69 research outputs found

    The Thomas Precession Factor in Spin-Orbit Interaction

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    The origin of the Thomas factor 1/2 in the spin-orbit hamiltonian can be understood by considering the case of a classical electron moving in crossed electric and magnetic fields chosen such that the electric Coulomb force is balanced by the magnetic Lorentz force.Comment: PDF File, 5 pages, to appear in American Journal of Physic

    AlSb/InAs/AlSb quantum wells

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    Researchers studied the InAs/AlSb system recently, obtaining 12nm wide quantum wells with room temperature mobilities up to 28,000 cm(exp 2)/V center dot S and low-temperature mobilities up to 325,000 cm(exp 2)/V center dot S, both at high electron sheet concentrations in the 10(exp 12)/cm(exp 2) range (corresponding to volume concentrations in the 10(exp 18)/cm(exp 2) range). These wells were not intentionally doped; the combination of high carrier concentrations and high mobilities suggest that the electrons are due to not-intentional modulation doping by an unknown donor in the AlSb barriers, presumably a stoichiometric defect, like an antisite donor. Inasmuch as not intentionally doped bulk AlSb is semi-insulating, the donor must be a deep one, being ionized only by draining into the even deeper InAs quantum well. The excellent transport properties are confirmed by other observations, like excellent quantum Hall effect data, and the successful use of the quantum wells as superconductive weak links between Nb electrodes, with unprecendentedly high critical current densities. The system is promising for future field effect transistors (FETs), but many processing problems must first be solved. Although the researchers have achieved FETs, the results so far have not been competitive with GaAs FETs

    Two-electron atoms, ions and molecules

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    The quantum mechanics of two-electron systems is reviewed, starting with the ground state of the helium atom and helium-like ions, with central charge Z≄2Z\ge 2. For Z=1, demonstrating the stability of the negative hydrogen ion, H−^-, cannot be achieved using a mere product of individual electron wave functions, and requires instead an explicit account for the anticorrelation among the two electrons. The wave function proposed by Chandrasekhar is revisited, where the permutation symmetry is first broken and then restored by a counter-term. More delicate problems can be studied using the same strategy: the stability of hydrogen-like ions (M+,m−,m−)(M^+,m^-,m^-) for any value of the proton-to-electron mass ratio M/mM/m; the energy of the lowest spin-triplet state of helium and helium-like ions; the stability of the doubly-excited hydrogen ion with unnatural parity. The positronium molecule (e+,e+,e−,e−)(e^+,e^+,e^-,e^-), which has been predicted years ago and discovered recently, can also be shown to be stable against spontaneous dissociation, though the calculation is a little more involved. Emphasis is put on symmetry breaking which can either spoil or improve the stability of systems.Comment: 16 pages, 2 figure

    Quasiparticle dynamics in ballistic weak links under weak voltage bias: An elementary treatment

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    A simple one-dimensional model for SNS weak links in the ballistic limit is presented. In the presence of a bias voltage, the quasiparticle state at any given instant of time is described as a superposition of that particular set of phase-dependent Andreev bound states that belongs to the specific phase difference present at this instant between the superconducting banks. The treatment -- basically a form of adiabatic perturbation theory -- has a strong formal similarity to the treatment of the k-space dynamics of an electron in a periodic potential under perturbation by an external electric field, sufficiently strong to cause transitions across the energy gaps between bands (Zener tunneling). It is shown that the quasiparticle wave function retains its phase information during analogous transitions between Andreev bands. The experimental observation of Shapiro steps at one-half the canonical voltage follows naturally from the model, along with some of the experimental properties of these steps, especially their much weaker temperature dependence, compared to the canonical steps.Comment: 21 pages, 3 figures, PDF format. To be published in Superlattices and Microstructures (Special issue on mesoscopic superconductivity

