37 research outputs found
Circular photogalvanic effect induced by near-infrared radiation in InAs quantum wires patterned quasi two-dimensional electron system
In this work we investigated the InAs/InAlAs quantum wires (QWRs)
superlattice by optically exciting the structure with near-infrared radiation.
By varying the helicity of the radiation at room temperature we observed the
circular photogalvanic effect related to the symmetry of the
structure, which could be attributed to the formation of a quasi
two-dimensional system underlying in the vicinity of the QWRs pattern. The
ratio of Rashba and Dresselhaus terms shows an evolution of the spin-orbit
interaction in quasi two-dimensional structure with the QWR layer deposition
thickness.Comment: 9 pages, 3 figure
Direct photoluminescence probing of ferromagnetism in monolayer two-dimensional CrBr3
Atomically thin magnets are the key element to build up spintronics based on
two-dimensional materials. The surface nature of two-dimensional ferromagnet
opens up opportunities to improve the device performance efficiently. Here, we
report the intrinsic ferromagnetism in atomically thin monolayer CrBr3,
directly probed by polarization resolved magneto-photoluminescence. The
spontaneous magnetization persists in monolayer CrBr3 with a Curie temperature
of 34 K. The development of magnons by the thermal excitation is in line with
the spin-wave theory. We attribute the layer-number dependent hysteresis loops
in thick layers to the magnetic domain structures. As a stable monolayer
material in air, CrBr3 provides a convenient platform for fundamental physics
and pushes the potential applications of the two-dimensional ferromagnetism.Comment: 27 pages, 10 figure
Optical spin pumping induced pseudo-magnetic field in two dimensional heterostructures
Two dimensional heterostructures are likely to provide new avenues for the
manipulation of magnetization that is crucial for spintronics or
magnetoelectronics. Here, we demonstrate that optical spin pumping can generate
a large effective magnetic field in two dimensional MoSe2/WSe2
heterostructures. We determine the strength of the generated field by
polarization-resolved measurement of the interlayer exciton photoluminescence
spectrum: the measured splitting exceeding 10 milli-electron volts (meV)
between the emission originating from the two valleys corresponds to an
effective magnetic field of ~ 30 T. The strength of this optically induced
field can be controlled by the excitation light polarization. Our finding opens
up new possibilities for optically controlled spintronic devices based on van
der Waals heterostructures
Observation of strong anisotropic forbidden transitions in (001) InGaAs/GaAs single-quantum well by reflectance-difference spectroscopy and its behavior under uniaxial strain
The strong anisotropic forbidden transition has been observed in a series of InGaAs/GaAs single-quantum well with well width ranging between 3 nm and 7 nm at 80 K. Numerical calculations within the envelope function framework have been performed to analyze the origin of the optical anisotropic forbidden transition. It is found that the optical anisotropy of this transition can be mainly attributed to indium segregation effect. The effect of uniaxial strain on in-plane optical anisotropy (IPOA) is also investigated. The IPOA of the forbidden transition changes little with strain, while that of the allowed transition shows a linear dependence on strain
Helicity-dependent photocurrents in graphene layers excited by mid-infrared radiation of a CO-laser
We report the study of the helicity driven photocurrents in graphene excited
by mid-infrared light of a CO-laser. Illuminating an unbiased monolayer
sheet of graphene with circularly polarized radiation generates -- under
oblique incidence -- an electric current perpendicular to the plane of
incidence, whose sign is reversed by switching the radiation helicity. We show
that the current is caused by the interplay of the circular Hall effect
and the circular photogalvanic effect. Studying the frequency dependence of the
current in graphene layers grown on the SiC substrate we observe that the
current exhibits a resonance at frequencies matching the longitudinal optical
phonon in SiC