Symmetry-controlled singlet-triplet transition in a double-barrier quantum ring

Heidi Potts; Josef Josefi; I-Ju Chen; Sebastian Lehmann; Kimberly A. Dick; Martin Leijnse; Stephanie M. Reimann; Jakob Bengtsson; Claes Thelander

doi:10.1103/PhysRevB.104.L081409

Symmetry-controlled singlet-triplet transition in a double-barrier quantum ring

Heidi Potts^*, Josef Josefi, I-Ju Chen, Sebastian Lehmann, Kimberly A. Dick, Martin Leijnse, Stephanie M. Reimann, Jakob Bengtsson, Claes Thelander

^*Corresponding author af dette arbejde

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

6 Citationer (Scopus)

1 Downloads (Pure)

Abstract

We engineer a system of two strongly confined quantum dots to gain reproducible electrostatic control of the even-electron spin at zero magnetic field. Coupling the dots in a tight ring-shaped potential with two tunnel barriers, we demonstrate that an electric field can switch the electron ground state between a singlet and a triplet configuration. Comparing our experimental cotunneling spectroscopy data to a full many-body treatment of interacting electrons in a double-barrier quantum ring, we find excellent agreement in the evolution of many-body states with electric and magnetic fields. The calculations show that the singlet-triplet energy crossover, not found in conventionally coupled quantum dots, is made possible by the ring-shaped geometry of the confining potential.

Originalsprog	Engelsk
Artikelnummer	081409
Tidsskrift	Physical Review B
Vol/bind	104
Udgave nummer	8
Antal sider	5
ISSN	2469-9950
DOI	https://doi.org/10.1103/PhysRevB.104.L081409
Status	Udgivet - 25 aug. 2021
Udgivet eksternt	Ja

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10.1103/PhysRevB.104.L081409Licens: CC BY

PhysRevB.104.L081409Forlagets udgivne version, 1,29 MB

Citationsformater

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title = "Symmetry-controlled singlet-triplet transition in a double-barrier quantum ring",

abstract = "We engineer a system of two strongly confined quantum dots to gain reproducible electrostatic control of the even-electron spin at zero magnetic field. Coupling the dots in a tight ring-shaped potential with two tunnel barriers, we demonstrate that an electric field can switch the electron ground state between a singlet and a triplet configuration. Comparing our experimental cotunneling spectroscopy data to a full many-body treatment of interacting electrons in a double-barrier quantum ring, we find excellent agreement in the evolution of many-body states with electric and magnetic fields. The calculations show that the singlet-triplet energy crossover, not found in conventionally coupled quantum dots, is made possible by the ring-shaped geometry of the confining potential.",

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author = "Heidi Potts and Josef Josefi and I-Ju Chen and Sebastian Lehmann and Dick, {Kimberly A.} and Martin Leijnse and Reimann, {Stephanie M.} and Jakob Bengtsson and Claes Thelander",

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T1 - Symmetry-controlled singlet-triplet transition in a double-barrier quantum ring

AU - Potts, Heidi

AU - Josefi, Josef

AU - Chen, I-Ju

AU - Lehmann, Sebastian

AU - Dick, Kimberly A.

AU - Leijnse, Martin

AU - Reimann, Stephanie M.

AU - Bengtsson, Jakob

AU - Thelander, Claes

PY - 2021/8/25

Y1 - 2021/8/25

N2 - We engineer a system of two strongly confined quantum dots to gain reproducible electrostatic control of the even-electron spin at zero magnetic field. Coupling the dots in a tight ring-shaped potential with two tunnel barriers, we demonstrate that an electric field can switch the electron ground state between a singlet and a triplet configuration. Comparing our experimental cotunneling spectroscopy data to a full many-body treatment of interacting electrons in a double-barrier quantum ring, we find excellent agreement in the evolution of many-body states with electric and magnetic fields. The calculations show that the singlet-triplet energy crossover, not found in conventionally coupled quantum dots, is made possible by the ring-shaped geometry of the confining potential.

AB - We engineer a system of two strongly confined quantum dots to gain reproducible electrostatic control of the even-electron spin at zero magnetic field. Coupling the dots in a tight ring-shaped potential with two tunnel barriers, we demonstrate that an electric field can switch the electron ground state between a singlet and a triplet configuration. Comparing our experimental cotunneling spectroscopy data to a full many-body treatment of interacting electrons in a double-barrier quantum ring, we find excellent agreement in the evolution of many-body states with electric and magnetic fields. The calculations show that the singlet-triplet energy crossover, not found in conventionally coupled quantum dots, is made possible by the ring-shaped geometry of the confining potential.

KW - SPINS

KW - DOTS

U2 - 10.1103/PhysRevB.104.L081409

DO - 10.1103/PhysRevB.104.L081409

M3 - Journal article

SN - 2469-9950

VL - 104

JO - Physical Review B

JF - Physical Review B

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