Motivated by a large number of recent magnetotransport studies we have
revisited the problem of the microscopic calculation of the quasiparticle
effective mass in a paramagnetic two-dimensional (2D) electron liquid (EL). Our
systematic study is based on a generalized $GW$ approximation which makes use
of the many-body local fields and takes advantage of the results of the most
recent QMC calculations of the static charge- and spin-response of the 2D EL.
We report extensive calculations for the many-body effective mass enhancement
over a broad range of electron densities. In this respect we critically examine
the relative merits of the on-shell approximation, commonly used in
weak-coupling situations, {\it versus} the actual self-consistent solution of
the Dyson equation. We show that already for $r_s \simeq 3$ and higher, a
solution of the Dyson equation proves here necessary in order to obtain a well
behaved effective mass. Finally we also show that our theoretical results for a
quasi-2D EL, free of any adjustable fitting parameters, are in good qualitative
agreement with some recent measurements in a GaAs/AlGaAs heterostructure.Comment: 12 pages, 3 figures, CMT28 Conference Proceedings, work related to
  cond-mat/041226

Asgari, R.

Davoudi, B.

Giuliani, G. F.

Polini, M.

Tosi, M. P.

Vignale, G.

Physical Review B

English

arXiv

http://arxiv.org/PS_cache/cond-mat/pdf/0412/0412665v1.pdfMotivated by a large number of recent magnetotransport studies we have revisited the problem of the microscopic calculation of the quasiparticle effective mass in a paramagnetic two-dimensional (2D) electron liquid (EL). Our systematic study is based on a generalized $GW$ approximation which makes use of the many-body local fields and takes advantage of the results of the most recent QMC calculations of the static charge- and spin-response of the 2D EL. We report extensive calculations for the many-body effective mass enhancement over a broad range of electron densities. In this respect we critically examine the relative merits of the on-shell approximation, commonly used in weak-coupling situations, {\it versus} the actual self-consistent solution of the Dyson equation. We show that already for $r_s \simeq 3$ and higher, a solution of the Dyson equation proves here necessary in order to obtain a well behaved effective mass. Finally we also show that our theoretical results for a quasi-2D EL, free of any adjustable fitting parameters, are in good qualitative agreement with some recent measurements in a GaAs/AlGaAs heterostructure.One of us (M.P.) gratefully acknowledges the hospitality of Giovanni Vignale at the Department of Physics and Astronomy of the University of Missouri-Columbia and partial support fromWashington University and from the Division of Undergraduate Education of the U.S. National Science Foundation through grant DUE-0127488 to the Shodor Education Foundation, Inc. This work was partially supported by MIUR through the PRIN2001 and PRIN2003 programs. G.V. acknowledges support
from NSF Grant No. DMR 0313681

Polini, Marco

Giuliani, Gabriele, 1953-

Vignale, Giovanni, 1957-

University of Missouri: MOspace

Many-body effective mass enhancement in a two-dimensional electron liquid

URL:http://link.aps.org/doi/10.1103/PhysRevB.71.045323
DOI:10.1103/PhysRevB.71.045323Motivated by a number of recent experimental studies we have revisited the problem of the microscopic calculation of the quasiparticle self-energy and many-body effective mass enhancement in an unpolarized two- dimensional electron liquid. Our systematic study is based on the many-body local field theory and takes advantage of the results of the most recent diffusion Monte Carlo calculations of the static charge and spin
response of the electron liquid. We report extensive calculations of both the real and imaginary parts of the quasiparticle self- energy. We also present results for the many-body effective mass enhancement and the
renormalization constant over a broad range of electron densities. In this respect we critically examine the relative merits of the on-shell approximation, commonly used in weak coupling situations versus the actual
self-consistent solution of the Dyson equation. We show that already for rs.3 and higher, a solution of the Dyson equation proves necessary in order to obtain a well-behaved effective mass. Finally we find confirmation that the inclusion of both charge- and spin-density fluctuations beyond the random phase approximation is
indeed crucial to get reasonable agreement with recent measurements.This work was partially supported by MIUR through the PRIN2001 and PRIN2003 programs. G.V. acknowledges support from NSF Grant No. DMR 0313681

Quasiparticle self-energy and many-body effective mass enhancement in a two-dimensional electron liquid

Motivated by a number of recent experimental studies we have revisited the problem of the microscopic calculation of the quasiparticle self-energy and many-body effective mass enhancement in an unpolarized two-dimensional electron liquid. Our systematic study is based on the many-body local field theory and takes advantage of the results of the most recent diffusion Monte Carlo calculations of the static charge and spin response of the electron liquid. We report extensive calculations of both the real and imaginary parts of the quasiparticle self-energy. We also present results for the many-body effective mass enhancement and the renormalization constant over a broad range of electron densities. In this respect we critically examine the relative merits of the on-shell approximation, commonly used in weak coupling situations versus the actual self-consistent solution of the Dyson equation. We show that already for r(s)similar or equal to3 and higher, a solution of the Dyson equation proves necessary in order to obtain a well-behaved effective mass. Finally we find confirmation that the inclusion of both charge- and spin-density fluctuations beyond the random phase approximation is indeed crucial to get reasonable agreement with recent measurements

Purdue E-Pubs

Many-body effective mass enhancement in a two-dimensional electron
  liquid

Many-body effective mass enhancement in a two-dimensional electron liquid

Abstract

Similar works

Full text

Available Versions

University of Missouri: MOspace

University of Missouri: MOspace

Purdue E-Pubs