143,847 research outputs found

    Averages and moments associated to class numbers of imaginary quadratic fields

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    For any odd prime β„“\ell, let hβ„“(βˆ’d)h_\ell(-d) denote the β„“\ell-part of the class number of the imaginary quadratic field Q(βˆ’d)\mathbb{Q}(\sqrt{-d}). Nontrivial pointwise upper bounds are known only for β„“=3\ell =3; nontrivial upper bounds for averages of hβ„“(βˆ’d)h_\ell(-d) have previously been known only for β„“=3,5\ell =3,5. In this paper we prove nontrivial upper bounds for the average of hβ„“(βˆ’d)h_\ell(-d) for all primes β„“β‰₯7\ell \geq 7, as well as nontrivial upper bounds for certain higher moments for all primes β„“β‰₯3\ell \geq 3.Comment: 26 pages; minor edits to exposition and notation, to agree with published versio

    A documentation of two- and three-dimensional shock-separated turbulent boundary layers

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    A shock-related separation of a turbulent boundary layer has been studied and documented. The flow was that of an axisymmetric turbulent boundary layer over a 5.02-cm-diam cylinder that was aligned with the wind tunnel axis. The boundary layer was compressed by a 30 deg half-angle conical flare, with the cone axis inclined at an angle alpha to the cylinder axis. Nominal test conditions were P sub tau equals 1.7 atm and M sub infinity equals 2.85. Measurements were confined to the upper-symmetry, phi equals 0 deg, plane. Data are presented for the cases of alpha equal to 0. 5. and 10 deg and include mean surface pressures, streamwise and normal mean velocities, kinematic turbulent stresses and kinetic energies, as well as reverse-flow intermittencies. All data are given in tabular form; pressures, streamwise velocities, turbulent shear stresses, and kinetic energies are also presented graphically

    The energy partitioning of non-thermal particles in a plasma: or the Coulomb logarithm revisited

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    The charged particle stopping power in a highly ionized and weakly to moderately coupled plasma has been calculated to leading and next-to-leading order by Brown, Preston, and Singleton (BPS). After reviewing the main ideas behind this calculation, we use a Fokker-Planck equation derived by BPS to compute the electron-ion energy partitioning of a charged particle traversing a plasma. The motivation for this application is ignition for inertial confinement fusion -- more energy delivered to the ions means a better chance of ignition, and conversely. It is therefore important to calculate the fractional energy loss to electrons and ions as accurately as possible, as this could have implications for the Laser Megajoule (LMJ) facility in France and the National Ignition Facility (NIF) in the United States. The traditional method by which one calculates the electron-ion energy splitting of a charged particle traversing a plasma involves integrating the stopping power dE/dx. However, as the charged particle slows down and becomes thermalized into the background plasma, this method of calculating the electron-ion energy splitting breaks down. As a result, the method suffers a systematic error of order T/E0, where T is the plasma temperature and E0 is the initial energy of the charged particle. In the case of DT fusion, for example, this can lead to uncertainties as high as 10% or so. The formalism presented here is designed to account for the thermalization process, and in contrast, it provides results that are near-exact.Comment: 10 pages, 3 figures, invited talk at the 35th European Physical Society meeting on plasma physic

    Simultaneous Integer Values of Pairs of Quadratic Forms

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    We prove that a pair of integral quadratic forms in 5 or more variables will simultaneously represent "almost all" pairs of integers that satisfy the necessary local conditions, provided that the forms satisfy a suitable nonsingularity condition. In particular such forms simultaneously attain prime values if the obvious local conditions hold. The proof uses the circle method, and in particular pioneers a two-dimensional version of a Kloosterman refinement.Comment: 63 page

    The persistence of wishful thinking: Response to "Updated thinking on positivity ratios"

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    This is a response to Barbara Fredrickson's comment [American Psychologist 68, 814-822 (2013)] on our article arXiv:1307.7006. We analyze critically the renewed claims made by Fredrickson (2013) concerning positivity ratios and "flourishing", and attempt to disentangle some conceptual confusions; we also address the alleged empirical evidence for nonlinear effects. We conclude that there is no evidence whatsoever for the existence of any "tipping points", and only weak evidence for the existence of any nonlinearity of any kind. Our original concern, that the application of advanced mathematical techniques in psychology and related disciplines may not always be appropriate, remains undiminished.Comment: LaTeX2e, 10 pages including 6 Postscript figure

    Positive psychology and romantic scientism: Reply to comments on Brown, Sokal, & Friedman (2013)

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    This is a response to five comments [American Psychologist 69, 626-629 and 632-635 (2014)] on our article arXiv:1307.7006.Comment: PDF, 9 page
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