Coupling artificial molecular spin states by photon-assisted tunnelling

被引:0
|
作者
L.R. Schreiber
F.R. Braakman
T. Meunier
V. Calado
J. Danon
J.M. Taylor
W. Wegscheider
L.M.K. Vandersypen
机构
[1] Kavli Institute of Nanoscience,
[2] TU Delft,undefined
[3] Institut Néel,undefined
[4] CNRS and Université Joseph Fourier,undefined
[5] Dahlem Center for Complex Quantum Systems,undefined
[6] Freie Universität Berlin,undefined
[7] Joint Quantum Institute of Standards and Technology,undefined
[8] University of Maryland,undefined
[9] Institute for Experimental and Applied Physics,undefined
[10] University of Regensburg,undefined
[11] Solid State Physics Laboratory,undefined
来源
Nature Communications | / 2卷
关键词
D O I
暂无
中图分类号
学科分类号
摘要
Artificial molecules containing just one or two electrons provide a powerful platform for studies of orbital and spin quantum dynamics in nanoscale devices. A well-known example of these dynamics is tunnelling of electrons between two coupled quantum dots triggered by microwave irradiation. So far, these tunnelling processes have been treated as electric-dipole-allowed spin-conserving events. Here we report that microwaves can also excite tunnelling transitions between states with different spin. We show that the dominant mechanism responsible for violation of spin conservation is the spin–orbit interaction. These transitions make it possible to perform detailed microwave spectroscopy of the molecular spin states of an artificial hydrogen molecule and open up the possibility of realizing full quantum control of a two-spin system through microwave excitation.
引用
收藏
相关论文
共 50 条
  • [1] Coupling artificial molecular spin states by photon-assisted tunnelling
    Schreiber, L. R.
    Braakman, F. R.
    Meunier, T.
    Calado, V.
    Danon, J.
    Taylor, J. M.
    Wegscheider, W.
    Vandersypen, L. M. K.
    NATURE COMMUNICATIONS, 2011, 2
  • [2] Photon-assisted tunnelling with nonclassical light
    Souquet, J. -R.
    Woolley, M. J.
    Gabelli, J.
    Simon, P.
    Clerk, A. A.
    NATURE COMMUNICATIONS, 2014, 5
  • [3] Photon-assisted tunnelling with nonclassical light
    J. -R. Souquet
    M. J. Woolley
    J. Gabelli
    P. Simon
    A. A. Clerk
    Nature Communications, 5
  • [4] Photon-assisted electron spin tunnelling in double-well potential
    Li Chun-Lei
    Xu Yan
    Zhang Yan-Xiang
    Ye Bao-Sheng
    ACTA PHYSICA SINICA, 2013, 62 (10)
  • [5] Photon-assisted tunnelling through a quantum dot
    Delft Univ of Technology, Delft, Netherlands
    Semicond Sci Technol, 11 S (1512-1515):
  • [6] Photon-assisted tunnelling through a quantum dot
    Oosterkamp, TH
    Kouwenhoven, LP
    Koolen, AEA
    vanderVaart, NC
    Harmans, CJPM
    SEMICONDUCTOR SCIENCE AND TECHNOLOGY, 1996, 11 (11) : 1512 - 1515
  • [7] Thermoelectric Effect in Photon-Assisted, Spin-Polarized Tunnelling through a Quantum Dot
    Bocian, K.
    Rudzinski, W.
    ACTA PHYSICA POLONICA A, 2015, 127 (02) : 484 - 486
  • [8] Photon-assisted tunnelling of zero modes in a Majorana wire
    van Zanten, David M. T.
    Sabonis, Deividas
    Suter, Judith
    Vayrynen, Jukka I.
    Karzig, Torsten
    Pikulin, Dmitry I.
    O'Farrell, Eoin C. T.
    Razmadze, Davydas
    Petersson, Karl D.
    Krogstrup, Peter
    Marcus, Charles M.
    NATURE PHYSICS, 2020, 16 (06) : 663 - +
  • [9] Photon-assisted tunnelling of zero modes in a Majorana wire
    David M. T. van Zanten
    Deividas Sabonis
    Judith Suter
    Jukka I. Väyrynen
    Torsten Karzig
    Dmitry I. Pikulin
    Eoin C. T. O’Farrell
    Davydas Razmadze
    Karl D. Petersson
    Peter Krogstrup
    Charles M. Marcus
    Nature Physics, 2020, 16 : 663 - 668
  • [10] Photon-assisted electronic and spin transport in a junction containing precessing molecular spin
    Filipovic, Milena
    Belzig, Wolfgang
    PHYSICAL REVIEW B, 2016, 93 (07)
12345