Ch. Binek
University of Nebraska–Lincoln
13 Papers
35 Citations
Ch. Binek is an academic researcher from University of Nebraska–Lincoln. The author has contributed to research in topics: Exchange bias & Magnetic field. The author has an hindex of 9, co-authored 13 publications.
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Papers
The 2020 magnetism roadmap
E. Y. Vedmedenko,Roland Kawakami,Denis D. Sheka,Pietro Gambardella,Andrei Kirilyuk,Atsufumi Hirohata,Ch. Binek,Oksana Chubykalo-Fesenko,Stefano Sanvito,Brian J. Kirby,Julie Grollier,Karin Everschor-Sitte,Tobias Kampfrath,Tobias Kampfrath,Chun-Yeol You,Andreas Berger +15 more
TL;DR: The very relevant advances in the field of magnetism research during the past years make yet another Magnetism Roadmap a very sensible and timely endeavour, and allow its authors and readers to take another broad-based, but concise look at the most significant developments in magnetism.
Optimization of magneto-optical Kerr setup: analyzing experimental assemblies using Jones matrix formalism.
TL;DR: A comparative study on an experimental and theoretical optimization of magneto-optical Kerr setups based on photoelastic modulation and phase sensitive detector methodology finds one particular setup which maximizes I(omega) as well as I2 omega and maximizes the signal-to-noise ratio.
Compact Modeling and Design of Magneto-Electric Transistor Devices and Circuits
Nishtha Sharma,Ch. Binek,Andrew Marshall,Jonathan P. Bird,Peter A. Dowben,Dmitri E. Nikonov +5 more
- 01 Sep 2018
TL;DR: Benchmarking results show that these Verilog-A based model MEFET devices perform better in terms of energy and delay for implementing more complex functions, than the basic logic gates.
17
Tunable Exchange Bias Effects
Ch. Binek
- 01 Jan 2009
TL;DR: In this article, the authors discuss the potential use of electrically controlled exchange bias in spintronic applications and discuss the extrinsic control mechanisms of the interface magnetization in exchange bias heterostructures.
12
Magnetic entropy changes in nanogranular Fe:Ni61Cu39
TL;DR: In this article, an artificial environment-friendly Gd-free magnetic nanostructures for magnetic cooling are investigated by temperature-dependent magnetic measurements, where two-phase nanocomposites where nanoclusters (Fe) are embedded in a Ni61Cu39 matrix are considered.