Your search keyword '"Kaushalya Jhuria"' showing total 4 results

1. Effect of localization on photoluminescence and zero-field splitting of silicon color centers

Author

Vsevolod Ivanov, Jacopo Simoni, Yeonghun Lee, Wei Liu, Kaushalya Jhuria, Walid Redjem, Yertay Zhiyenbayev, Christos Papapanos, Wayesh Qarony, Boubacar Kanté, Arun Persaud, Thomas Schenkel, and Liang Z. Tan

Subjects

Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Quantum Physics, Engineering, Strongly Correlated Electrons (cond-mat.str-el), Fluids & Plasmas, Physical Sciences, Chemical Sciences, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

The study of defect centers in silicon has been recently reinvigorated by their potential applications in optical quantum information processing. A number of silicon defect centers emit single photons in the telecommunication $O$-band, making them promising building blocks for quantum networks between computing nodes. The two-carbon G-center, self-interstitial W-center, and spin-$1/2$ T-center are the most intensively studied silicon defect centers, yet despite this, there is no consensus on the precise configurations of defect atoms in these centers, and their electronic structures remain ambiguous. Here we employ \textit{ab initio} density functional theory to characterize these defect centers, providing insight into the relaxed structures, bandstructures, and photoluminescence spectra, which are compared to experimental results. Motivation is provided for how these properties are intimately related to the localization of electronic states in the defect centers. In particular, we present the calculation of the zero-field splitting for the excited triplet state of the G-center defect as the structure is transformed from the A-configuration to the B-configuration, showing a sudden increase in the magnitude of the $D_{zz}$ component of the zero-field splitting tensor. By performing projections onto the local orbital states of the defect, we analyze this transition in terms of the symmetry and bonding character of the G-center defect which sheds light on its potential application as a spin-photon interface., Comment: 11 pages, 6 figures

Published

2022

2. Spin–orbit torque switching of a ferromagnet with picosecond electrical pulses

Author

Xinping Shi, Elodie Martin, Richard Wilson, Aldo Ygnacio Arriola Córdova, Jon Gorchon, Sébastien Petit-Watelot, Juan-Carlos Rojas-Sánchez, Gregory Malinowski, Jeffrey Bokor, Kaushalya Jhuria, Aristide Lemaître, Michel Hehn, Stéphane Mangin, Akshay Pattabi, Julius Hohlfeld, Roberto Lo Conte, Institut Jean Lamour (IJL), Université de Lorraine (UL)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Department of Electrical Engineering and Computer Sciences (Berkeley EECS), University of California [Riverside] (UCR), University of California, Centre de Nanosciences et de Nanotechnologies [Marcoussis] (C2N), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Magnetization dynamics, Materials science, Kerr effect, Spintronics, business.industry, Spin-transfer torque, 02 engineering and technology, 021001 nanoscience & nanotechnology, 7. Clean energy, 01 natural sciences, Electronic, Optical and Magnetic Materials, Switching time, Condensed Matter::Materials Science, Magnetization, Picosecond, 0103 physical sciences, Optoelectronics, [PHYS.COND]Physics [physics]/Condensed Matter [cond-mat], Electrical and Electronic Engineering, 010306 general physics, 0210 nano-technology, business, Instrumentation, Ultrashort pulse

Abstract

The development of approaches that can efficiently control the magnetization of magnetic materials is central to the creation of fast and low-power spintronic devices. Spin transfer torque can be used to electrically manipulate magnetic order in devices, but is typically limited to nanosecond timescales. Alternatively, spin–orbit torque can be employed, and switching with current pulses down to ~200 ps has been demonstrated. However, the upper limit to magnetization switching speed remains unestablished. Here, we show that photoconductive switches can be used to apply 6-ps-wide electrical pulses and deterministically switch the out-of-plane magnetization of a common thin cobalt film via spin–orbit torque. We probe the ultrafast magnetization dynamics due to spin–orbit torques with sub-picosecond resolution using the time-resolved magneto-optical Kerr effect (MOKE). We also estimate that the magnetization switching consumes less than 50 pJ in micrometre-sized devices. The magnetization of a cobalt thin film can be reversed by spin–orbit torques using picosecond electrical pulses that are generated by photoconductive switches.