    Beth Levine in memoriam

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    Beth Levine was born on 7 April 1960 in Newark, New Jersey. She went to college at Brown University where she received an A.B. Magna Cum Laude, and she attended medical school at Cornell University Medical College, receiving her MD in 1986. She completed her internship and residency in Internal Medicine at Mount Sinai Hospital in New York, and her fellowship in Infectious Diseases at The Johns Hopkins Hospital. Most recently, Beth was a Professor of Internal Medicine and Microbiology, Director of the Center for Autophagy Research, and holder of the Charles Sprague Distinguished Chair in Biomedical Science at the University of Texas Southwestern Medical Center in Dallas. Beth died on 15 June 2020 from cancer. Beth is survived by her husband, Milton Packer, and their two children, Rachel (26 years old) and Ben (25 years old). Dr. Levine was as an international leader in the field of autophagy research. Her laboratory identified the mammalian autophagy gene BECN1/beclin 1; identified conserved mechanisms underlying the regulation of autophagy (e.g. BCL2-BECN1 complex formation, insulin-like signaling, EGFR, ERBB2/HER2 and AKT1-mediated BECN1 phosphosphorylation); and provided the first evidence that autophagy genes are important in antiviral host defense, tumor suppression, lifespan extension, apoptotic corpse clearance, metazoan development, Na,K-ATPase-regulated cell death, and the beneficial metabolic effects of exercise. She developed a potent autophagy-inducing cell permeable peptide, Tat-beclin 1, which has potential therapeutic applications in a range of diseases. She was a founding Associate Editor of the journal Autophagy and an editorial board member of Cell and Cell Host & Microbe. She has received numerous awards/honors in recognition of her scientific achievement, including: The American Cancer Society Junior Faculty Research Award (1994); election into the American Society of Clinical Investigation (2000); the Ellison Medical Foundation Senior Scholars Award in Global Infectious Diseases (2004); elected member, American Association of Physicians (2005); appointment as a Howard Hughes Medical Institute Investigator (2008); Edith and Peter O’Donnell Award in Medicine (2008); elected fellow, American Association for the Advancement of Science (2012); election into the National Academy of Sciences (2013); election into the Academy of Medicine, Engineering and Science of Texas (2013); the ASCI Stanley J. Korsmeyer Award (2014); Phyllis T. Bodel Women in Medicine Award, Yale University School of Medicine (2018); recipient, Barcroft Medal, Queen’s University Belfast (2018).Fil: An, Zhenyi. No especifĂ­ca;Fil: Ballabi, Andrea. No especifĂ­ca;Fil: Bennett, Lynda. No especifĂ­ca;Fil: Boya, Patricia. No especifĂ­ca;Fil: Cecconi, Francesco. No especifĂ­ca;Fil: Chiang, Wei Chung. No especifĂ­ca;Fil: Codogno, Patrice. No especifĂ­ca;Fil: Colombo, Maria Isabel. No especifĂ­ca;Fil: Cuervo, Ana Maria. No especifĂ­ca;Fil: Debnath, Jayanta. No especifĂ­ca;Fil: Deretic, Vojo. No especifĂ­ca;Fil: Dikic, Ivan. No especifĂ­ca;Fil: Dionne, Keith. No especifĂ­ca;Fil: Dong, Xiaonan. No especifĂ­ca;Fil: Elazar, Zvulun. No especifĂ­ca;Fil: Galluzzi, Lorenzo. No especifĂ­ca;Fil: Gentile, Frank. No especifĂ­ca;Fil: Griffin, Diane E.. No especifĂ­ca;Fil: Hansen, Malene. No especifĂ­ca;Fil: