electron beam lithography, to establish nano-sized electrical contacts.”

Ma said the project’s primary objective was to test the theoretical prediction that suggests the thinnest TaIrTe4 layer acts as a two-dimensional topological insulator—also known as a quantum spin Hall insulator—a novel material where its interior is insulating and electricity flows along its boundaries without any energy loss. This unique combination makes these materials a focus of researchers trying to develop future generations of energy-efficient electronic devices.

Through manipulation of specific parameters—referred to as gate voltages—the team found TaIrTe4's transition between the two distinct topological states, Ma said. In both instances, the material exhibits zero electrical conductivity within its interior, while its boundaries remain conductive. Through systematic experimental and theoretical investigation, they determined that these two topological states stem from disparate origins.

The findings, which exceeded the theoretical predictions, surprised the scientists.

“Typically, adding electrons to a material increases its conductivity due to the greater number of charge or electricity carriers,” Ma said. “Initially, our system behaved as expected and became more conductive with the addition of electrons. However, beyond a certain point, adding more electrons unexpectedly turned the interior insulating again, with electrical conduction only at the boundaries and without energy loss, which is exactly again a topological insulating phase just like at the starting point when the interior has no electrons. This transition to a second topological insulating phase is entirely unexpected.”

Ma said future work on the discovery includes collaborations with groups skilled in other specialized techniques, like nanoscale imaging probes, to further understand the unexpected behavior.

“We'll also focus on refining our material's quality to improve the already impressive dissipationless topological conduction,” Ma said. “Furthermore, we plan to build heterostructures based on this new material to unlock even more intriguing physical behaviors.”

At Boston College, Ma collaborated with Professors of Physics Kenneth Burch and Ziqiang Wang; staff at the University Clean Room; ýapp post-docs Jian Tang, Zumeng Huang, and Zhe Sun; graduate students Thomas Siyuan Ding, Michael Geiwitz, Mohamed Shehabeldin, Vsevolod Belosevich, and Yiping Wang; and Zihan Wang, a visiting undergraduate researcher.