528 research outputs found
Variations of the Atlantic meridional overturning circulation in control and transient simulations of the last millennium
The variability of the Atlantic meridional overturing circulation (AMOC) strength is investigated in control experiments and in transient simulations of up to the last millennium using the low-resolution Community Climate System Model version 3. In the transient simulations the AMOC exhibits enhanced low-frequency variability that is mainly caused by infrequent transitions between two semi-stable circulation states which amount to a 10 percent change of the maximum overturning. One transition is also found in a control experiment, but the time-varying external forcing significantly increases the probability of the occurrence of such events though not having a direct, linear impact on the AMOC. The transition from a high to a low AMOC state starts with a reduction of the convection in the Labrador and Irminger Seas and goes along with a changed barotropic circulation of both gyres in the North Atlantic and a gradual strengthening of the convection in the Greenland-Iceland-Norwegian (GIN) Seas. In contrast, the transition from a weak to a strong overturning is induced by decreased mixing in the GIN Seas. As a consequence of the transition, regional sea surface temperature (SST) anomalies are found in the midlatitude North Atlantic and in the convection regions with an amplitude of up to 3 K. The atmospheric response to the SST forcing associated with the transition indicates a significant impact on the Scandinavian surface air temperature (SAT) in the order of 1 K. Thus, the changes of the ocean circulation make a major contribution to the Scandinavian SAT variability in the last millennium
Time of emergence of trends in ocean biogeochemistry
For the detection of climate change, not only the magnitude of a trend signal
is of significance. An essential issue is the time period required by the
trend to be detectable in the first place. An illustrative measure for this
is time of emergence (ToE), that is, the point in time when a signal finally
emerges from the background noise of natural variability. We investigate the
ToE of trend signals in different biogeochemical and physical surface
variables utilizing a multi-model ensemble comprising simulations of 17 Earth
system models (ESMs). We find that signals in ocean biogeochemical variables
emerge on much shorter timescales than the physical variable sea surface
temperature (SST). The ToE patterns of <i>p</i>CO<sub>2</sub> and pH are spatially
very similar to DIC (dissolved inorganic carbon), yet the trends emerge much
faster – after roughly 12 yr for the majority of the global ocean area,
compared to between 10 and 30 yr for DIC. ToE of 45–90 yr are even larger
for SST. In general, the background noise is of higher importance in
determining ToE than the strength of the trend signal. In areas with high
natural variability, even strong trends both in the physical climate and
carbon cycle system are masked by variability over decadal timescales. In
contrast to the trend, natural variability is affected by the seasonal cycle.
This has important implications for observations, since it implies that
intra-annual variability could question the representativeness of irregularly
sampled seasonal measurements for the entire year and, thus, the
interpretation of observed trends
Reconstructing climate variability from Greenland ice sheet accumulation: An ERA40 study
Re-analysis data covering the period 1958–2001 are used to investigate the relationship between regional, inter-annual snow accumulation variability over the Greenland Ice Sheet (GrIS) and large scale circulation patterns, cyclone frequency, and strength. Four regions of the GrIS have been identified that are highly independent with respect to accumulation variability. Accumulation indices of three of these regions are associated with distinct large-scale circulation patterns: Central-western GrIS reveals an inverse relationship with a NAO-like pattern, the south-west a positive correlation with a high pressure bridge from central North Atlantic to Scandinavia, and the south-eastern GrIS a positive correlation with a high-pressure anomaly over the Greenland Sea. These large-scale patterns also impact European climate in different ways. Accumulation variability in north-eastern GrIS, however, is dominated by cyclones originating from the Greenland Sea. Thus, Greenland ice core accumulation records offer the potential to reconstruct various large-scale circulation patterns and regional storm activity
Stable equatorial ice belts at high obliquity in a coupled atmosphere-ocean model
Various climate states at high obliquity are realized for a range of stellar
irradiance using a dynamical atmosphere-ocean-sea ice climate model in an
Aquaplanet configuration. Three stable climate states are obtained that differ
in the extent of the sea ice cover. For low values of irradiance the model
simulates a Cryoplanet that has a perennial global sea ice cover. By increasing
stellar irradiance, transitions occur to an Uncapped Cryoplanet with a
perennial equatorial sea ice belt, and eventually to an Aquaplanet with no ice.
Using an emulator model we find that the Uncapped Cryoplanet is a robust stable
state for a range of irradiance and high obliquities and contrast earlier
results that high-obliquity climate states with an equatorial ice belt may be
unsustainable or unachievable. When the meridional ocean heat flux is
strengthened, the parameter range permitting a stable Uncapped Cryoplanet
decreases due to melting of equatorial sea ice. Beyond a critical threshold of
meridional ocean heat flux, the perennial equatorial ice belt disappears.
