A pilot coupled climate sensitivity study is presented based on the newly developed adjoint coupled climate model, Centrum für Erdsystemforschung und Nachhaltigkeit (CEN) Earth System Assimilation Model (CESAM). To this end the components of the coupled forward model are summarized, and the generation of the adjoint code out of the model forward code through the application of the Transformation of Algorithms in FORTRAN (TAF) adjoint compiler is discussed. It is shown that simulations of the intermediate-complexity CESAM are comparable in quality to CMIP-type coupled climate models, justifying the usage of the model to compute adjoint sensitivities of the northern Europe near-surface temperature to anomalies in surface temperature, sea surface salinity, and sea ice over the North Atlantic and the Arctic on time scales of up to one month. Results confirm that on a time scale of up to a few days surface temperatures over northern Europe are influenced by Atlantic temperature anomalies just upstream of the target location. With increasingly longer time lapse, however, it is the influence of SSTs over the central and western North Atlantic on the overlying atmosphere and the associated changes in storm-track pattern that dominate the evolution of the surface European temperature. Influences of surface salinity and sea ice on the northern European temperature appear to have similar sensitivity mechanisms, invoked indirectly through their influence on near-surface temperature anomalies. The adjoint study thus confirms that the SST’s impact on the atmospheric dynamics, notably storm tracks, is the primary cause for the influence of northern European temperature changes.
MT-YBCO samples oxygenated under controlled oxygen pressure exhibited at 77 K a critical current density
jc = 85 kA cm−2 in zero field
and more than 10 kA cm−2
up to 5 T field when the external magnetic field was perpendicular to the
ab-plane of
Y123, and a jc = 23 kA cm−2
in zero field and jc
close to 1 kA cm−2
in 10 T field when the magnetic field was perpendicular to the
c-axis
of Y123. The microstructure of these samples contained an unusually high density of twins (about
30 twins µm−1) as well as a lot of stacking faults around Y211 inclusions. Using quasi-hydrostatic
high pressure–high temperature (HP–HT) treatment we may vary the twin and
dislocation densities in the material by changing the sample orientation in high
pressure apparatus, while the oxygen content of Y123 phase as well as the lattice
parameters remain unchanged. The microstructure of the material in the case
where the highest pressure has been applied in the direction perpendicular to the
ab-plane of Y123 is characterized by a very low twin density, perfect dislocations stepped
along directions and small faulted loops corresponding to CuO intercalating in the matrix. For this material
jc = 10
and 8 kA cm−2
in zero field were observed (when the external magnetic field was perpendicular to the
ab-plane and
perpendicular to the c-axis of Y123, respectively). High pressure–high temperature treatment causes an increase
in the material density (up to near the theoretical one), microhardness and fracture
toughness.
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