59 research outputs found
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How organized is deep convection over Germany?
Deep moist convection shows a tendency to organize into mesoscale structures. To be able to understand the potential effect of convective organization on the climate, one needs first to characterize organization. In this study, we systematically characterize the organizational state of convection over Germany based on two years of cloud-top observations derived from the Meteosat Second Generation satellite and of precipitation cores detected by the German C-band radar network. The organizational state of convection is characterized by commonly employed organization indices, which are mostly based on the object numbers, sizes and nearest-neighbour distances. According to the organization index Iorg, cloud tops and precipitation cores are found to be in an organized state for 69% and 92% of the time, respectively. There is an increase in rainfall when the number of objects and their sizes increase, independently of the organizational state. Case-studies of specific days suggest that convectively organized states correspond to either local multi-cell clusters, with less numerous, larger objects close to each other, or to scattered clusters, with more numerous, smaller organized objects spread out over the domain. For those days, simulations are performed with the large-eddy model ICON with grid spacings of 625, 312 and 156?m. Although the model underestimates rainfall and shows a too large cold cloud coverage, the organizational state is reasonably well represented without significant differences between the grid spacings
Evaluation of polarimetric ice microphysical retrievals with OLYMPEX campaign data
Polarimetric microphysical retrievals reveal a great potential for the evaluation of numerical models and data assimilation. However, the accuracy of ice microphysical retrievals is still poorly explored. To evaluate these retrievals and assess their accuracy, polarimetric radar measurements are spatially and temporally collocated with in situ aircraft measurements obtained during the OLYMPEX campaign (Olympic Mountain Experiment). Retrievals for ice water content (IWC), total number concentration Nt, and mean volume diameter Dm of ice particles are assessed by comparing an in situ dataset obtained by the University of North Dakota (UND) Citation II aircraft with X-band Doppler on Wheels (DOW) measurements. Sector-averaged range height indicator (RHI) scans are used to derive vertical profiles of microphysical retrievals. The comparison of these estimates with in situ data provides insights into strengths, weaknesses, and the accuracy of the different retrievals and quantifies the improvements in polarimetry-informed retrievals compared to conventional, non-polarimetric ones. In particular, the recently introduced hybrid ice water content retrieval exploiting reflectivity ZH, differential reflectivity ZDR, and specific differential phase KDP outperforms other retrievals based on either (ZH, ZDR) or (ZH, KDP) or non-polarimetric retrievals in terms of correlations with in situ measurements and the root mean square error.</p
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Near-realtime quantitative precipitation estimation and prediction (RealPEP)
Flash floods in small- to medium-sized catchments and intense precipitation over cities
caused by severe local storms pose increasing threats to our society. For the timely prediction of such events, the value of high-resolution and high-quality QPE and corresponding
forecasts cannot be overrated. Seamless predictions harmonizing nowcasting and numerical
weather prediction (NWP) across forecast lead times from minutes to days would greatly help
to improve the value and efficiency of warnings. Organized by the Research Unit on Near-Realtime Precipitation Estimation and Prediction (RealPEP, www2.meteo.uni-bonn.de/realpep)
and supported by the Project on Seamless Integrated Forecasting System (SINFONY, www.dwd
.de/DE/forschung/forschungsprogramme/sinfony_iafe/sinfony_node.html) of the German Meteorological Service (DWD), an international 3-day online conference was held from 5 to 7 October 2020,
dedicated to Precipitation and Flash-Flood Predictions from Minutes to Days (https://indico
.scc.kit.edu/event/883/). Most speakers agreed to have their presentations recorded, which we
uploaded to YouTube for further distribution (see, e.g., on the conference homepage, https://
indico.scc.kit.edu/event/883/page/588-recorded-talks).
