57 research outputs found
The diurnal evolution of the urban heat island of Paris: a model-based case study during Summer 2006
The urban heat island (UHI) over Paris during summer 2006 was simulated using the Advanced Regional Prediction System (ARPS) updated with a simple urban parametrization at a horizontal resolution of 1 km. Two integrations were performed, one with the urban land cover of Paris and another in which Paris was replaced by cropland. The focus is on a five-day clear-sky period, for which the UHI intensity reaches its maximum. The diurnal evolution of the UHI intensity was found to be adequately simulated for this five day period. The maximum difference at night in 2 m temperature between urban and rural areas stemming from the urban heating is reproduced with a relative error of less than 10%. The UHI has an ellipsoidal shape and stretches along the prevailing wind direction. The maximum UHI intensity of 6.1 K occurs at 23:00 UTC located 6 km downstream of the city centre and this largely remains during the whole night. An idealized one-column model study demonstrates that the nocturnal differential sensible heat flux, even though much smaller than its daytime value, is mainly responsible for the maximum UHI intensity. The reason for this nighttime maximum is that additional heat is only affecting a shallow layer of 150 m. An air uplift is explained by the synoptic east wind and a ramp upwind of the city centre, which leads to a considerable nocturnal adiabatic cooling over cropland. The idealized study demonstrates that the reduced vertical adiabatic cooling over the city compared to cropland induces an additional UHI build-up of 25%. The UHI and its vertical extent is affected by the boundary-layer stability, nocturnal low-level jet as well as radiative cooling. Therefore, improvements of representing these boundary-layer features in atmospheric models are important for UHI studies
A new regional climate model for POLAR-CORDEX : evaluation of a 30-year hindcast with COSMO-CLM2 over Antarctica
Continent-wide climate information over the Antarctic Ice Sheet (AIS) is important to obtain accurate information of present climate and reduce uncertainties of the ice sheet mass balance response and resulting global sea level rise to future climate change. In this study, the COSMO-CLM2 Regional Climate Model is applied over the AIS and adapted for the specific meteorological and climatological conditions of the region. A 30-year hindcast was performed and evaluated against observational records consisting of long-term ground-based meteorological observations, automatic weather stations, radiosoundings, satellite records, stake measurements and ice cores. Reasonable agreement regarding the surface and upper-air climate is achieved by the COSMO-CLM2 model, comparable to the performance of other state-of-the-art climate models over the AIS. Meteorological variability of the surface climate is adequately simulated, and biases in the radiation and surface mass balance are small. The presented model therefore contributes as a new member to the COordinated Regional Downscaling EXperiment project over the AIS (POLAR-CORDEX) and the CORDEX-CORE initiative
Modelling the water balance of Lake Victoria (East Africa) – Part 1: Observational analysis
Lake Victoria is the largest lake in Africa and one of the two major sources
of the Nile river. The water level of Lake Victoria is determined by its
water balance, consisting of precipitation on the lake, evaporation from the
lake, inflow from tributary rivers and lake outflow, controlled by two
hydropower dams. Due to a scarcity of in situ observations, previous estimates
of individual water balance terms are characterized by substantial
uncertainties, which means that the water balance is often not closed
independently. In this first part of a two-paper series, we present a water
balance model for Lake Victoria, using state-of-the-art remote sensing
observations, high-resolution reanalysis downscaling and outflow values
recorded at the dam. The uncalibrated computation of the individual water
balance terms yields lake level fluctuations that closely match the levels
retrieved from satellite altimetry. Precipitation is the main cause of
seasonal and interannual lake level fluctuations, and on average causes the
lake level to rise from May to July and to fall from August to December.
Finally, our results indicate that the 2004–2005 drop in lake level can be
about half attributed to a drought in the Lake Victoria Basin and about half
to an enhanced outflow, highlighting the sensitivity of the lake level to
human operations at the outflow dam.</p
An improved algorithm for polar cloud-base detection by ceilometer over the ice sheets
Optically thin ice and mixed-phase clouds play an important role in polar
regions due to their effect on cloud radiative impact and precipitation.
