Theory of coherent dynamic nuclear polarization in quantum dots
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Theory of coherent dynamic nuclear polarization in quantum dots. / Neder, Izhar; Rudner, Mark Spencer; Halperin, Bertrand.
I: Physical Review B Condensed Matter, Bind 89, Nr. 8, 085403, 04.02.2014.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Theory of coherent dynamic nuclear polarization in quantum dots
AU - Neder, Izhar
AU - Rudner, Mark Spencer
AU - Halperin, Bertrand
PY - 2014/2/4
Y1 - 2014/2/4
N2 - We consider the production of dynamic nuclear spin polarization (DNP) in a two-electron double quantum dot, in which the electronic levels are repeatedly swept through a singlet-triplet avoided crossing. Our analysis helps to elucidate the intriguing interplay between electron-nuclear hyperfine coupling, electronic spin-orbit coupling, and electron and nuclear Larmor precession in an externally- applied magnetic field, in guiding the production of DNP. In particular, we specifically address the roles of multiple nuclear spin species. By treating the nuclear spin dynamics semi-classically, we identify two contributions to the DNP production rate, a “geometric contribution” and a “dynamic contribution,” which depend in very different ways on control parameters such as the sweep rate and holding time near the level crossing. We find that the dynamical contribution dominates the DNP when the system is held near the singlet-triplet avoided crossing for a time on the order of the nuclear Larmor period. Detailed numerical calculations provide a physical picture for understanding the oscillations observed by Foletti et. al. in arXiv:0801.3613.
AB - We consider the production of dynamic nuclear spin polarization (DNP) in a two-electron double quantum dot, in which the electronic levels are repeatedly swept through a singlet-triplet avoided crossing. Our analysis helps to elucidate the intriguing interplay between electron-nuclear hyperfine coupling, electronic spin-orbit coupling, and electron and nuclear Larmor precession in an externally- applied magnetic field, in guiding the production of DNP. In particular, we specifically address the roles of multiple nuclear spin species. By treating the nuclear spin dynamics semi-classically, we identify two contributions to the DNP production rate, a “geometric contribution” and a “dynamic contribution,” which depend in very different ways on control parameters such as the sweep rate and holding time near the level crossing. We find that the dynamical contribution dominates the DNP when the system is held near the singlet-triplet avoided crossing for a time on the order of the nuclear Larmor period. Detailed numerical calculations provide a physical picture for understanding the oscillations observed by Foletti et. al. in arXiv:0801.3613.
U2 - 10.1103/PhysRevB.89.085403
DO - 10.1103/PhysRevB.89.085403
M3 - Journal article
VL - 89
JO - Physical Review B
JF - Physical Review B
SN - 2469-9950
IS - 8
M1 - 085403
ER -
ID: 90872994