Publication:
Thermophysical properties of low-density neon gas from highly accurate first-principles calculations and dielectric-constant gas thermometry measurements

cris.customurl 14453
cris.virtual.department Thermodynamik
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cris.virtual.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtual.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtual.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtual.departmentbrowse Thermodynamik
cris.virtual.departmentbrowse Thermodynamik
cris.virtual.departmentbrowse Thermodynamik
cris.virtualsource.department 96d8e6e1-6361-46c5-ae2c-a84605aadf12
cris.virtualsource.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtualsource.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtualsource.department #PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtualsource.department #PLACEHOLDER_PARENT_METADATA_VALUE#
dc.contributor.author Hellmann, Robert
dc.contributor.author Gaiser, Christof
dc.contributor.author Fellmuth, Bernd
dc.contributor.author Vasyltsova, Tatjana
dc.contributor.author Bich, Eckard
dc.date.issued 2021-04-28
dc.description.abstract New interatomic potential energy and interaction-induced polarizability curves for two ground-state neon atoms were developed and used to predict the second density, acoustic, and dielectric virial coefficients and the dilute gas shear viscosity and thermal conductivity of neon at temperatures up to 5000 K. The potential energy curve is based on supermolecular coupled-cluster (CC) calculations at very high levels up to CC with single, double, triple, quadruple, and perturbative pentuple excitations [CCSDTQ(P)]. Scalar and spin-orbit relativistic effects, the diagonal Born-Oppenheimer correction, and retardation of the dispersion interactions were taken into account. The interaction-induced polarizability curve, which in this work is only needed for the calculation of the second dielectric virial coefficient, is based on supermolecular calculations at levels up to CCSDT and includes a correction for scalar relativistic effects. In addition to these first-principles calculations, highly accurate dielectric-constant gas thermometry (DCGT) datasets measured at temperatures from 24.5 to 200 K were analyzed to obtain the difference between the second density and dielectric virial coefficients with previously unattained accuracy. The agreement of the DCGT values with the ones resulting from the first-principles calculations is, despite some small systematic deviations, very satisfactory. Apart from this combination of two virial coefficients, the calculated thermophysical property values of this work are significantly more accurate than any available experimental data.
dc.description.version NA
dc.identifier.doi 10.1063/5.0047999
dc.identifier.issn 0021-9606
dc.identifier.issn 1089-7690
dc.identifier.pmid 33940840
dc.identifier.scopus 2-s2.0-85104874388
dc.identifier.uri https://openhsu.ub.hsu-hh.de/handle/10.24405/14453
dc.language.iso en
dc.relation.journal The journal of chemical physics : JCP
dc.relation.orgunit Thermodynamik
dc.rights.accessRights metadata only access
dc.title Thermophysical properties of low-density neon gas from highly accurate first-principles calculations and dielectric-constant gas thermometry measurements
dc.type Research article
dspace.entity.type Publication
hsu.peerReviewed
hsu.uniBibliography
oaire.citation.endPage 16
oaire.citation.issue 16
oaire.citation.startPage 1
oaire.citation.volume 154
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