Two-electron dephasing in single Si and GaAs quantum dots
pith:XRCDKS5K Add to your LaTeX paper
What is a Pith Number?\usepackage{pith}
\pithnumber{XRCDKS5K}
Prints a linked pith:XRCDKS5K badge after your title and writes the identifier into PDF metadata. Compiles on arXiv with no extra files. Learn more
read the original abstract
We study the dephasing of two-electron states in a single quantum dot in both GaAs and Si. We investigate dephasing induced by electron-phonon coupling and by charge noise analytically for pure orbital excitations in GaAs and Si, as well as for pure valley excitations in Si. In GaAs, polar optical phonons give rise to the most important contribution, leading to a typical dephasing rate of ~5.9 GHz. For Si, intervalley optical phonons lead to a typical dephasing rate of ~140 kHz for orbital excitations and ~1.1 MHz for valley excitations. For harmonic, disorder-free quantum dots, charge noise is highly suppressed for both orbital and valley excitations, since neither has an appreciable dipole moment to couple to electric field variations from charge fluctuators. However, both anharmonicity and disorder break the symmetry of the system, which can lead to increased dipole moments and therefore faster dephasing rates.
This paper has not been read by Pith yet.
Forward citations
Cited by 1 Pith paper
-
Twisted light generates robust many-body states for practical quantum computing
Twisted light enables optical write, read, and scalable addressing of symmetry-protected correlation sectors in quantum dots via OAM selection rules, with closed-form gate parameters in the Calogero interaction limit.
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.