Cloud-base heights can be detected by ceilometers, low-power backscatter
lidars that run continuously and therefore have the potential to provide
basic cloud statistics including cloud frequency, base height and vertical
structure. The standard cloud-base detection algorithms of ceilometers are
designed to detect optically thick liquid-containing clouds, while the
detection of thin ice clouds requires an alternative approach. This paper
presents the polar threshold (PT) algorithm that was developed to be
sensitive to optically thin hydrometeor layers (minimum optical depth
Ï„ ≥ 0.01). The PT algorithm detects the first hydrometeor layer
in a vertical attenuated backscatter profile exceeding a predefined threshold
in combination with noise reduction and averaging procedures. The optimal
backscatter threshold of 3 × 10<sup>−4</sup> km<sup>−1</sup> sr<sup>−1</sup> for
cloud-base detection near the surface was derived based on a sensitivity
analysis using data from Princess Elisabeth, Antarctica and Summit,
Greenland. At higher altitudes where the average noise level is higher than
the backscatter threshold, the PT algorithm becomes signal-to-noise ratio
driven. The algorithm defines cloudy conditions as any atmospheric profile
containing a hydrometeor layer at least 90 m thick. A comparison with
relative humidity measurements from radiosondes at Summit illustrates the
algorithm's ability to significantly discriminate between clear-sky and
cloudy conditions. Analysis of the cloud statistics derived from the PT
algorithm indicates a year-round monthly mean cloud cover fraction of 72%
(±10%) at Summit without a seasonal cycle. The occurrence of
optically thick layers, indicating the presence of supercooled liquid water
droplets, shows a seasonal cycle at Summit with a monthly mean summer peak of
40 % (±4%). The monthly mean cloud occurrence frequency in summer
at Princess Elisabeth is 46% (±5%), which reduces to 12%
(±2.5%) for supercooled liquid cloud layers. Our analyses
furthermore illustrate the importance of optically thin hydrometeor layers
located near the surface for both sites, with 87% of all detections below
500 m for Summit and 80% below 2 km for Princess Elisabeth. These
results have implications for using satellite-based remotely sensed cloud
observations, like CloudSat that may be insensitive for hydrometeors near
the surface. The decrease of sensitivity with height, which is an inherent
limitation of the ceilometer, does not have a significant impact on our
results. This study highlights the potential of the PT algorithm to extract
information in polar regions from various hydrometeor layers using
measurements by the robust and relatively low-cost ceilometer instrument
Modelling the water balance of Lake Victoria (East Africa) – Part 2: Future projections
Lake Victoria, the second largest freshwater lake in the world, is one of the
major sources of the Nile river. The outlet to the Nile is controlled by two
hydropower dams of which the allowed discharge is dictated by the Agreed
Curve, an equation relating outflow to lake level. Some regional climate
models project a decrease in precipitation and an increase in evaporation
over Lake Victoria, with potential important implications for its water
balance and resulting level. Yet, little is known about the potential
consequences of climate change for the water balance of Lake Victoria. In
this second part of a two-paper series, we feed a new water balance model for
Lake Victoria presented in the first part with climate simulations available
through the COordinated Regional Climate Downscaling
Experiment (CORDEX) Africa
framework. Our results reveal that most regional climate models are not
capable of giving a realistic representation of the water balance of Lake
Victoria and therefore require bias correction. For two emission scenarios
(RCPs 4.5 and 8.5), the decrease in precipitation over the lake and an
increase in evaporation are compensated by an increase in basin precipitation
leading to more inflow. The future lake level projections show that the dam
management scenario and not the emission scenario is the main controlling
factor of the future water level evolution. Moreover, inter-model
uncertainties are larger than emission scenario uncertainties. The comparison
of four idealized future management scenarios pursuing certain policy
objectives (electricity generation, navigation reliability and environmental
conservation) uncovers that the only sustainable management scenario is
mimicking natural lake level fluctuations by regulating outflow according to
the Agreed Curve. The associated outflow encompasses, however, ranges from
14 m3 day−1 (−85 %) to 200 m3 day−1 (+100 %)
within this ensemble, highlighting that future hydropower generation and
downstream water availability may strongly change in the next decades even if
dam management adheres to he Agreed Curve. Our results overall underline that
managing the dam according to the Agreed Curve is a key prerequisite for
sustainable future lake levels, but that under this management scenario,
climate change might potentially induce profound changes in lake level and
outflow volume.</p
Possible role of anthropogenic climate change in the record-breaking 2020 Lake Victoria levels and floods
