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  <identifier identifierType="DOI">10.18453/rosdok_id00004656</identifier>
  <creators>
    <creator>
      <creatorName nameType="Personal">Mai, Matthäus</creatorName>
      <givenName>Matthäus</givenName>
      <familyName>Mai</familyName>
      <nameIdentifier nameIdentifierScheme="GND" schemeURI="http://d-nb.info/gnd/">http://d-nb.info/gnd/1338452541</nameIdentifier>
    </creator>
  </creators>
  <titles>
    <title>A new gravity-wave parameterization for atmospheric circulation models with full respect to transience and conservation laws</title>
  </titles>
  <publisher>Universität Rostock</publisher>
  <publicationYear>2023</publicationYear>
  <resourceType resourceTypeGeneral="Text" />
  <subjects>
    <subject xml:lang="en" schemeURI="http://dewey.info/" subjectScheme="dewey">530 Physics</subject>
  </subjects>
  <dates>
    <date dateType="Created">2023</date>
  </dates>
  <language>en</language>
  <alternateIdentifiers>
    <alternateIdentifier alternateIdentifierType="PURL">https://purl.uni-rostock.de/rosdok/id00004656</alternateIdentifier>
    <alternateIdentifier alternateIdentifierType="URN">urn:nbn:de:gbv:28-rosdok_id00004656-5</alternateIdentifier>
  </alternateIdentifiers>
  <descriptions>
    <description descriptionType="Abstract">In this thesis, we present a new framework for gravity wave parameterizations, that relaxes the steady state approximation - the Radiative Transfer gravity wave Parameterization (RTP). This transient parameterization provides the local energy density of a wave field, from which the wave-mean flow interactions are calculated. Results of idealised simulations show that the wave field behaves as theoretically expected in different background configurations. This all takes place in consideration of the conservation of energy and momentum.</description>
  </descriptions>
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