Observing Atomic Collapse in Graphene

Yang Wang; Dillon Wong; Andrey Shytov; Victor Brar; Sangkook Choi; Qiong Wu; Hsin-zon Tsai; William Regan; Alex Zettl; Roland Kawakami; Steven Louie; Leonid Levitov; Michael Crommie

Observing Atomic Collapse in Graphene

ORAL

Abstract

Relativistic quantum mechanics predicts that super-heavy atoms possess unique properties not shared by ordinary atoms. In particular, a very strong electric field around the nucleus should result in ``atomic collapse,'' with an electron component falling onto the nucleus and a positron component escaping to infinity. Predicted by Dirac 80 years ago, atomic collapse has thus far remained experimentally out of reach using accelerator-based techniques. Here we report the observation of atomic collapse on gated graphene devices. The energy and spatial dependence of the atomic collapse state was measured using scanning tunneling microscopy (STM).

March 21, 2013, 1:03 PM – March 21, 2013, 1:15 PM

Authors

Yang Wang
- Physics Dept. UC Berkeley, LBNL
Dillon Wong
- Physics Dept. UC Berkeley, LBNL
Andrey Shytov
- Shool of Physics, Univ. of Exeter
Victor Brar
- Physics Dept. UC Berkeley, LBNL
Sangkook Choi
- Physics Dept. UC Berkeley
Qiong Wu
- Physics Dept. UC Berkeley, LBNL
Hsin-zon Tsai
- Physics Dept. UC Berkeley
William Regan
- Physics Dept. UC Berkeley, LBNL
Alex Zettl
- Physics Dept. UC Berkeley, LBNL
Roland Kawakami
- Dept. of physics and astronomy, UC Riverside
Steven Louie
- Physics Dept. UC Berkeley, LBNL
Leonid Levitov
- Dept. of Physics, MIT
Michael Crommie
- Physics Dept. UC Berkeley, LBNL