1 / 13

WCRP Workshop on Determination of Solid Precipitation in Cold Climate Regions

WCRP Workshop on Determination of Solid Precipitation in Cold Climate Regions. Fairbanks, Alaska June 9-14, 2002. Organized by: WCRP CliC and GEWEX Projects Host: University of Alaska Fairbanks (UAF) Sponsors : WCRP and GCOS Meteorological Service of Canada

brennan-lopez
Download Presentation

WCRP Workshop on Determination of Solid Precipitation in Cold Climate Regions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. WCRP Workshop on Determination of Solid Precipitation in Cold Climate Regions Fairbanks, Alaska June 9-14, 2002

  2. Organized by: WCRP CliC and GEWEX Projects Host: University of Alaska Fairbanks (UAF) Sponsors: WCRP and GCOS Meteorological Service of Canada NOAA Arctic Research Office NOAA/NASA GEWEX Americas Prediction Project UAF International Arctic Research Centre UAF Water and Environmental Research Centre

  3. Participation: • Over 50 invited participants from 13 countries. • Representation from the major cold regions of the world including North and South America, Scandinavia, Eurasia, China and the Arctic and Antarctic. • Experts on cold climate precipitation; in-situ measurement and remote sensing; development of precipitation adjustment techniques and implementation on regional and global scales; major field programs; global data archives and modeling. • Over 50 paper and poster presentations.

  4. Workshop Objectives: • to review the current status of measuring or determining precipitation, especially solid precipitation, in cold climate regions • to identify gaps and issues • to recommend actions that will allow us to determine precipitation over a range of time and space scales for climatological and hydrological analyses, regional water budgets, validation and process experiments and models

  5. WG1: Precipitation Measurement • Conventional measurement methods • Alternative strategies • New technologies

  6. WG1: Precipitation Measurement Issues: • impact of automation on precipitation measurement and related QA/QC challenges; • continuing need for conventional point precipitation measurements against declining networks in many countries; • accessibility of up-to-date meta data; • need to blend (fuse or combine) data from different sources (in-situ, model, satellite); • need to maintain reasonable expectations on what satellite and radar technologies are able to provide; and • need for further intensive field efforts to address scaling.

  7. WG1: Precipitation Measurement Suggested actions: • establish a WCRP working group to develop guidelines on the minimum station density required for climate research studies on solid precipitation in cold climate regions; • conduct urgently needed research to determine how to obtain climate quality data from automated weather observing systems--need to define and attribute “climate”-quality to operational weather observing systems/sites; • encourage national research agencies to establish programs to provide support for the development of new instruments to measure solid precipitation in high latitude region; and • identify and establish intercomparison sites for standardized testing of new technology, such as radar, hot plate, pressure, or blowing snow

  8. WG2: Measurement Errors and Adjustment Procedures Issues: • is there a need for intercomparison of adjustment procedures; • how can we quantify and/or represent the error in the adjusted measurements and monitor the improvements made by making these adjustments; • what are the errors in gridding and creating gridded products; what must be done to the existing and planned national networks and archives to provide consistent adjustments to facilitate comparisons among national, regional and global climatologies; and • what is the practicality of adjustments related to time scale, space scale and metadata requirements.

  9. WG2: Measurement Errors and Adjustment Procedures Findings: • there is real value in reporting adjusted precipitation and there is a continuing need for ongoing intercomparisons; • correction factors are compromised by limited data sets and there are regional/climatic differences in adjustment factors; • the application of real time / dynamic adjustments should be done with caution—we must first determine the limitations; • we need to adapt to changing user needs; and • good meta data and station histories are not only important, but essential.

  10. WG3: Global Precipitation Data Sets Questions: • what are the principal user requirements for a global precipitation data set; • what are the limitations in the current global precipitation data sets; • what improvements could/should be made in these global precipitation data sets; • what new measurement techniques (e.g. GPM) could provide data for these global data sets; • what research and development is needed to prepare for these new measurement and data systems; • what are the limitations in merging satellite and in-situ products and how are these limitations overcome; and • is there a role for a data-model mix in producing global precipitation data products?

  11. WG3: Global Precipitation Data Sets Research needs: • Improve the use of wind information to enhance adjustments of snow both at a point and over a region; • optimizing the blend of moisture flux convergence and gauge measurements in data sparse areas (e.g. Greenland); • determining how to incorporate non-standard data (e.g. ice cores) into precipitation climatologies; • development of models for downscaling to topography, blending strategies for data assimilation (e.g. define error characteristics), and interpolation to determine large scale precipitation patterns in the absence of data; • estimation of snowfall and snow pack in mountainous regions; and • techniques to distinguish between solid and liquid precipitation.

  12. WG3: Global Precipitation Data Sets Recommendations: • provide enthusiastic support to GPM by developing regional baseline data streams for algorithm development; • develop a strategy for exploiting new technologies in the development of algorithms and models for third and fourth generation precipitation climatologies; • use daily precipitation as a building block for precipitation climatologies; • develop a system for a critical mass of snow accumulation stations in Antarctica to provide accumulations with a one-month data latency; • obtain comprehensive meta data on gauge placement; • ensure full data rescue and digitization of “at risk” cold season data sets; and • ensure CliC and GEWEX address the priority research needs (listed above) for developing global precipitation data sets.

  13. Gaps and common issues: • precipitation measurement in mountainous regions; • measurement of low intensity solid precipitation events; • measurement /estimation of precipitation in Antarctica; • solid precipitation over sea ice and ice covered Arctic Ocean; • how to quantify the errors associated with adjustment procedures and determine the limitations on time and space scales for adjustments; • gridding—what analysis method to be used and sampling error depend on amount of data; • GPCC—some countries have not provided data since gridded products distributed free; • GPCC—sampling errors have to be addressed by CliC, also how to proceed and methods that can be implemented; and • how to improve the linkage to the GCM community and determining modeling needs.

More Related