Open AccessFirst-Principles Calculation of the Third Virial Coefficient of Helium
Author(s) -
Giovanni Garberoglio,
Allan H. Harvey
Publication year - 2009
Publication title -
journal of research of the national institute of standards and technology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.202
H-Index - 59
eISSN - 2165-7254
pISSN - 1044-677X
DOI - 10.6028/jres.114.018
Subject(s) - virial coefficient , semiclassical physics , helium , path integral monte carlo , physics , range (aeronautics) , work (physics) , monte carlo method , metrology , virial theorem , path integral formulation , statistical physics , thermodynamics , atomic physics , quantum mechanics , materials science , mathematics , statistics , galaxy , composite material , quantum
Knowledge of the pair and three-body potential-energy surfaces of helium is now sufficient to allow calculation of the third density virial coefficient, C(T), with significantly smaller uncertainty than that of existing experimental data. In this work, we employ the best available pair and three-body potentials for helium and calculate C(T) with path-integral Monte Carlo (PIMC) calculations supplemented by semiclassical calculations. The values of C(T) presented extend from 24.5561 K to 10 000 K. In the important metrological range of temperatures near 273.16 K, our uncertainties are smaller than the best experimental results by approximately an order of magnitude, and the reduction in uncertainty at other temperatures is at least as great. For convenience in calculation of C(T) and its derivatives, a simple correlating equation is presented.
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