Climate model boundary conditions for four Cretaceous time slices
Publication date
2007
Authors
Sewall, J.O.
Wal, R.S.W. van de
Zwan, C.J. van der
Oosterhout, C. van
Dijkstra, H.A.
Scotese, C.R.
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Supervisors
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Article
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(c) UU Universiteit Utrecht, 2007
Abstract
General circulation models (GCMs) are useful
tools for investigating the characteristics and dynamics of
past climates. Understanding of past climates contributes
significantly to our overall understanding of Earth’s climate
system. One of the most time consuming, and often daunting,
tasks facing the paleoclimate modeler, particularly those
without a geological background, is the production of surface
boundary conditions for past time periods. These boundary
conditions consist of, at a minimum, continental configurations
derived from plate tectonic modeling, topography,
bathymetry, and a vegetation distribution. Typically,
each researcher develops a unique set of boundary conditions
for use in their simulations. Thus, unlike simulations
of modern climate, basic assumptions in paleo surface
boundary conditions can vary from researcher to researcher.
This makes comparisons between results from multiple researchers
difficult and, thus, hinders the integration of studies
across the broader community. Unless special changes
to surface conditions are warranted, researcher dependent
boundary conditions are not the most efficient way to proceed
in paleoclimate investigations. Here we present surface
boundary conditions (land-sea distribution, paleotopography,
paleobathymetry, and paleovegetation distribution) for
four Cretaceous time slices (120 Ma, 110 Ma, 90Ma, and
70 Ma). These boundary conditions are modified from base
datasets to be appropriate for incorporation into numerical
studies of Earth’s climate and are available in NetCDF format
upon request from the lead author. The land-sea distribution,
bathymetry, and topography are based on the 1 ×1 (latitude
× longitude) paleo Digital Elevation Models (paleoDEMs)
of Christopher Scotese. Those paleoDEMs were adjusted using
the paleogeographical reconstructions of Ronald Blakey (Northern Arizona University) and published literature and
were then modified for use in GCMs. The paleovegetation
distribution is based on published data and reconstructions
and consultation with members of the paleobotanical community
and is represented as generalized biomes that should
be easily translatable to many vegetation-modeling schemes.