The STARTWAVE atmospheric water database

The STARTWAVE (STudies in Atmospheric Radiative Transfer and Water Vapour Effects) project aims to investigate the role which water vapour plays in the climate system, and in particular its interaction with radiation. Within this framework, an ongoing water vapour database project was set up which comprises integrated water vapour (IWV) measurements made over the last ten years by ground-based microwave radiometers, Global Positioning System (GPS) receivers and sun photometers located throughout Switzerland at altitudes between 330 and 3584 m. At Bern (46.95° N, 7.44° E) tropospheric and stratospheric water vapour profiles are obtained on a regular basis and integrated liquid water, which is important for cloud characterisation, is also measured. Additional stratospheric water vapour profiles are obtained by an airborne microwave radiometer which observes large parts of the northern hemisphere during yearly flight campaigns. The database allows us to validate the various water vapour measurement techniques. Comparisons between IWV measured by the Payerne radiosonde with that measured at Bern by two microwave radiometers, GPS and sun photometer showed instrument biases within ±0.5 mm. The bias in GPS relative to sun photometer over the 2001 to 2004 period was –0.8 mm at Payerne (46.81° N, 6.94° E, 490 m), which lies in the Swiss plains north of the Alps, and +0.6 mm at Davos (46.81° N, 9.84° E, 1598 m), which is located within the Alps in the eastern part of Switzerland. At Locarno (46.18° N, 8.78° E, 366 m), which is located on the south side of the Alps, the bias is +1.9 mm. The sun photometer at Locarno was found to have a bias of –2.2 mm (13% of the mean annual IWV) relative to the data from the closest radiosonde station at Milano. This result led to a yearly rotation of the sun photometer instruments between low and high altitude stations to improve the calibrations. In order to demonstrate the capabilites of the database for studying water vapour variations, we investigated a front which crossed Switzerland between 18 November 2004 and 19 November 2004. During the frontal passage, the GPS and microwave radiometers at Bern and Payerne showed an increase in IWV of between 7 and 9 mm. The GPS IWV measurements were corrected to a standard height of 500 m, using an empirically derived exponential relationship between IWV and altitude. A qualitative comparison was made between plots of the IWV distribution measured by the GPS and the 6.2 µm water vapour channel on the Meteosat Second Generation (MSG) satellite. Both showed that the moist air moved in from a northerly direction, although the MSG showed an increase in water vapour several hours before increases in IWV were detected by GPS or microwave radiometer. This is probably due to the fact that the satellite instrument is sensitive to an atmospheric layer at around 320 hPa, which makes a contribution of one percent or less to the IWV.

[1]  A. Robock,et al.  Analysis of seasonal cycles in climatic trends with application to satellite observations of sea ice extent , 2002 .

[2]  Susanne Crewell,et al.  Comparison of model predicted liquid water path with ground-based measurements during CLIWA-NET , 2005 .

[3]  Dean Lauritsen,et al.  Performance of operational radiosonde humidity sensors in direct comparison with a chilled mirror dew‐point hygrometer and its climate implication , 2003 .

[4]  Patrizia Basili,et al.  Atmospheric water vapor retrieval by means of both a GPS network and a microwave radiometer during an experimental campaign in Cagliari, Italy, in 1999 , 2001, IEEE Trans. Geosci. Remote. Sens..

[5]  Jan M. Johansson,et al.  Three months of continuous monitoring of atmospheric water vapor with a network of Global Positioning System receivers , 1998 .

[6]  Stefan C. Müller,et al.  An airborne radiometer for stratospheric water vapor measurements at 183 GHz , 2005, IEEE Transactions on Geoscience and Remote Sensing.

[7]  N. Kämpfer,et al.  A 10‐year integrated atmospheric water vapor record using precision filter radiometers at two high‐alpine sites , 2005 .

[8]  M. Liniger,et al.  Comparison of GPS and ERA40 IWV in the Alpine region, including correction of GPS observations at Jungfraujoch (3584 m) , 2006 .

[9]  Guergana Guerova,et al.  Validation of NWP Mesoscale Models with Swiss GPS Network AGNES , 2003 .

[10]  Gerd K. Hartmann,et al.  The Millimeter Wave Atmospheric Sounder (MAS): a shuttle-based remote sensing experiment , 1992 .

[11]  T. Eck,et al.  Sun photometric measurements of atmospheric water vapor column abundance in the 940‐nm band , 1997 .

[12]  Christian Mätzler,et al.  Ground-based observations of atmospheric radiation at 5, 10, 21, 35, and 94 GHz , 1992 .

[13]  William L. Smith,et al.  IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION , 2000 .

