Current‐induced control of the electron–nuclear spin system in semiconductors on a micrometer scale

Abstract: The ability of using onchip microcoils to control the electron–nuclear spin system in semiconductors is demonstrated. Electrically generated magnetic fields of several tens of mT can be obtained on a micrometer length scale, which are switchable on a sub‐ns time scale due to the low complex coil impedance. This allows one to electrically (i) manipulate the nuclear spins by means of nuclear magnetic resonance in n‐GaAs and (ii) control the hyperfine flip‐flop rate in CdSe/ZnSe quantum dots.

“…Semiconductor-based quantum systems are considered as possible quantum-computing devices [8] , in which quantum states, such as electron spin, photon polarity, and magnetic polarization, are manipulated. Ferromagnetic Mn-doped III-V semiconductors can supply polarized electrons and control electron spin states [9,10] , and small coils can be used to control the electron-nuclear-spin system [11] . Influence of hyperfine interactions (HFI) between the lattice nuclei and electrons are to be considered for controlling electron-nuclear-spin systems.…”

Dynamic nuclear self-polarization of III–V semiconductors

“…Semiconductor-based quantum systems are considered as possible quantum-computing devices [8] , in which quantum states, such as electron spin, photon polarity, and magnetic polarization, are manipulated. Ferromagnetic Mn-doped III-V semiconductors can supply polarized electrons and control electron spin states [9,10] , and small coils can be used to control the electron-nuclear-spin system [11] . Influence of hyperfine interactions (HFI) between the lattice nuclei and electrons are to be considered for controlling electron-nuclear-spin systems.…”

Dynamic nuclear self-polarization of III–V semiconductors