Spatial Control of Charge Doping in van der Waals Heterostructures
ORAL
Abstract
Advancements in designing innovative electronic devices and exploring novel physics are often limited by the spatial control of charge doping in 2D materials. A variety of conventional techniques, such as electrostatic gating, are used to achieve charge doping control but suffer from complicated fabrication processes that introduce impurities and lack flexibility. To overcome these challenges, we have introduced new methods of patterning doping profiles in van der Waals heterostructures by controllably exciting defect states in our device with light illumination and local field excitation. In this study we create rewritable nanoscale doping patterns with improved spatial control. These spatially dependent doping patterns are then characterized through local probe and transport methods. This local patterning technique will enable novel device designs and allow for the exploration of patterned superlattice structures in 2D materials.
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Presenters
Salman Kahn
Univ of California - Berkeley
UCB
Physics, University of California, Berkeley
Authors
Salman Kahn
Univ of California - Berkeley
UCB
Physics, University of California, Berkeley
Wu Shi
Lawrence Berkeley National Laboratory
Physics, University of California, Berkeley
Univ of California - Berkeley
Sheng-Yu Wang
UC Berkeley
Physics, University of California, Berkeley
Hsin-Zon Tsai
Physics, Univ of California - Berkeley
Univ of California - Berkeley
UCB
Physics, UC Berkeley
Physics, University of California, Berkeley
Department of physics, University of California - Berkeley
Dillon Wong
Princeton University
Joseph Henry Laboratories & Department of Physics, Princeton University
UCB
Physics, Princeton University
Univ of California - Berkeley
Takashi Taniguchi
National Institute for Materials Science
NIMS
National Institute for Material Science
Advanced Materials Laboratory, National Institute for Materials Science
National Institute of Materials Science
Research Center for Functional Materials, National Institute for Materials Science
National Institute for Materials Science (NIMS
Advanced Materials Laboratory, NIMS
National Institute for Materials Science, Advanced Materials Laboratory
National Institue for Materials Science
National Institute of Material Science
National Institute for Matericals Science
Advanced Materials Laboratory
National Institute for Materials Science, 1-1 Namiki
NIMS-Japan
Kenji Watanabe
National Institute for Materials Science
NIMS
National Institute for Material Science
Advanced Materials Laboratory, National Institute for Materials Science
National Institute of Materials Science
Research Center for Functional Materials, National Institute for Materials Science
National Institute for Materials Science (NIMS
Advanced Materials Laboratory, NIMS
National Institute for Materials Science, Advanced Materials Laboratory
National Institue for Materials Science
National Institute of Material Science
National Institute for Matericals Science
Advanced Materials Laboratory
National Institute for Materials Science, 1-1 Namiki
Advanced materials laboratory, National institute for Materials Science
NIMS-Japan
Alex Zettl
UC Berkeley and LBNL
UC berkeley
Univ of California - Berkeley
Physics, UC Berkeley
Physics, University of California, Berkeley
University of California at Berkeley
Physics, University of California - Berkeley
Department of Physics, Univ of California - Berkeley
Michael Crommie
Physics, Univ of California - Berkeley
UC Berkeley and LBNL
Univ of California - Berkeley
UCB
Physics, UC Berkeley
Physics, University of California, Berkeley
Department of physics, University of California - Berkeley
