R. S. Weidman scite author profile

R. S. Weidman

5Publications

18Citation Statements Received

25Citation Statements Given

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University of Illinois Urbana-Champaign, Michigan Technological University

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Lattice Constant at the Insulator-Metal Transition of Crystalline Xenon

et al. 1980

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The metallization lattice constant for fee Xe has been calculated in three different, independent ways. The result is relatively insensitive to basis set, details of local exchangecorrelation potential, or use of the muffin-tin potential. The calculated metallization lattice constant is 7.9 a.u. or P=1. 28 Mbar, confirming Ross and McMahan's calculation but disagreeing with Nelson and Ruoff's experimental value. PACS numbers: 71.30.+ h, 64.30.+ t, 71.25.Tn Metallic conduction in Xe at 330 kbar and 32 K has been reported by Nelson and Ruoff. 1 Subsequently, Ross and McMahan 2 reported an augmented-plane-wave calculation (APW) with HedinLundquist local exchange and correlation. They found no metallization until P= 1.3 Mbar, a result confirmed by Worth and Trickey 3 and by Wilkins and Williams. 3 In view of the fact that simple local-density theories always give a smaller band gap at P = 0 than the experimental value, 4 it is quite surprising that the calculated metallization pressure is almost a factor of 4 greater than that reported from experiment. It is especially surprising in view of the excellent agreement 2 ' 5 between calculated and measured P-V curves over the entire pressure range. We have therefore undertaken an extensive check to see whether we could uncover any flaw in the pressure calculations.Our first concern was muffin-tin effects introduced by the standard implementation of the APW formulism, as well as related effects in the newly developed augmented-spherical-wave method 6 used by Wilkins and Williams (Ref. 3). Recently two of us (A.K.R. and S.B.T.) have developed a computer code which enables one to use our selfconsistent, muffin-tin APW output as input to the Wang-Calloway 7 linear combination of Gaussiantype orbitals (LCGTO) code. We are enabled thus to assess muffin-tin effects by direct, systematic calculations. The LCGTO Ansatz opens up the possibilty of basis-set inadequacies, of course. We have attempted to confront that problem in two ways. First, we have chosen a rather large Gaussian basis (16 s, 12 p, 8 d) of Huzinaga. 8 Second, we have used the local orbitals, mixed basis (Slater-type orbitals plus plane waves, hereafter STO + PW) scheme of Kunz. 9 Here we used STO basis set contracted to 5s, 4/>, 2d functions plus 113 plane waves. Our third concern was with the details of the local-exchange-correlation model employed. To probe this possible source of discrepancy with experiment, we did the APW and LCGTO calculations usingXa exchange-correlation with the so-called virial-theorem a, 10 while the STO + PW calculation used the KohnSham-Gaspar (KSG) value of a plus a self-energy correction. 11 All calculations were done on a 256-point first-Brillouin-zone mesh c Neither the LCGTO nor the STO + PW computer codes are equipped at present to compute total energies and hence T=0 K static lattice P-V curves. Therefore, we have tabulated our data as a function of the cubic lattice constant and used the APW-Xa equation of state to convert to a corresponding pressure (see Table I). Since it is...

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Electronic and transport properties of CuCl

Kunz

Weidman

Collins

2009

Int. J. Quantum Chem.

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In this article we present a set of fully self-consistent studiesof the energy bands' defect and/or impurity levels in CuCI. These studies are performed as a function of lattice constant and uniaxial compression along the (001) direction. The methods employed are the self-consistent Hartree-Fock plus correlation corrections method. Calculations are performed for the normal lattice constant, 3% volume reduction, and 15% volume reduction, and for a 2% reduction in lattice constant along the (001) direction. The defect and/or impurity systems studied include F centers, H-centers, OHcenters, 02-plus anion vacancy centers, and S2-plus anion vacancy centers. We find the upper valence band is largely Cu 3d in origin and that for normal lattice constant the band gap is direct, at r, and is about 4.0 eV. Under uniaxial stress or hydrostatic pressure, a weak indirect gap may be generated of insufficient width to agree with Abrikosov's hypothesis. We find, however, that defects or impurities produce electrons near the conduction band. We speculate about the role of these electrons as they may pertain to recent CuCI experiments.

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A self-consistent energy-band study in CuCl

Kunz

Weidman

1979

J. Phys. C: Solid State Phys.

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An atomistic study of grain boundary segregation and cracking

1984

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AB initio calculations of the electronic properties of polyethylene

Weidman

Bedford

Kunz

1981

Solid State Communications

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R. S. Weidman

Lattice Constant at the Insulator-Metal Transition of Crystalline Xenon

Electronic and transport properties of CuCl

A self-consistent energy-band study in CuCl

An atomistic study of grain boundary segregation and cracking

AB initio calculations of the electronic properties of polyethylene

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