Yuri Galperin
Russian Academy of Sciences
164 Papers
504 Citations
Yuri Galperin is an academic researcher from Russian Academy of Sciences. The author has contributed to research in topics: Superconductivity & Magnetic field. The author has an hindex of 24, co-authored 164 publications. Previous affiliations of Yuri Galperin include Argonne National Laboratory & Norwegian Academy of Science and Letters.
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Papers
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On the theory of thermoelectric phenomena in superconductors
TL;DR: In this paper, the authors argue that the charge on-conservation arguments by Marinescu and Overhauser do not require any revision of the Boltzmann transport equation in superconductors, and show that their ''electron-conserving transport theory'' contradicts thermodynamics.
20
Statistics of Deep Energy States in Coulomb Glasses
TL;DR: The distribution of the local minima is exponential, which is in agreement with extreme value statistics considerations, and the relaxation of the system energy shows logarithmic time dependence reflecting the ultrametric structure of theSystem.
19
Metal frame as local protection of superconducting films from thermomagnetic avalanches
TL;DR: In this article, a normal-metal frame surrounding a selected region inside the film area can provide efficient protection from the dendritic avalanches during their propagation stage, and the level of screening depends on the ratio of the sheet conductance of the metal and the superconductor in the resistive state.
Quantized acoustoelectric current in a finite-length ballistic quantum channel: The noise spectrum
TL;DR: In this article, a phenomenological description of the process, in terms of a random pulse sequence, is proposed, and the important ingredients of this description are the probabilities for a surface acoustic wave well to capture n electrons.
18
Nucleation and propagation of thermomagnetic avalanches in thin-film superconductors
TL;DR: In this article, the authors consider ultra-fast dendritic flux avalanches in thin superconducting disks and demonstrate that the combination of the linear stability analysis with the numerical approach provides an efficient framework for understanding the ultrafast coupled non-local dynamics of electromagnetic fields and dissipation in superconductor films.