The speakers were both invited experts in the respective research fields and researchers
from the RealPEP and SINFONY projects. Talks and discussions could be followed on video
stream. Interaction between the about 250 participants was enabled by entering written questions and comments via a dedicated tool, which allowed for voting and thus also ranking
questions. Registered participants could enter chat rooms from where they could be moved to
the speaker room for posing the questions directly to the speakers and the auditorium. On the
last day of the conference podium discussions with selected speakers summarized talks and
discussions and elaborated on overarching problems, ideas, and developments in the fields
of quantitative precipitation estimation (QPE), quantitative precipitation nowcasting (QPN),
quantitative precipitation forecasting (QPF), flash-flood prediction (FFP), and their organization into seamless prediction systems, which also constituted the topics of the five sessions
during the conference. We report here in particular on the outcomes of the panel discussions
Precipitation and microphysical processes observed by three polarimetric X-band radars and ground-based instrumentation during HOPE
This study presents a first analysis of precipitation and related
microphysical processes observed by three polarimetric X-band Doppler radars
(BoXPol, JuXPol and KiXPol) in conjunction with a ground-based network of
disdrometers, rain gauges and vertically pointing micro rain radars (MRRs)
during the High Definition Clouds and Precipitation for advancing Climate
Prediction (HD(CP)2) Observational Prototype Experiment (HOPE) during
April and May 2013 in Germany. While JuXPol and KiXPol were continuously
observing the central HOPE area near Forschungszentrum JĂĽlich at a close
distance, BoXPol observed the area from a distance of about 48.5 km. MRRs
were deployed in the central HOPE area and one MRR close to BoXPol in Bonn,
Germany. Seven disdrometers and three rain gauges providing point
precipitation observations were deployed at five locations within a
5 km  ×  5 km region, while three other disdrometers were
collocated with the MRR in Bonn. The daily rainfall accumulation at each
rain gauge/disdrometer location estimated from the three X-band polarimetric
radar observations showed very good agreement. Accompanying microphysical
processes during the evolution of precipitation systems were well captured
by the polarimetric X-band radars and corroborated by independent
observations from the other ground-based instruments
How uncertain are precipitation and peak flow estimates for the July 2021 flooding event?
The disastrous July 2021 flooding event made us question the ability of current hydrometeorological tools in providing timely and reliable flood forecasts for unprecedented events. This is an urgent concern since extreme events are increasing due to global warming, and existing methods are usually limited to more frequently observed events with the usual flood generation processes. For the July 2021 event, we simulated the hourly
streamflows of seven catchments located in western Germany by combining
seven partly polarimetric, radar-based quantitative precipitation estimates
(QPEs) with two hydrological models: a conceptual lumped model (GR4H) and a
physically based, 3D distributed model (ParFlowCLM). GR4H parameters were
calibrated with an emphasis on high flows using historical discharge
observations, whereas ParFlowCLM parameters were estimated based on
landscape and soil properties. The key results are as follows. (1)Â With no
correction of the vertical profiles of radar variables, radar-based QPE
products underestimated the total precipitation depth relative to rain
gauges due to intense collision–coalescence processes near the surface, i.e., below the height levels monitored by the radars. (2) Correcting the vertical profiles of radar variables led to substantial improvements. (3) The probability of exceeding the highest measured peak flow before July 2021 was highly impacted by the QPE product, and this impact depended on the catchment for both models. (4) The estimation of model parameters had a
larger impact than the choice of QPE product, but simulated peak flows of
ParFlowCLM agreed with those of GR4H for five of the seven catchments. This
study highlights the need for the correction of vertical profiles of
reflectivity and other polarimetric variables near the surface to improve
radar-based QPEs for extreme flooding events. It also underlines the large
uncertainty in peak flow estimates due to model parameter estimation.</p
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Assimilation of 3D radar reflectivities with an ensemble Kalman filter on the convective scale
An ensemble data assimilation system for 3D radar reflectivity data is introduced for the convection-permitting numerical weather prediction model of the COnsortium for Small-scale MOdelling (COSMO) based on the Kilometre-scale ENsemble Data Assimilation system (KENDA), developed by Deutscher Wetterdienst and its partners. KENDA provides a state-of-the-art ensemble data assimilation system on the convective scale for operational data assimilation and forecasting based on the Local Ensemble Transform Kalman Filter (LETKF). In this study, the Efficient Modular VOlume RADar Operator is applied for the assimilation of radar reflectivity data to improve short-term predictions of precipitation. Both deterministic and ensemble forecasts have been carried out. A case-study shows that the assimilation of 3D radar reflectivity data clearly improves precipitation location in the analysis and significantly improves forecasts for lead times up to 4 h, as quantified by the Brier Score and the Continuous Ranked Probability Score. The influence of different update rates on the noise in terms of surface pressure tendencies and on the forecast quality in general is investigated. The results suggest that, while high update rates produce better analyses, forecasts with lead times of above 1 h benefit from less frequent updates. For a period of seven consecutive days, assimilation of radar reflectivity based on the LETKF is compared to that of DWD's current operational radar assimilation scheme based on latent heat nudging (LHN). It is found that the LETKF competes with LHN, although it is still in an experimental phase
A low-cost mechanically-steered weather radar concept
Due to the Earth curvature, current operational networks of long-range weather radars are inherently unable to cover about 70% of the lower troposphere. Dense networks of inexpensive short-range units could notably improve the awareness and timely reaction to important weather events. A concept for a weather network node featuring mechanical rotation in azimuth and frequency steering in elevation is proposed, merging traditional approaches and technology advancements to fulfill present-day requirements within low-cost constraints. Achieving optimal cross-polarization drives the choice of a mechanically steered aperture. Integrated front-end chipsets support distributed power generation as close as possible to the antenna. Receiver over-elevation removes the need for a rotary joint, if sufficient processing power is available on-board
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