THE BALTEX BRIDGE CAMPAIGN: An Integrated Approach for a Better Understanding of Clouds

Crewell, Susanne; Bloemink, H.; Feijt, A.; García, Sebastián Gimeno; Jolivet, Dominique; Krasnov, Oleg A.; Lammeren, A. van; Löhnert, Ulrich; Meijgaard, E. van; Meywerk, J.; Quante, Markus; Pfeilsticker, K.; Schmidt, S.; Scholl, T.; Simmer, Clemens; Schröder, Marc; Trautmann, Thomas; Venema, Victor; Wendisch, Manfred; Willén, Ulrika

doi:10.1175/bams-85-10-1565

Cited by 42 publications

(37 citation statements)

References 44 publications

(29 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For this intercomparison, individual model transferability experiments will be defined as simulating cloud systems of different origins, structures, and evolution within a single domain by a single model. From a comparison of the results of NWP and RCMs with measurements taken during an enhanced observational period of the BALTEX BRIDGE experiment, Crewell et al (2004) observed that there are large discrepancies among the liquid water climatologies of models, and that a clear improvement in the simulation of clouds was achieved when 40 or more levels were used to resolve the fine structure of clouds. Simulations with regional models, some with enhanced vertical resolution, will be compared against intensive observations made during the Northern Hemisphere summer.…”

Section: Futu Re De Ve Lopm E Ntsmentioning

confidence: 99%

Transferability Intercomparison: An Opportunity for New Insight on the Global Water Cycle and Energy Budget

Takle¹,

Roads²,

Rockel³

et al. 2007

Bulletin of the American Meteorological Society

View full text Add to dashboard Cite

Transferability intercomparisons provide a new approach for advancing the science of modeling the water cycle and energy budget on regional to global scales by using multiple limited-area models applied to multiple domains. The water and associated energy cycles introduce exponential, episodic, and other nonlinear processes that create difficulties for observing, simulating, and predicting climate variations. The water cycle both creates and responds to spatial heterogeneities that feed back strongly on the energy budget and circulation system. These feedback processes represent some of the largest uncertainties in our ability to simulate future scenarios of Earths climate, especially scenarios that suggest warming beyond the temperature bounds of recent interglacial conditions and hence for which we have no previous observations for comparison. Water cycle processes also occur on a wide range of spatial and temporal scales, many being far too small to either be globally observed and or simulated by global climate and weather forecast models.Transferability intercomparions represent a new approach for understanding the water cycle and energy budget on regional to global scales. This new class of intercomparisons applies multiple regional climate models to a prescribed collection of domains where enhanced observations are conducted and results are archived in a coordinated manner. The primary goals of the transferability intercomparisons are to understand the complex interactions forming the water cycle and evaluate our ability to simulate these processes. The transferability framework goes

show abstract

Section: Futu Re De Ve Lopm E Ntsmentioning

confidence: 99%

Transferability Intercomparison: An Opportunity for New Insight on the Global Water Cycle and Energy Budget

Takle¹,

Roads²,

Rockel³

et al. 2007

Bulletin of the American Meteorological Society

View full text Add to dashboard Cite

show abstract

“…There has been enormous progress in the development and refinement of ground-based remote sensing instruments for Published by Copernicus Publications on behalf of the European Geosciences Union. the determination of humidity, wind, cloud parameters and rain rate in recent years (e.g., Bösenberg and Linné, 2002;Haeffelin et al, 2005;Peters et al, 2002;Intrieri et al, 2002), and also the retrieval algorithms for characterising clouds have been much improved in recent years, not least because of international projects like BALTEX BRIDGE with its subprogramm CLIWA-NET and CLOUDNET (http: //www.cloud-net.org), and the German 4D CLOUDS project (e.g., Crewell et al, 2004;Löhnert et al, 2004). In particular the CLOUDNET project has promoted the retrievals of cloud liquid water and cloud ice water content (e.g., Tinel et al, 2005;Liu and Illingworth, 2000;Hogan et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Quality assessment of water cycle parameters in REMO by radar-lidar synergy

et al. 2008

View full text Add to dashboard Cite

Abstract.A comparison study of water cycle parameters derived from ground-based remote-sensing instruments and from the regional model REMO is presented. Observational data sets were collected during three measuring campaigns in summer/autumn 2003 and 2004 at Richard Aßmann Observatory, Lindenberg, Germany. The remote sensing instruments which were used are differential absorption lidar, Doppler lidar, ceilometer, cloud radar, and micro rain radar for the derivation of humidity profiles, ABL height, water vapour flux profiles, cloud parameters, and rain rate. Additionally, surface latent and sensible heat flux and soil moisture were measured. Error ranges and representativity of the data are discussed. For comparisons the regional model REMO was run for all measuring periods with a horizontal resolution of 18 km and 33 vertical levels. Parameter output was every hour. The measured data were transformed to the vertical model grid and averaged in time in order to better match with gridbox model values. The comparisons show that the atmospheric boundary layer is not adequately simulated, on most days it is too shallow and too moist. This is found to be caused by a wrong partitioning of energy at the surface, particularly a too large latent heat flux. The reason is obviously an overestimation of soil moisture during drying periods by the one-layer scheme in the model. The profiles of water vapour transport within the ABL appear to be realistically simulated. The comparison of cloud cover reveals an underestimation of low-level and mid-level clouds by the model, whereas the comparison of high-level clouds is hampered by the inability of the cloud radar to see cirrus clouds above 10 km. Simulated ABL clouds apparently have a too low cloud base, and the vertical extent is underCorrespondence to: B. Hennemuth (hennemuth@dkrz.de) estimated. The ice water content of clouds agree in model and observation whereas the liquid water content is unsufficiently derived from cloud radar reflectivity in the present study. Rain rates are similar, but the representativeness of both observations and grid box values is low.

show abstract

“…Because microwave radiometry is the most accurate way to measure liquid water path, more than 10 different microwave radiometers from European universities and research organizations operated successfully during three enhanced observation phases-all part of BRIDGE, the major field experiment of BALTEX. Most importantly, the BALTEX BRIDGE Campaign (BBC; Crewell et al 2004) included multiple aircraft observations and a microwave intercomparison campaign that served as a baseline to develop an operational microwave radiometer for LWP and thermodynamic profiles (HATPRO; Rose et al 2005). Methodologies focusing on the evaluation of model-predicted cloud parameters with CLIWA-NET inferred observations were developed and examined in various applications, for example, a statistical evaluation Origin of pollution 1/3 of regional particulate matter concentrations are due to local emissions, while 2/3 originate from continental transport.…”

Section: Westbrook Andmentioning

confidence: 99%

Parallel Developments and Formal Collaboration between European Atmospheric Profiling Observatories and the U.S. ARM Research Program

Haeffelin

Crewell

Illingworth

et al. 2016

Meteorological Monographs

Self Cite

View full text Add to dashboard Cite

THE BALTEX BRIDGE CAMPAIGN: An Integrated Approach for a Better Understanding of Clouds

Cited by 42 publications

References 44 publications

Transferability Intercomparison: An Opportunity for New Insight on the Global Water Cycle and Energy Budget

Transferability Intercomparison: An Opportunity for New Insight on the Global Water Cycle and Energy Budget

Quality assessment of water cycle parameters in REMO by radar-lidar synergy

Parallel Developments and Formal Collaboration between European Atmospheric Profiling Observatories and the U.S. ARM Research Program

Contact Info

Product

Resources

About