Hardwick, J. Marie. No especifĂ­ca;Fil: He, Congcong. No especifĂ­ca;Fil: Huang, Shu Yi. No especifĂ­ca;Fil: Hurley, James. No especifĂ­ca;Fil: Jackson, William T.. No especifĂ­ca;Fil: Jozefiak, Cindy. No especifĂ­ca;Fil: Kitsis, Richard N.. No especifĂ­ca;Fil: Klionsky, Daniel J.. No especifĂ­ca;Fil: Kroemer, Guido. No especifĂ­ca;Fil: Meijer, Alfred J.. No especifĂ­ca;Fil: MelĂ©ndez, Alicia. No especifĂ­ca;Fil: Melino, Gerry. No especifĂ­ca;Fil: Mizushima, Noboru. No especifĂ­ca;Fil: Murphy, Leon O.. No especifĂ­ca;Fil: Nixon, Ralph. No especifĂ­ca;Fil: Orvedahl, Anthony. No especifĂ­ca;Fil: Pattingre, Sophie. No especifĂ­ca;Fil: Piacentini, Mauro. No especifĂ­ca;Fil: Reggiori, Fulvio. No especifĂ­ca;Fil: Ross, Theodora. No especifĂ­ca;Fil: Rubinsztein, David C.. No especifĂ­ca;Fil: Ryan, Kevin. No especifĂ­ca;Fil: Sadoshima, Junichi. No especifĂ­ca;Fil: Schreiber, Stuart L.. No especifĂ­ca;Fil: Scott, Frederick. No especifĂ­ca;Fil: Sebti, Salwa. No especifĂ­ca;Fil: Shiloh, Michael. No especifĂ­ca;Fil: Shoji, Sanae. No especifĂ­ca;Fil: Simonsen, Anne. No especifĂ­ca;Fil: Smith, Haley. No especifĂ­ca;Fil: Sumpter, Kathryn M.. No especifĂ­ca;Fil: Thompson, Craig B.. No especifĂ­ca;Fil: Thorburn, Andrew. No especifĂ­ca;Fil: Thumm, Michael. No especifĂ­ca;Fil: Tooze, Sharon. No especifĂ­ca;Fil: Vaccaro, Maria Ines. Consejo Nacional de Investigaciones CientĂ­ficas y TĂ©cnicas. Oficina de CoordinaciĂłn Administrativa Houssay. Instituto de BioquĂ­mica y Medicina Molecular. Universidad de Buenos Aires. Facultad Medicina. Instituto de BioquĂ­mica y Medicina Molecular; ArgentinaFil: Virgin, Herbert W.. No especifĂ­ca;Fil: Wang, Fei. No especifĂ­ca;Fil: White, Eileen. No especifĂ­ca;Fil: Xavier, Ramnik J.. No especifĂ­ca;Fil: Yoshimori, Tamotsu. No especifĂ­ca;Fil: Yuan, Junying. No especifĂ­ca;Fil: Yue, Zhenyu. No especifĂ­ca;Fil: Zhong, Qing. No especifĂ­ca

    Molecular mechanisms of cell death: recommendations of the Nomenclature Committee on Cell Death 2018.

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    Over the past decade, the Nomenclature Committee on Cell Death (NCCD) has formulated guidelines for the definition and interpretation of cell death from morphological, biochemical, and functional perspectives. Since the field continues to expand and novel mechanisms that orchestrate multiple cell death pathways are unveiled, we propose an updated classification of cell death subroutines focusing on mechanistic and essential (as opposed to correlative and dispensable) aspects of the process. As we provide molecularly oriented definitions of terms including intrinsic apoptosis, extrinsic apoptosis, mitochondrial permeability transition (MPT)-driven necrosis, necroptosis, ferroptosis, pyroptosis, parthanatos, entotic cell death, NETotic cell death, lysosome-dependent cell death, autophagy-dependent cell death, immunogenic cell death, cellular senescence, and mitotic catastrophe, we discuss the utility of neologisms that refer to highly specialized instances of these processes. The mission of the NCCD is to provide a widely accepted nomenclature on cell death in support of the continued development of the field

    Quantum mechanics : for engineering, materials science and applied physics/ Kroemer

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    xxx, 639 hal. : ill. ; 24 cm
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