Abstract
Polarization of electromagnetic waves plays an extremely important role in interaction of radiation with matter. In particular, interaction of polarized waves with ordered matter strongly depends on orientation and symmetry of vibrations of chemical bonds in crystals. In quantum technologies, the polarization of photons is considered as a “degree of freedom”, which is one of the main parameters that ensure efficient quantum computing. However, even for visible light, polarization control is in most cases separated from light emission. In this paper, we report on a new type of polarization control, implemented directly in a spintronic terahertz emitter. The principle of control, realized by a weak magnetic field at room temperature, is based on a spin-reorientation transition (SRT) in an intermetallic heterostructure TbCo2/FeCo with uniaxial in-plane magnetic anisotropy. SRT is implemented under magnetic field of variable strength but of a fixed direction, orthogonal to the easy magnetization axis. Variation of the magnetic field strength in the angular (canted) phase of the SRT causes magnetization rotation without changing its magnitude. The charge current excited by the spin-to-charge conversion is orthogonal to the magnetization. As a result, THz polarization rotates synchronously with magnetization when magnetic field strength changes. Importantly, the radiation intensity does not change in this case. Control of polarization by SRT is applicable regardless of the spintronic mechanism of the THz emission, provided that the polarization direction is determined by the magnetic moment orientation. The results obtained open the prospect for the development of the SRT approach for THz emission control.
Highlights
Polarization of electromagnetic waves plays an extremely important role in interaction of radiation with matter
Charge but spin has been taken into consideration in spintronic THz emitters (STE), where ultrafast spin photocurrent can convert into a transverse charge current
We report on THz emission in the TbCo2/FeCo heterostructure
Summary
Polarization of electromagnetic waves plays an extremely important role in interaction of radiation with matter. THz polarization rotates synchronously with magnetization when magnetic field strength changes. Control of polarization by SRT is applicable regardless of the spintronic mechanism of the THz emission, provided that the polarization direction is determined by the magnetic moment orientation. Generation of terahertz (THz) radiation is of great technological importance for many current and future applications, such as non-destructive diagnostics, ultra-fast computing, wireless communications[1,2,3,4], as well as direct control of the materials order parameters[5]. The inverse spin-Hall effect (ISHE) transforms the out-of-plane spin current into the desired sub-picosecond in-plane charge current The latter gives rise to the emission of a THz electromagnetic pulse. By changing magnetic field direction, polarization plane of THz wave can be c ontrolled[16]
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