Published

2020

3. Scalable manufacturing of quantum light emitters in silicon under rapid thermal annealing

Author

Yertay Zhiyenbayev, Walid Redjem, Vsevolod Ivanov, Wayesh Qarony, Christos Papapanos, Jacopo Simoni, Wei Liu, Kaushalya Jhuria, Liang Z. Tan, Thomas Schenkel, and Boubacar Kanté

Subjects

Atomic and Molecular Physics, and Optics

Abstract

Quantum light sources play a fundamental role in quantum technologies ranging from quantum networking to quantum sensing and computation. The development of these technologies requires scalable platforms, and the recent discovery of quantum light sources in silicon represents an exciting and promising prospect for scalability. The usual process for creating color centers in silicon involves carbon implantation into silicon, followed by rapid thermal annealing. However, the dependence of critical optical properties, such as the inhomogeneous broadening, the density, and the signal-to-background ratio, on centers implantation steps is poorly understood. We investigate the role of rapid thermal annealing on the dynamic of the formation of single color centers in silicon. We find that the density and the inhomogeneous broadening greatly depend on the annealing time. We attribute the observations to nanoscale thermal processes occurring around single centers and leading to local strain fluctuations. Our experimental observation is supported by theoretical modeling based on first principles calculations. The results indicate that annealing is currently the main step limiting the scalable manufacturing of color centers in silicon.

Published

2023

4. Picosecond Spin Orbit Torque Switching

Author

Xinping Shi, Roberto Lo Conte, Jon Gorchon, Akshay Pattabi, Juan-Carlos Rojas-Sánchez, Michel Hehn, Gregory Malinowski, Aristide Lemaître, Kaushalya Jhuria, Sébastien Petit-Watelot, Elodie Martin, Jeffrey Bokor, Aldo Ygnacio Arriola Córdova, Stéphane Mangin, Julius Hohlfeld, and Richard Wilson

Subjects

010302 applied physics, Physics, Spintronics, Condensed Matter - Mesoscale and Nanoscale Physics, business.industry, FOS: Physical sciences, Applied Physics (physics.app-ph), Physics - Applied Physics, Dissipation, 7. Clean energy, 01 natural sciences, Magnetization, Ferromagnetism, Picosecond, 0103 physical sciences, Femtosecond, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Optoelectronics, 010306 general physics, business, Ultrashort pulse, Spin-½

Abstract

Reducing energy dissipation while increasing speed in computation and memory is a long-standing challenge for spintronics research. In the last 20 years, femtosecond lasers have emerged as a tool to control the magnetization in specific magnetic materials at the picosecond timescale. However, the use of ultrafast optics in integrated circuits and memories would require a major paradigm shift. An ultrafast electrical control of the magnetization is far preferable for integrated systems. Here we demonstrate reliable and deterministic control of the out-of-plane magnetization of a 1 nm-thick Co layer with single 6 ps-wide electrical pulses that induce spin-orbit torques on the magnetization. We can monitor the ultrafast magnetization dynamics due to the spin-orbit torques on sub-picosecond timescales, thus far accessible only by numerical simulations. Due to the short duration of our pulses, we enter a counter-intuitive regime of switching where heat dissipation assists the reversal. Moreover, we estimate a low energy cost to switch the magnetization, projecting to below 1fJ for a (20 nm)^3 cell. These experiments prove that spintronic phenomena can be exploited on picosecond time-scales for full magnetic control and should launch a new regime of ultrafast spin torque studies and applications., Includes article + supplementary information. Latest version uses full name of the first author. Nature Electronics (2020)

Published

2019