M
M. Zalalutdinov
Researcher at United States Naval Research Laboratory
Publications - 32
Citations - 812
M. Zalalutdinov is an academic researcher from United States Naval Research Laboratory. The author has contributed to research in topics: Resonator & Ferromagnetic resonance. The author has an hindex of 11, co-authored 31 publications receiving 736 citations. Previous affiliations of M. Zalalutdinov include United States Department of the Navy.
Papers
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Journal ArticleDOI
Wafer-scale reduced graphene oxide films for nanomechanical devices.
Jeremy T. Robinson,M. Zalalutdinov,Jeffrey W. Baldwin,Eric S. Snow,Zhongqing Wei,Paul E. Sheehan,Brian H. Houston +6 more
TL;DR: Graphene oxide films' ability to withstand high in-plane tension as well as their high Q-values reveals that film integrity is enhanced by platelet-platelet bonding unavailable in pure graphite.
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Engineering Graphene Mechanical Systems
M. Zalalutdinov,Jeremy T. Robinson,Chad E. Junkermeier,James C. Culbertson,Thomas L. Reinecke,Rory Stine,Paul E. Sheehan,Brian H. Houston,Eric S. Snow +8 more
TL;DR: The ability to fine-tune intraplatelet mechanical properties through chemical modification and to locally activate direct carbon-carbon bonding within carbon-based nanomaterials will transform these systems into true "materials-by-design" for nanomechanics.
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Ultrathin Single Crystal Diamond Nanomechanical Dome Resonators
M. Zalalutdinov,M.P. Ray,Douglas M. Photiadis,Jeremy T. Robinson,Jeffrey W. Baldwin,J. E. Butler,Tatyana Feygelson,Bradford B. Pate,Brian H. Houston +8 more
TL;DR: Shell-type resonators only 70 nm thick, the thinnest single crystal diamond structures produced to date, demonstrate a high-quality factor and suggest an extrinsic origin to the dominant dissipation mechanism and methods to further enhance resonator performance.
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Damping Models for Microcantilevers, Bridges, and Torsional Resonators in the Free-Molecular-Flow Regime
TL;DR: In this article, the authors present simple models for determining the damping and the quality factor of microcantilever, bridge, and paddle resonators in vertical, horizontal, and torsional motion, using a consistent model of gas-surface interaction, operating in the free-molecular-flow regime.
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Spin-Mechanical Coupling of an InAs Quantum Dot Embedded in a Mechanical Resonator.
Samuel G. Carter,A. S. Bracker,Garnett W. Bryant,Mijin Kim,Chul Soo Kim,M. Zalalutdinov,Michael K. Yakes,Cyprian Czarnocki,Joshua Casara,Michael Scheibner,D. Gammon +10 more
TL;DR: In this paper, the authors demonstrate strain-induced coupling between a hole spin in a quantum dot and mechanical motion of a cantilever by measuring optical transitions of quantum dots integrated into GaAs mechanical resonators synchronously with the motion of driven resonators.