[14]  T. Herring,et al.  GPS Meteorology: Remote Sensing of Atmospheric Water Vapor Using the Global Positioning System , 1992 .

[15]  N. Kämpfer,et al.  Radiometric determination of water vapor and liquid water and its validation with other techniques , 1992 .

[16]  Gunnar Elgered,et al.  Climate monitoring using GPS , 2002 .

[17]  E. Brockmann,et al.  An Integrated Assessment of Measured and Modeled Integrated Water Vapor in Switzerland for the Period 2001–03 , 2005 .

[18]  Gerd Gendt,et al.  On the determination of atmospheric water vapor from GPS measurements , 2003 .

[19]  A. Smirnov,et al.  AERONET-a federated instrument network and data archive for aerosol Characterization , 1998 .

[20]  Impact of Radiometric Water Vapor Measurements on Troposphere and Height Estimates by GPS , 2004 .

[21]  J. Houghton,et al.  Climate change 2001 : the scientific basis , 2001 .

[22]  Beat Schmid,et al.  Modeled and empirical approaches for retrieving columnar water vapor from solar transmittance measurements in the 0.72, 0.82, and 0.94 μm absorption bands , 2000 .

[23]  Holger Vömel,et al.  Middle Atmospheric Water Vapour Radiometer (MIAWARA): Validation and first results of the LAPBIAT Upper Tropospheric Lower Stratospheric Water Vapour Validation Project (LAUTLOS-WAVVAP) campaign , 2005 .

[24]  Gerd K. Hartmann,et al.  Latitudinal survey of water vapor in the middle atmosphere using an airborne millimeter wave sensor , 1988 .

[25]  D. Ruffieux,et al.  Influence of Radiation on the Temperature Sensor Mounted on the Swiss Radiosonde , 2003 .

[26]  Lucie A. Vincent,et al.  A Technique for the Identification of Inhomogeneities in Canadian Temperature Series , 1998 .

[27]  Norman T. O'Neill,et al.  Multisensor analysis of integrated atmospheric water vapor over Canada and Alaska , 2003 .

[28]  W. Elliott,et al.  Recent Changes in NWS Upper-Air Observations with Emphasis on Changes from VIZ to Vaisala Radiosondes , 2002 .

[29]  M. Desbois,et al.  A new METEOSAT “water vapor” archive for climate studies , 2003 .

[30]  M. Janssen Atmospheric Remote Sensing by Microwave Radiometry , 1993 .

[31]  Niklaus Kämpfer,et al.  A new 22-GHz radiometer for middle atmospheric water vapor profile measurements , 2004, IEEE Transactions on Geoscience and Remote Sensing.

[32]  E. Clothiaux,et al.  Importance of Accurate Liquid Water Path for Estimation of Solar Radiation in Warm Boundary Layer Clouds: An Observational Study , 2003 .

[33]  Christian Mätzler,et al.  ASMUWARA, a ground-based radiometer system for tropospheric monitoring , 2006 .

[34]  W. Elliott,et al.  Radiosonde-Based Northern Hemisphere Tropospheric Water Vapor Trends , 2001 .

[35]  Christian Mätzler,et al.  Tropospheric water and temperature retrieval for ASMUWARA , 2006 .

[36]  S. Oltmans,et al.  The increase in stratospheric water vapor from balloonborne, frostpoint hygrometer measurements at Washington, D.C., and Boulder, Colorado , 2000 .

[37]  P. Rosenkranz Water vapor microwave continuum absorption: A comparison of measurements and models , 1998 .

[38]  D. Rind,et al.  A comparison of the Stratospheric Aerosol and Gas Experiment II tropospheric water vapor to radiosonde measurements , 1993 .

[39]  The retrieval of temperature profiles with the ground based radiometer system ASMUWARA , 2003 .

[40]  Gerd K. Hartmann,et al.  Space‐borne H2O observations in the Arctic stratosphere and mesosphere in the spring of 1992 , 1996 .

[41]  Hans J. Liebe,et al.  MPM—An atmospheric millimeter-wave propagation model , 1989 .

[42]  R. Peter,et al.  Stratospheric and mesospheric latitudinal water vapor distributions obtained by an airborne millimeter‐wave spectrometer , 1998 .

[43]  Niklaus Kämpfer,et al.  Weighted mean tropospheric temperature and transmittance determination at millimeter‐wave frequencies for ground‐based applications , 1998 .

[44]  Shepard A. Clough,et al.  The ARM program's water vapor intensive observation periods - Overview, initial accomplishments, and future challenges , 2003 .

[45]  A. J. Miller,et al.  Factors affecting the detection of trends: Statistical considerations and applications to environmental data , 1998 .