Your search keyword '"Parsonnet, Eric"' showing total 3 results

1. Nonvolatile Electric Field Control of Thermal Magnons in the Absence of an Applied Magnetic Field

Author

Parsonnet, Eric, Caretta, Lucas, Nagarajan, Vikram, Zhang, Hongrui, Taghinejad, Hossein, Behera, Piush, Huang, Xiaoxi, Kavle, Pravin, Fernandez, Abel, Nikonov, Dmitri, Li, Hai, Young, Ian, Analytis, James, and Ramesh, Ramamoorthy

Subjects

Condensed Matter - Materials Science

Abstract

Spin transport through magnetic insulators has been demonstrated in a variety of materials and is an emerging pathway for next-generation spin-based computing. To modulate spin transport in these systems, one typically applies a sufficiently strong magnetic field to allow for deterministic control of magnetic order. Here, we make use of the well-known multiferroic magnetoelectric, BiFeO3, to demonstrate non-volatile, hysteretic, electric-field control of thermally excited magnon current in the absence of an applied magnetic field. These findings are an important step toward magnon-based devices, where electric-field-only control is highly desirable., Comment: 34 pages, 4 figures, 9 supplemental figures

Published

2022

2. Nonvolatile Electric-Field Control of Inversion Symmetry

Author

Caretta, Lucas, Shao, Yu-Tsun, Yu, Jia, Mei, Antonio B., Grosso, Bastien F., Dai, Cheng, Behera, Piush, Lee, Daehun, McCarter, Margaret, Parsonnet, Eric, P., Harikrishnan K., Xue, Fei, Barnard, Ed, Ganschow, Steffen, Raja, Archana, Martin, Lane W., Chen, Long-Qing, Fiebig, Manfred, Lai, Keji, Spaldin, Nicola A., Muller, David A., Schlom, Darrell G., and Ramesh, Ramamoorthy

Subjects

Condensed Matter - Materials Science

Abstract

In condensed-matter systems, competition between ground states at phase boundaries can lead to significant changes in material properties under external stimuli, particularly when these ground states have different crystal symmetries. A key scientific and technological challenge is to stabilize and control coexistence of symmetry-distinct phases with external stimuli. Using BiFeO3 (BFO) layers confined between layers of the dielectric TbScO3 as a model system, we stabilize the mixed-phase coexistence of centrosymmetric and non-centrosymmetric BFO phases with antipolar, insulating and polar, semiconducting behavior, respectively at room temperature. Application of in-plane electric (polar) fields can both remove and introduce centrosymmetry from the system resulting in reversible, nonvolatile interconversion between the two phases. This interconversion between the centrosymmetric insulating and non-centrosymmetric semiconducting phases coincides with simultaneous changes in the non-linear optical response of over three orders of magnitude, a change in resistivity of over five orders of magnitude, and a change in the polar order. Our work establishes a materials platform allowing for novel cross-functional devices which take advantage of changes in optical, electrical, and ferroic responses., Comment: L Caretta and Y-T Shao contributed equally. 64 pages, 4 figures, 25 supplemental figures, 1 supplemental table

Published

2022

3. Noise Electrometry of Polar and Dielectric Materials

Author

Sahay, Rahul, Hsieh, Satcher, Parsonnet, Eric, Martin, Lane W., Ramesh, Ramamoorthy, Yao, Norman Y., and Chatterjee, Shubhayu

Subjects

Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

A qubit sensor with an electric dipole moment acquires an additional contribution to its depolarization rate when it is placed in the vicinity of a polar or dielectric material as a consequence of electrical noise arising from polarization fluctuations in the material. Here, we characterize this relaxation rate as a function of experimentally tunable parameters such as sample-probe distance, probe-frequency, and temperature, and demonstrate that it offers a window into dielectric properties of insulating materials over a wide range of frequencies and length scales. We discuss the experimental feasibility of our proposal and illustrate its ability to probe a variety of phenomena, ranging from collective polar excitations to phase transitions and disorder-dominated physics in relaxor ferroelectrics. Our proposal paves the way for a novel table-top probe of polar and dielectric materials in a parameter regime complementary to existing tools and techniques., Comment: 5 + 2 + 15 pages; 2 figures

Published

2021