We are working to migrate this publications database, and the current listing does not reflect the most recent publications available. Thank you for your patience, and please reach out to library@ssec.wisc.edu with any questions.


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Results: Found 934 records (displaying records 126 through 150)

126. Delamere, J.; Clough, S. A.; Turner, D. D.; Mlawer, E. J.; Cady-Pereira, K.; Knuteson, R.; Tobin, D. C.; Revercomb, H. E. and Shephard, M.. Radiative closure studies at the North Slope of Alaska ARM Climate Research Facility. Boston, MA, American Meteorological Society, 2006, Abstract P1.9. 

127. DeSlover, D. H. and Knuteson, R. O.. AERI-derived cirrus cloud optical depth retrievals. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2001, abstract. 

128. DeSlover, D. H. and Smith, W. L.. AERI cloud optical depth retrieval from MPL-measured cloud boundaries. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 1999. Reprint # 3082. 

129. DeSlover, D. H. and Turner, D. D.. Cirrus cloud optical properties derived from AERI measurements. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2004, abstract. 

130. DeSlover, D. H.; Holz, R. E.; Turner, D.; Tobin, D.; Knuteson, R.; Revercomb, H.; Ackerman, S.; Platnick, S.; Wind, G.; King, M. D. and McGill, M.. High spectral resolution infrared closure study applied to TC4 cloud property retrievals. Washington, DC, American Geophysical Union, 2007, Abstract A13C-1366. 

131. DeSlover, D. H.; Knuteson, R. O.; Turner, D. D.; Whiteman, D. N. and Smith, W. L.. AERI and Raman lidar cirrus cloud optical depth retrieval to validate aircraft-based cirrus measurements. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2002, abstract. 

132. DeSlover, D. H.; Piironen, P. K.; Eloranta, E. W. and Smith, W. L.. High spectral resolution remote sensing of cirrus cloud visible to infrared spectral optical depth ration. Volume: 1997, Washington, DC, Optical Society of America, 1997, pp.161-163. Reprint # 3260. 

133. DeSlover, D. H.; Tobin, D. C.; Knuteson, R. O. and Revercomb, H.. Detecting climate signatures with high spectral resolution infrared satellite measurements. Darmstadt, Germany, European Organization for the Exploitation of Meteorological Satellites (EUMETSAT), 2014, abstract. 

134. Deslover, D. H.; Tobin, D.; Knuteson, R. O. and Revercomb, H. E.. Detecting climate signatures with high spectral resolution infrared satellite measurements. Washington, DC, American Geophysical Union, 2013, Abstract A51E-0089. 

135. DeSlover, D. H.; Turner, D. D. and Knuteson, R. O.. AERI-measured cirrus cloud optical depth and particle size. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2003, abstract. 

136. DeSlover, Daniel H.. Analysis of visible and infrared cirrus cloud optical properties using high spectral resolution remote sensing. Madison, WI, University of Wisconsin-Madison, Department of Atmospheric and Oceanic Sciences, 1996. Call Number: UW MET Publication No.96.08.D1. 

137. DeSlover, Daniel H.; Eloranta, Edwin W. and Smith, William L.. Determination of cirrus cloud optical depths using University of Wisconsin's high spectral resolution lidar and Atmospheric Emitted Radiance Interferometer. Milwaukee, WI, Wisconsin Space Grant Consortium, 1994, unpaged. unpaged. Reprint # 3348. 

138. DeSlover, Daniel H.; Eloranta, Edwin W. and Smith, William L.. Ground- and aircraft-based high spectral resolution remote sensing of cirrus cloud optical properties. Boston, MA, American Meteorological Society, 1998, pp.82-85. Reprint # 2615. 

139. DeSlover, Daniel H.; Eloranta, Edwin W. and Smith, William L.. Observation of cirrus cloud optical properties using University of Wisconsin's high spectral resolution lidar and Atmospheric Emitted Radiance Interferometer. Milwaukee, WI, Wisconsin Space Grant Consortium, 1995, unpaged. unpaged. Reprint # 3406. 

140. DeSlover, Daniel H.; Knuteson, R.; Tobin, D. C. and Revercomb, H.. Monitoring climate signatures with high spectral resolution infrared satellite measurements. Boston, MA, American Meteorological Society, 2015, Abstract 54. 

141. DeSlover, Daniel H.; Knuteson, Robert O.; Osborne, Brian; Zhou, Daniel K. and Smith, William L.. Validation of aircraft-measured land surface emissivity. Bellingham, WA, SPIE-The International Society for Optical Engineering, 2003, pp.384-391. Reprint # 3475. 

142. DeSlover, Daniel H.; Nasiri, Shaima; Knuteson, Robert O. and Revercomb, Hank E.. Measurement of cirrus cloud optical properties from ground- and aircraft-based high spectral resolution interferometry. Bellingham, WA, SPIE-The International Society for Optical Engineering, 2001, pp.1-7. Reprint # 3358. 

143. DeSlover, Daniel H.; Smith, William L.; Piironen, Paivi, K. and Eloranta, Edwin W.. A methodology for measuring cirrus cloud visible-to-infrared spectral optical depth ratiosJournal of Atmospheric and Oceanic Technology, Volume: 16, Issue: 2, 1999, pp.251-262. Reprint # 2576. 
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144. DeSlover, Daniel H.; Turner, David D. and Knuteson, Robert O.. Comparison of cirrus cloud optical properties from ground-, aircraft-, and satellite-based measurements. Bellingham, WA, SPIE-The International Society for Optical Engineering, 2003, pp.567-573. Reprint # 4682. 

145. DeSlover, Daniel H.; Turner, David D.; Whiteman, David N. and Smith, William L.. Ground- and aircraft-based cirrus cloud measurements using lidar and high spectral resolution FTS during the AFWEX 2000 field campaign. Bellingham, WA, SPIE-The International Society for Optical Engineering, 2002, pp.1-8. Reprint # 3466. 

146. DeSlover, Daniel; Holz, Robert; Turner, David and Revercomb, Henry. Aircraft S-HIS observations during MPACE. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2006, abstract. 

147. Diak, George R. and Smith, William L.. An investigation of the role of current and future remote sensing data systems in numerical meteorology. Washington, DC, National Aeronautics and Space Administration (NASA), Scientific and Technical Information Branch, 1993, pp.129-133. Reprint # 2215. 

148. Diak, George R. and Smith, William L.. An investigation of the role of current and future remote sensing data systems in numerical meteorology. Final report on NASA Contract NCC8-12. Madison, WI, University of Wisconsin-Madison, Space Science and Engineering Center, Cooperative Institute for Meteorological Satellite Studies (CIMSS), 1992. Call Number: UW SSEC Publication No.92.09.D1. 
PDF Document Link to PDF

149. Diak, George R.; Scheuer, Christopher J.; Whipple, Mark S. and Smith, William L.. Remote sensing of land-surface energy balance using data from the High-resolution Interferometer Sounder (HIS): A simulation studyRemote Sensing of Environment, Volume: 48, Issue: 1, 1994, pp.106-118. Reprint # 1568. 

150. Diak, George R.; Scheur, Christopher J.; Whipple, Mark S. and Smith, William L.. The future application of High-spectral Resolution Infrared measurements of the surface and atmosphere to the remote sensing of the land-surface energy balance. Boston, MA, American Meteorological Society, 1993, pp.108-109. Reprint # 1337. 

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