The experimental realization of ultrathin graphene – which earned two scientists from the University of Manchester, U.K., the Nobel Prize in physics in 2010 – has ushered in a new age in materials research.
What started with graphene has evolved to include numerous related single-atom-thick materials, which have unusual properties due to their ultra-thinness. Among them are transition metal dichalcogenides (TMDs), materials that offer several key features not available in graphene and are emerging as next-generation semiconductors.
“Our proposal is very realistic – that’s why it’s exciting,” Kim said of her group’s research. “We have a theoretical strategy to materialize a topological superconductor … and that will be a step toward building a quantum computer. The history of superconductivity over the last 100 years has been led by accidental discoveries. We have a proposal that’s sitting on firm principles.
“Instead of hoping for a new material that has the properties you want,” she said, “let’s go after it with insight and design principle.”
Yi-Ting Hsu, a doctoral student in the Kim Group, is lead author of “Topological superconductivity in monolayer transition metal dichalcogenides,” published April 11 in Nature Communications. Other team members include Kim Group alumni Mark Fischer, now at ETH Zurich in Switzerland, and Abolhassan Vaezi, now at Stanford University.
The group’s proposal: The TMDs’ unusual properties favor two topological superconducting states, which, if experimentally confirmed, will open up possibilities for manipulating topological superconductors at temperatures near absolute zero.
Kim identified hole-doped (positive charge-enhanced) single-layer TMDs as a promising candidate for topological superconductivity, based on the known special locking between spin state and kinetic energy of electrons (spin-valley locking) of single-layer TMDs, as well as the recent observations of superconductivity in electron-doped (negative charge-enhanced) single-layer TMDs.
The group’s goal is a superconductor that operates at around 1 Kelvin (approximately minus 457 degrees Fahrenheit), that could be cooled with liquid helium sufficiently to maintain quantum computing potential in a superconducting state.
Theoretically, housing a quantum computer powerful enough to justify the power needed to keep the superconductor at 1 Kelvin is not out of the question, Kim said. In fact, IBM already has a 7-qubit (quantum bit) computer, which operates at less than 1 Kelvin, available to the public through its IBM Quantum Experience.
A quantum computer with approximately six times more qubits would fundamentally change computing, Kim said.
“If you get to 40 qubits, that computing power will exceed any classical computers out there,” she said. “And to house a 40-qubit [quantum computer] in cryogenic temperature is not that big a deal. It will be a revolution.”
Kim and her group are working with Debdeep Jena and Grace Xing of electrical and computer engineering, and Katja Nowack of physics, through an interdisciplinary research group seed grant from the Cornell Center for Materials Research. Each group brings researchers from different departments together, with support from both the university and the National Science Foundation’s Materials Research Science and Engineering Centers program.
“We’re combining the engineering expertise of DJ and Grace, and expertise Katja has in mesoscopic systems and superconductors,” Kim said. “It requires different expertise to come together to pursue this, and CCMR allows that.”
This work was also supported in part by the NSF’s PARADIM (Platform for the Accelerated Realization, Analysis, and Discovery of Interface Materials) program.