Applied Physics:
Coherent Holes in a Semiconductor Quantum Dot
Michael H. Kolodrubetz and
Jason R. Petta
Building a quantum computer requires finding a system with long-lived coherence—one in which the wave function of a quantum state maintains its phase over time. In solid-state implementations of quantum information processing, coherent states can be generated with electron spins, and semiconductor quantum dots are powerful platforms for preparing, controlling, and measuring electron spin coherence (1). However, interactions between the electron spin and its environment destroy the fragile coherence (2) and lead to a loss of information. On page 70 of this issue, Brunner et al. (3) address this problem by using "holes"—positive charge carriers that result from unfilled states in an electronic band. They demonstrate that one measure of coherence, the inhomogeneous dephasing time of the hole spin, is at least an order of magnitude longer than that for electron spins.
Department of Physics, Princeton University, Princeton, NJ 08544, USA.
E-mail: mkolodru{at}princeton.edu; petta{at}princeton.edu