Heavy rainfall in eastern Africa between late 2019 and mid 2020 caused devastating floods and landslides throughout the region. These rains drove the levels of Lake Victoria to a record-breaking maximum in the second half of May 2020. The combination of high lake levels, consequent shoreline flooding, and flooding of tributary rivers caused hundreds of casualties and damage to housing, agriculture, and infrastructure in the riparian countries of Uganda, Kenya, and Tanzania. Media and government reports linked the heavy precipitation and floods to anthropogenic climate change, but a formal scientific attribution study has not been carried out so far. In this study, we characterize the spatial extent and impacts of the floods in the Lake Victoria basin and then investigate to what extent human-induced climate change influenced the probability and magnitude of the record-breaking lake levels and associated flooding by applying a multi-model extreme event attribution methodology. Using remote-sensing-based flood mapping tools, we find that more than 29 000 people living within a 50 km radius of the lake shorelines were affected by floods between April and July 2020. Precipitation in the basin was the highest recorded in at least 3 decades, causing lake levels to rise by 1.21 m between late 2019 and mid 2020. The flood, defined as a 6-month rise in lake levels as extreme as that observed in the lead-up to May 2020, is estimated to be a 63-year event in the current climate. Based on observations and climate model simulations, the best estimate is that the event has become more likely by a factor of 1.8 in the current climate compared to a pre-industrial climate and that in the absence of anthropogenic climate change an event with the same return period would have led lake levels to rise by 7 cm less than observed. Nonetheless, uncertainties in the attribution statement are relatively large due to large natural variability and include the possibility of no observed attributable change in the probability of the event (probability ratio, 95 % confidence interval 0.8–15.8) or in the magnitude of lake level rise during an event with the same return period (magnitude change, 95 % confidence interval 0–14 cm). In addition to anthropogenic climate change, other possible drivers of the floods and their impacts include human land and water management, the exposure and vulnerability of settlements and economic activities located in flood-prone areas, and modes of climate variability that modulate seasonal precipitation. The attribution statement could be strengthened by using a larger number of climate model simulations, as well as by quantitatively accounting for non-meteorological drivers of the flood and potential unforced modes of climate variability. By disentangling the role of anthropogenic climate change and natural variability in the high-impact 2020 floods in the Lake Victoria basin, this paper contributes to a better understanding of changing hydrometeorological extremes in eastern Africa and the African Great Lakes region.</p
Evaluation of the CloudSat surface snowfall product over Antarctica using ground-based precipitation radars
In situ observations of snowfall over the Antarctic Ice Sheet are scarce.
Currently, continent-wide assessments of snowfall are limited to information
from the Cloud Profiling Radar on board the CloudSat satellite, which has not been evaluated up to now. In this study,
snowfall derived from CloudSat is evaluated using three ground-based
vertically profiling 24 GHz precipitation radars (Micro Rain Radars: MRRs).
Firstly, using the MRR long-term measurement records, an assessment of the
uncertainty caused by the low temporal sampling rate of CloudSat (one revisit
per 2.1 to 4.5 days) is performed. The 10–90th-percentile temporal sampling
uncertainty in the snowfall climatology varies between 30 % and 40 %
depending on the latitudinal location and revisit time of CloudSat. Secondly,
an evaluation of the snowfall climatology indicates that the CloudSat
product, derived at a resolution of 1∘ latitude by 2∘
longitude, is able to accurately represent the snowfall climatology at the
three MRR sites (biases < 15 %), outperforming ERA-Interim. For coarser
and finer resolutions, the performance drops as a result of higher omission
errors by CloudSat. Moreover, the CloudSat product does not perform well in
simulating individual snowfall events. Since the difference between the MRRs
and the CloudSat climatology are limited and the temporal uncertainty is
lower than current Climate Model Intercomparison Project Phase 5 (CMIP5)
snowfall variability, our results imply that the CloudSat product is valuable
for climate model evaluation purposes.</p
Global hunger and climate change adaptation through international trade
International trade enables us to exploit regional differences in climate change impacts and is increasingly regarded as a potential adaptation mechanism. Here, we focus on hunger reduction through international trade under alternative trade scenarios for a wide range of climate futures. Under the current level of trade integration, climate change would lead to up to 55 million people who are undernourished in 2050. Without adaptation through trade, the impacts of global climate change would increase to 73 million people who are undernourished (+33%). Reduction in tariffs as well as institutional and infrastructural barriers would decrease the negative impact to 20 million (−64%) people. We assess the adaptation effect of trade and climate-induced specialization patterns. The adaptation effect is strongest for hunger-affected import-dependent regions. However, in hunger-affected export-oriented regions, partial trade integration can lead to increased exports at the expense of domestic food availability. Although trade integration is a key component of adaptation, it needs sensitive implementation to benefit all regions
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Global heat uptake by inland waters
Heat uptake is a key variable for understanding the Earth system response to greenhouse gas forcing. Despite the importance of this heat budget, heat uptake by inland waters has so far not been quantified. Here we use a unique combination of global-scale lake models, global hydrological models and Earth system models to quantify global heat uptake by natural lakes, reservoirs, and rivers. The total net heat uptake by inland waters amounts to 2.6 ± 3.2 ×1020 J over the period 1900–2020, corresponding to 3.6% of the energy stored on land. The overall uptake is dominated by natural lakes (111.7%), followed by reservoir warming (2.3%). Rivers contribute negatively (-14%) due to a decreasing water volume. The thermal energy of water stored in artificial reservoirs exceeds inland water heat uptake by a factor ∼10.4. This first quantification underlines that the heat uptake by inland waters is relatively small, but non-negligible
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