S
Song Jin
Researcher at University of Wisconsin-Madison
Publications - 295
Citations - 39221
Song Jin is an academic researcher from University of Wisconsin-Madison. The author has contributed to research in topics: Nanowire & Perovskite (structure). The author has an hindex of 84, co-authored 275 publications receiving 31826 citations. Previous affiliations of Song Jin include Wisconsin Alumni Research Foundation & Cornell University.
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Journal Article
Current-Driven Dynamics of Skyrmions Stabilized in MnSi Nanowires Revealed by Topological Hall Effect
TL;DR: It is shown in nanowires that under the high current density of 108–109 A m−2, the topological Hall effect decreases with increasing current densities, which demonstrates the current-driven motion of skyrmions generating the emergent electric field in the extendedskyrmion phase region.
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Measurement of Ultrafast Excitonic Dynamics of Few-Layer MoS2 Using State-Selective Coherent Multidimensional Spectroscopy.
Kyle J. Czech,Blaise J. Thompson,Schuyler Kain,Qi Ding,Melinda J. Shearer,Robert J. Hamers,Song Jin,John C. Wright +7 more
TL;DR: State-selective coherent multidimensional spectroscopy on the as-prepared MoS2 film resolved the dynamics of a series of diagonal and cross-peak features involving the spin-orbit split A and B excitonic states and continuum states.
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Pressure-Induced Structural Transformations of ZnO Nanowires Probed by X-ray Diffraction
TL;DR: In this article, a wurtzite-to-rocksalt phase transformation was observed, but both the onset and the completion pressures of this transformation were enhanced compared with all previously studied morphologies of ZnO, including nanocrystals and their bulk counterparts.
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Two Are Better than One: Heterostructures Improve Hydrogen Evolution Catalysis
TL;DR: Hu et al. as discussed by the authors proposed a synergistic hybrid catalysts, composed of nanoscale heterostructures of layered MoS 2 and layered double hydroxides (LDHs), that can dramatically enhance the HER catalysis process in alkaline solutions.
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Influence of Hole-Sequestering Ligands on the Photostability of CdSe Quantum Dots
TL;DR: In this article, small organic molecules acting as hole-accepting ligands can be very effective in reducing photooxidation of CdSe QDs, and the aromatic amine, 4-dimethylaminothiophenol (DMATP), is shown to be especially effective in enhancing the stability of QD-sensitized solar cells when illuminated in air or in aqueous environments.