The split-operator technique for wave packet propagation in quantum
systems is expanded here to the case of propagatingwave functions
describing Schrodinger particles, namely, charge carriers in
semiconductor nanostructures within the effective mass approximation, in
the presence of Zeeman effect, as well as of Rashba and Dresselhaus
spin-orbit interactions. We also demonstrate that simple modifications
to the expanded technique allow us to calculate the time evolution of
wave packets describing Dirac particles, which are relevant for the
study of transport properties in graphene.
%0 Journal Article
%1 WOS:000353695400010
%A Chaves, A
%A Farias, G A
%A Peeters, F M
%A Ferreira, R
%C ROOM 3208, CENTRAL PLAZA, 18 HARBOUR RD, WANCHAI, HONG KONG 00000,
PEOPLES R CHINA
%D 2015
%I GLOBAL SCIENCE PRESS
%J COMMUNICATIONS IN COMPUTATIONAL PHYSICS
%K coupling; graphene; heterostructures} packet propagation; semiconductor spin-orbit {Wave
%N 3
%P 850-866
%R 10.4208/cicp.110914.281014a
%T The Split-Operator Technique for the Study of Spinorial Wavepacket
Dynamics
%V 17
%X The split-operator technique for wave packet propagation in quantum
systems is expanded here to the case of propagatingwave functions
describing Schrodinger particles, namely, charge carriers in
semiconductor nanostructures within the effective mass approximation, in
the presence of Zeeman effect, as well as of Rashba and Dresselhaus
spin-orbit interactions. We also demonstrate that simple modifications
to the expanded technique allow us to calculate the time evolution of
wave packets describing Dirac particles, which are relevant for the
study of transport properties in graphene.
@article{WOS:000353695400010,
abstract = {The split-operator technique for wave packet propagation in quantum
systems is expanded here to the case of propagatingwave functions
describing Schrodinger particles, namely, charge carriers in
semiconductor nanostructures within the effective mass approximation, in
the presence of Zeeman effect, as well as of Rashba and Dresselhaus
spin-orbit interactions. We also demonstrate that simple modifications
to the expanded technique allow us to calculate the time evolution of
wave packets describing Dirac particles, which are relevant for the
study of transport properties in graphene.},
added-at = {2022-05-23T20:00:14.000+0200},
address = {ROOM 3208, CENTRAL PLAZA, 18 HARBOUR RD, WANCHAI, HONG KONG 00000,
PEOPLES R CHINA},
author = {Chaves, A and Farias, G A and Peeters, F M and Ferreira, R},
biburl = {https://www.bibsonomy.org/bibtex/26f8b07222ebf58630ffe3b725cb0d1f3/ppgfis_ufc_br},
doi = {10.4208/cicp.110914.281014a},
interhash = {f76743ff5b049902d77a293e57a3c5db},
intrahash = {6f8b07222ebf58630ffe3b725cb0d1f3},
issn = {1815-2406},
journal = {COMMUNICATIONS IN COMPUTATIONAL PHYSICS},
keywords = {coupling; graphene; heterostructures} packet propagation; semiconductor spin-orbit {Wave},
number = 3,
pages = {850-866},
publisher = {GLOBAL SCIENCE PRESS},
pubstate = {published},
timestamp = {2022-05-23T20:00:14.000+0200},
title = {The Split-Operator Technique for the Study of Spinorial Wavepacket
Dynamics},
tppubtype = {article},
volume = 17,
year = 2015
}