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Your search keyword '"Murdick, Ryan A."' showing total 19 results
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19 results on '"Murdick, Ryan A."'

1. Role of Acoustic Phonon Transport in Near- to Asperity-Contact Heat Transfer

Author

Jarzembski, Amun, Tokunaga, Takuro, Crossley, Jacob, Yun, Jeonghoon, Shaskey, Cedric, Murdick, Ryan A., Park, Inkyu, Francoeur, Mathieu, and Park, Keunhan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Acoustic phonon transport is revealed as a potential radiation-to-conduction transition mechanism for single-digit nanometer vacuum gaps. To show this, we measure heat transfer from a feedback-controlled platinum nanoheater to a laterally oscillating silicon tip as the tip-nanoheater vacuum gap distance is precisely controlled from a single-digit nanometer down to bulk contact in a high-vacuum shear force microscope. The measured thermal conductance shows a gap dependence of $d^{-5.7\pm1.1}$ in the near-contact regime, which is in good agreement with acoustic phonon transport modeling based on the atomistic Green's function framework. The obtained experimental and theoretical results suggest that acoustic phonon transport across a nanoscale vacuum gap can be the dominant heat transfer mechanism in the near- and asperity-contact regimes and can potentially be controlled by an external force stimuli., Comment: 49 pages, 17 figures (including the main text, appendix, and supplemental material)

Published
2019

2. A brief review: Ultrafast electron diffractive voltammetry: General formalism and applications

Author

Chang, Kiseok, Murdick, Ryan A., Tao, Zhensheng, Han, Tzong-Ru T., and Ruan, Chong-Yu

Subjects
Physics - Chemical Physics, Condensed Matter - Materials Science
Abstract

We present a general formalism of ultrafast diffractive voltammetry approach as a contact-free tool to investigate the ultrafast surface charge dynamics in nanostructured interfaces. As case studies, the photoinduced surface charging processes in oxidized silicon surface and the hot electron dynamics in nanoparticle-decorated interface are examined based on the diffractive voltammetry framework. We identify that the charge redistribution processes appear on the surface, sub-surface, and vacuum levels when driven by intense femtosecond laser pulses. To elucidate the voltammetry contribution from different sources, we perform controlled experiments using shadow imaging techniques and N-particle simulations to aid the investigation of the photovoltage dynamics in the presence of pho- toemission. We show that voltammetry contribution associated with photoemission has a long decay tail and plays a more visible role in the nanosecond timescale, whereas the ultrafast voltammetry are dominated by local charge transfer, such as surface charging and molecular charge transport at nanostructured interfaces. We also discuss the general applicability of the diffractive voltammetry as an integral part of quantitative ultrafast electron diffraction methodology in researching different types of interfaces having distinctive surface diffraction and boundary conditions., Comment: 14 figures

Published
2013
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3. Electronically Driven Fragmentation of Silver Nanocrystals Revealed by Ultrafast Electron Crystallography

Author

Raman, Ramani K., Murdick, Ryan A., Worhatch, Richard J., Murooka, Yoshie, Mahanti, Subhendra D., Han, Tzong-Ru T., and Ruan, Chong-Yu

Subjects
Condensed Matter - Materials Science
Abstract

We report an ultrafast electron diffraction study of silver nanocrystals under surface plasmon resonance excitation, leading to a concerted fragmentation. By examining simultaneously transient structural, thermal, and Coulombic signatures of the prefragmented state, an electronically driven nonthermal fragmentation scenario is proposed., Comment: 5 figures

Published
2013
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4. The development and applications of ultrafast electron nanocrystallography

Author

Ruan, Chong-Yu, Murooka, Yoshie, Raman, Ramani K., Murdick, Ryan A., Worhatch, Richard J., and Pell, Aric