Therefore, a vigorous ocean circulation may render it unstable. Our results
suggest that perennial equatorial ice cover is a viable climate state of a
high-obliquity exoplanet. However, due to multiple equilibria, this state is
only reached from more glaciated conditions, and not from less glaciated
conditions.Comment: 9 pages, 5 figures, ApJ accepte
Final Report: Buffalo National River Ecosystems
The objective of this study was to sample the Buffalo River on a seasonal basis for a year, in order to determine whether any potential water quality problems existed
Impact-driven effects in thin-film growth: steering and transient mobility at the Ag(110) surface
Low-energy atomic impacts on the Ag(110) surface are investigated by
molecular dynamics simulations based on reliable many-body semiempirical
potentials. Trajectory deflections (steering) caused by the atom-surface
interaction are observed, together with impact-following, transient-mobility
effects. Such processes are quantitatively analysed and their dependence on the
initial kinetic energy and on the impinging direction is discussed. A clear
influence of the surface anisotropy on both steering and transient mobility
effects is revealed by our simulations for the simple isolated-atom case and in
the submonolayer-growth regime. For the latter case, we illustrate how steering
and transient mobility affect the film morphology at the nanoscale.Comment: 7 pages, 9 figure
EuroMarine Research Strategy Report: Deliverable 3.2. Seventh Framework Programme Project EuroMarine
Extratropical cyclone statistics during the last millennium and the 21st century
Extratropical cyclones in winter and their characteristics are investigated
in depth for the Atlantic European region, as they are responsible for a
significant part of the rainfall and extreme wind and/or
precipitation-induced hazards. The analysis is based on a seamless transient
simulation with a state-of-the-art fully coupled Earth system model from 850
to 2100 CE. The Representative Concentration Pathway 8.5 (RCP8.5) scenario is used in the 21st century. During the
Common Era, cyclone characteristics show pronounced variations on interannual
and decadal timescales, but no external forcing imprint is found prior to
1850. Thus, variations of extratropical cyclone characteristics are mainly
caused by internal variability of the coupled climate system. When
anthropogenic forcing becomes dominant in the 20th century, a decrease of the
cyclone occurrences mainly over the Mediterranean and a strong increase of
extreme cyclone-related precipitation become detectable. The latter is due to
thermodynamics as it follows the Clausius–Clapeyron relation. An important
finding, though, is that the relation between temperature and extreme
cyclone-related precipitation is not always controlled by the
Clausius–Clapeyron relation, which suggests that dynamical processes can play
an important role in generating extreme cyclone-related precipitation – for
example, in the absence of anomalously warm background conditions. Thus, the
importance of dynamical processes, even on decadal timescales, might explain
the conundrum that proxy records suggest enhanced occurrence of precipitation
extremes during rather cold periods in the past.</p
Tambora 1815 as a test case for high impact volcanic eruptions: Earth system effects
The eruption of Tambora (Indonesia) in April 1815 had substantial effects on global climate and led to the ‘Year Without a Summer’ of 1816 in Europe and North America. Although a tragic event—tens of thousands of people lost their lives—the eruption also was an ‘experiment of nature’ from which science has learned until today. The aim of this study is to summarize our current understanding of the Tambora eruption and its effects on climate as expressed in early instrumental observations, climate proxies and geological evidence, climate reconstructions, and model simulations. Progress has been made with respect to our understanding of the eruption process and estimated amount of SO2 injected into the atmosphere, although large uncertainties still exist with respect to altitude and hemispheric distribution of Tambora aerosols. With respect to climate effects, the global and Northern Hemispheric cooling are well constrained by proxies whereas there is no strong signal in Southern Hemisphere proxies. Newly recovered early instrumental information for Western Europe and parts of North America, regions with particularly strong climate effects, allow Tambora's effect on the weather systems to be addressed. Climate models respond to prescribed Tambora-like forcing with a strengthening of the wintertime stratospheric polar vortex, global cooling and a slowdown of the water cycle, weakening of the summer monsoon circulations, a strengthening of the Atlantic Meridional Overturning Circulation, and a decrease of atmospheric CO2. Combining observations, climate proxies, and model simulations for the case of Tambora, a better understanding of climate processes has emerged
Steering effect on the shape of islands for homoepitaxial growth of Cu on Cu(100)
The steering effect on the growth of islands is investigated by combining
molecular dynamics (MD) and kinetic Monte Carlo (KMC) simulations. Dynamics of
depositing atoms and kinetics of atoms on a substrate are realized by MD and
KMC, respectively. The reported experimental results on the asymmetric island
growth [van Dijken {\it et al.}, Phys. Rev. Lett. {\bf 82}, 4038 (1999).] is
well reproduced. A salient phenomenon, the reversal of the asymmetry, is found
as the island size increases, and attributed to the asymmetric flux on the
lower terrace of island.Comment: 5 figur
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