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Go to Combined momentum- and real-space photoelectric probes of dimensionality-tuned Weyl semimetals
Combined momentum- and real-space photoelectric probes of dimensionality-tuned Weyl semimetals

Combined momentum- and real-space photoelectric probes of dimensionality-tuned Weyl semimetals

Summary   The library of two-dimensional (2D) materials has recently grown to include topological insulators and semimetals. Their incorporation in special device geometries may lead to novel quantum electronics with enhanced functionalities. Weyl semimetals, in particular, offer the most robust form of topological protection. Recent results from our group indicate that Weyl nodes should be […]

March 12, 2019

PI: Adam Wei Tsen

2d 3d 13 More +

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Go to Zero-Dimensional Quantum Materials for the Next Generation of Highly-Selective Chemical Sensors
Zero-Dimensional Quantum Materials for the Next Generation of Highly-Selective Chemical Sensors

Zero-Dimensional Quantum Materials for the Next Generation of Highly-Selective Chemical Sensors

Summary   Heavy metals are a major public health concern and their on-site detection in water supplies is not well served by existing lab techniques. We develop a new multi-modal platform comprising functionalized quantum dots of two-dimensional materials (2D-QDs) for the sensing of four highly-toxic heavy metal pollutants (arsenic, cadmium, lead and mercury). The zero-dimensional […]

March 11, 2019

PI: Kevin Musselman

0d 2d 9 More +

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Go to Scanning Tunneling Microscopy of Quantum Materials, Devices and Molecules
Scanning Tunneling Microscopy of Quantum Materials, Devices and Molecules

Scanning Tunneling Microscopy of Quantum Materials, Devices and Molecules

Summary   This project advances our ability to characterize and study novel quantum materials, quantum devices, and even individual molecules at the atomic level. By combining Non-Contact Atomic Force Microscopy (NC-AFM), Scanning Tunneling Microscopy (STM) and scanning gate methods, we correlate spatial information with transport properties and can locally manipulate charge, spin and structural states. […]

January 28, 2019

PI: Jonathan Baugh

0d 1d 13 More +

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Go to Harnessing the Promise of Quantum Materials for Future Electronic Devices
Harnessing the Promise of Quantum Materials for Future Electronic Devices

Harnessing the Promise of Quantum Materials for Future Electronic Devices

Summary   Two-dimensional (2D) quantum materials, such as graphene and molybdenum disulfide, have great potential for use in future flexible and wearable electronics applications. With traditional silicon-based electronics nearing their theoretical performance limits, nano-electronics made from 2D quantum materials offer breakthrough opportunities for energy-efficient, wearable ubiquitous computation. In this project, we will study integration of […]

June 14, 2018

PI: Young Ki Yoon

2d electrical & computer engineering 2 More +

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Go to Two-Dimensional Quantum Materials and Heterostructures
Two-Dimensional Quantum Materials and Heterostructures
TQT Computation

Two-Dimensional Quantum Materials and Heterostructures

Two-dimensional (2D) layers just one atom thick can be stripped from certain materials, such as graphene.

June 1, 2017

PI: Adam Wei Tsen

2d chemistry 5 More +

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