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We review the development of ultrafast electron nanocrystallography as a method for investigating structural dynamics for nanoscale materials and interfaces. Its sensitivity and resolution are demonstrated in the studies of surface melting of gold nanocrystals, nonequilibrium transformation of graphite into reversible diamond-like intermediates, and molecular scale charge dynamics, showing a versatility for not only determining the structures, but also the charge and energy redistribution at interfaces. A quantitative scheme for three-dimensional retrieval of atomic structures is demonstrated with few-particle (< 1000) sensitivity, establishing this nanocrystallographic method as a tool for directly visualizing dynamics within isolated nanomaterials with atomic scale spatio-temporal resolution., Comment: 33 pages, 17 figures (Review article, 2008 conference of ultrafast electron microscopy conference and ultrafast sciences)

Published
2009
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5. Photovoltage Dynamics of the Hydroxylated Si(111) Surface Investigated by Ultrafast Electron Diffraction

Author

Murdick, Ryan A., Raman, Ramani K., Murooka, Yoshie, and Ruan, Chong-Yu

Subjects
Condensed Matter - Materials Science
Abstract

We present a novel method to measure transient photovoltage at nanointerfaces using ultrafast electron diffraction. In particular, we report our results on the photoinduced electronic excitations and their ensuing relaxations in a hydroxyl-terminated silicon surface, a standard substrate for fabricating molecular electronics interfaces. The transient surface voltage is determined by observing Coulomb refraction changes induced by the modified space-charge barrier within a selectively probed volume by femtosecond electron pulses. The results are in agreement with ultrafast photoemission studies of surface state charging, suggesting a charge relaxation mechanism closely coupled to the carrier dynamics near the surface that can be described by a drift-diffusion model. This study demonstrates a newly implemented ultrafast diffraction method for investigating interfacial processes, with both charge and structure resolution., Comment: 5 pages, 5 figures

Published
2008
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6. Dynamics of Size-Selected Gold Nanoparticles Studied by Ultrafast Electron Nanocrystallography

Author

Ruan, Chong-Yu, Murooka, Yoshie, Raman, Ramani K., and Murdick, Ryan A.

Subjects
Condensed Matter - Materials Science
Abstract

We report the studies of ultrafast electron nanocrystallography on size-selected Au nanoparticles (2-20 nm) supported on a molecular interface. Reversible surface melting, melting, and recrystallization were investigated with dynamical full-profile radial distribution functions determined with sub-picosecond and picometer accuracies. In an ultrafast photoinduced melting, the nanoparticles are driven to a non-equilibrium transformation, characterized by the initial lattice deformations, nonequilibrium electron-phonon coupling, and upon melting, the collective bonding and debonding, transforming nanocrystals into shelled nanoliquids. The displasive structural excitation at premelting and the coherent transformation with crystal/liquid coexistence during photomelting differ from the reciprocal behavior of recrystallization, where a hot lattice forms from liquid and then thermally contracts. The degree of structural change and the thermodynamics of melting are found to depend on the size of nanoparticle., Comment: 16 pages, 4 figures

Published
2007
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7. Light-Induced Charge Carrier Dynamics at Nanostructured Interfaces Investigated by Ultrafast Electron Diffractive Photovoltammetry

Author

Chang, Kiseok, Murdick, Ryan A., Han, Tzong-Ru T., Yuan, Fei, Ruan, Chong-Yu, Wang, Zhiming M, Series editor, Waag, Andreas, Series editor, Salamo, Greg, Series editor, Kishimoto, Naoki, Series editor, Bellucci, Stefano, Series editor, Park, Young June, Series editor, Wu, Jiang, editor, and Wang, Zhiming M., editor

Published
2014
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11. The effect of the cut surface during electrical stimulation of a cardiac wedge preparation

Author

Roth, Bradley J., Patel, Salil G., and Murdick, Ryan A.

Subjects
Heart diseases -- Research, Heart diseases -- Diagnosis, Wedges -- Research, Biological sciences, Business, Computers, Health care industry
Abstract

Optical mapping from the cut surface of a 'wedge preparation' allows observation inside the heart wall, below the epicardium or endocardium. We use numerical simulations based on the bidomain model to illustrate how the transmembrane potential is influenced by the cut surface. The distribution of transmembrane potential around a unipolar cathode depends on the fiber angle. Fur intermediate angles, hyperpolarization appears on only one side of the electrode, and is large and widespread. Index Terms--Bidomain, cardiac, electrical stimulation, fiber geometry, wedge preparation.

Published
2006

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