Related papers: Optical heterodyne microscopy of operating spin Hall nano-oscillator arrays

Optical heterodyne microscopy of operating spin Hall nano-oscillator arrays

URL: http://arxiv.org/abs/2406.01155v1
Date: Mon, 3 Jun 2024 09:50:58 GMT
Title: Optical heterodyne microscopy of operating spin Hall nano-oscillator arrays
Authors: A. Alemán, A. A. Awad, S. Muralidhar, R. Khymyn, A. Kumar, A. Houshang, D. Hanstorp, J. Åkerman,
Abstract summary: We use two types of optical heterodyne detection techniques to characterize nano-constriction spin Hall nano-oscillators (SHNOs) To validate the technique and demonstrate its robustness, we study SHNOs made from two different material stacks, NiFe/Pt and W/CoFeB/MgO. To demonstrate the key features of direct, non-invasive, submicron, spatial, and phase-resolved characterization of the SHNO magnetodynamics, we map out the auto-oscillation magnitude and phase of two phase-binarized SHNOs used in Ising Machines
Score: 2.7966353325311357
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Optical heterodyne detection is a powerful technique for characterizing a wide range of physical excitations. Here, we use two types of optical heterodyne detection techniques (fundamental and parametric pumping) to microscopically characterize the high-frequency auto-oscillations of single and multiple nano-constriction spin Hall nano-oscillators (SHNOs). To validate the technique and demonstrate its robustness, we study SHNOs made from two different material stacks, NiFe/Pt and W/CoFeB/MgO, and investigate the influence of both the RF injection power and the laser power on the measurements, comparing the optical results to conventional electrical measurements. To demonstrate the key features of direct, non-invasive, submicron, spatial, and phase-resolved characterization of the SHNO magnetodynamics, we map out the auto-oscillation magnitude and phase of two phase-binarized SHNOs used in Ising Machines. This proof-of-concept platform establishes a strong foundation for further extensions, contributing to the ongoing development of crucial characterization techniques for emerging computing technologies based on spintronics devices

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