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 8662 records (displaying records 7551 through 7575)

7551. Turner, David D.. Microphysical properties of single and mixed-phase Arctic clouds derived from AERI observations. Leipzig, Germany, Institute for Tropospheric Research, 2003, pp.181-183. Reprint # 3742. 

7552. Turner, David D. and Ackerman, Steve A.. Cloud phase determination in the Arctic using AERI data. Boston, MA, American Meteorological Society, 2002, Paper JP1.11. Reprint # 3843. 

7553. Turner, David D. and Eloranta, Edwin W.. Validating mixed-phase cloud optical depth retrieved from infrared observations with high spectral resolution lidarIEEE Geoscience and Remote Sensing Letters, Volume: 5, Issue: 2, 2008, pp.285-288. Reprint # 5761. 

7554. Turner, David D.; Cadeddu, Maria P.; Lohnert, Ulrich; Crewell, Susanne and Vogelmann, Andrew M.. Modifications to the water vapor continuum in the microwave suggested by ground-based 150-GHz observationsIEEE Transactions on Geoscience and Remote Sensing, Volume: 47, Issue: 10, 2009, pp.3326-2237. Reprint # 6204. 

7555. Turner, David D.; Clough, Shepard A.; Liljegren, James C.; Clothiaux, Eugene E.; Cady-Pereira, Karen E. and Gaustad, Krista L.. Retrieving liquid water path and precipitable water vapor from the Atmospheric Radiation Measurement (ARM) microwave radiometersIEEE Transactions on Geoscience and Remote Sensing, Volume: 45, Issue: 11, 2007, pp.3680-3690. Reprint # 5624. 

7556. Turner, David D.; Ferrare, Richard A.; Heilman, Lorranie A. and Tooman, Tim P.. A two year climatology of water vapor and aerosols in the lower troposphere measured by a raman lidar. Paris, France, l'Ecole Polytechnique, 2001, pp.309-312. Reprint # 5994. 

7557. Turner, David D.; Gero, P. Jonathan and Tobin, David C.. The far-infrared: Focusing on a relatively underexplored portion of the electromagnetic spectrumBulletin of the American Meteorological Society, Volume: 93, Issue: 11, 2012. Reprint # 6917. 
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7558. Turner, David D.; Tobin, D.; Knuteson, R. O.; Revercomb, H. E.; Clough, S. A.; Mlawer, E. J.; Cady-Pereira, K. and Delamere, J.. Evaluation of ground-based infrared and microwave spectral observations and calculations using six years of ARM data. Boston, MA, American Meteorological Society, 2006, Abstract P1.11. 

7559. Turner, David D.; Whiteman, David N. and Russo, Felicita. Analysis and calibration of CRF Raman lidar cloud liquid water measurements. Final technical report for DOE Contract No.FG02-06ER64305 for the period 1 October 2006-30 September 2007. Madison, WI, University of Wisconsin-Madison, Space Science and Engineering Center (SSEC), 2007. Call Number: UW SSEC Publication No.07.10.T1. 
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7560. Turner, David; Gero, P. Jonathan P.; Hackel, Denny; Phillips, Coda; Smith, Nadia and Wagner, Tim. Networked thermodynamic boundary layer profiling with AERIs during the PECAN Field Campaign. Washington, DC, American Geophysical Union, 2015, Abstract A41F-0121. 

7561. Turner, David; Merrelli, Aronne; Cadeddu, Maria; Mlawer, Eli; Delamere, Hennifer; Tobin, David; Knuteson, Robert; Palchetti, Luca; Bianchini, Giovanni; Mlynczak, Martin; Cageao, Richard and Johnson, Dave. Evaluating the accuracy of the far-infrared spectral observations, water vapor measurements, and the radiative transfer model in extremely dry, clear-sky periods during RHUBC-II. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2011, abstract. 
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7562. Turner, David; Shupe, Matthew; DeSlover, Daniel; Mlawer, Eli and Shippert. Radiative heating rate profiles over the ACRF NSA site at Barrow. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2009, abstract. 

7563. Turner, David; Tobin, David; Mlawer, Eli and Delamere, Jennifer. The RHUBC-II Campaign: Analysis of downwelling infrared radiance. Washington, DC, US Department of Energy, Office of Energy Research, Office of Health and Environmental Research, Environmental Sciences Division, 2010, abstract. 
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7564. Tushaus, Samantha A. and Kulie, M. S.. The microwave snow scattering signature: Precipitation regime dependence. Boston, MA, American Meteorological Society, 2016, Abstract 328. 

7565. Tushaus, Samantha A.; Kulie, M. S. and Petty, G. W.. Exploring the scattering signal of GMIs 166GHz channel. Boston, MA, American Meteorological Society, 2016, Abstract 57. 

7566. Uccellini, Louis W.; Brill, Keith F.; Petersen, Ralph A.; Keyser, Daniel; Aune, Robert; Kocin, Paul J. and des Jardins, Mary. A report on the upper-level wind conditions preceding and during the Shuttle Challenger (STS 51L) explosionBulletin of the the American Meteorological Society, Volume: 67, Issue: 10, 1986, pp.1248-1265. Reprint # 5046. 
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7567. Uhlenbrock, N. L.; Bedka, K. M.; Feltz, W. F. and Ackerman, S. A.. Mountain wave signatures in MODIS 6.7 micron imagery and their relation to pilot reports of turbulenceWeather and Forecasting, Volume: 22, Issue: 3, 2007, pp.662-670. Reprint # 5370. 
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7568. Uhlenbrock, N.; Ackerman, S.; Feltz, W.; Sharman, R. and Mecikalski, J.. The use of satellite water vapor imagery and model data to diagnose and forecast turbulent mountain waves. Paris, France, Meteo France, 2005, Paper 5.30. Reprint # 5436. 

7569. Uhlenbrock, Nathan; Ackerman, Steve; Feltz, Wayne; Sharman, Bob and Mecikalski, J.. The use of MODIS water vapor imagery, NWP model analysis, and pilot reports to diagnose turbulent mountain waves. Boston, MA, American Meteorological Society, 2006, Paper P8.4. Reprint # 4840. 

7570. Uhlenbrock, Nathan; Ackerman, Steve; Feltz, Wayne; Whittaker, Tom; Shaman, Bob; Gumley, Liam and Bedka, Kristopher. The use of satellite water vapor imagery and model data to diagnose and forecast turbulent mountain waves. Boston, MA, American Meteorological Society, 2005, Paper P2.40. Reprint # 3957. 

7571. University of Wisconsin-Madison, Space Science and Engineering Center. Hurricane Hugo: 16-22 September 1989. Madison, WI, 1989. 11 minutes. Call Number: Videotape #16. 

7572. University of Wisconsin-Madison, Space Science and Engineering Center. Hurricane Andrew: Satellite and radar sequences. Madison, WI, 1992. Call Number: Videotape #50. 

7573. Uspensky, A. B.; Kukharsky, A. V.; Trotsenko, A. N.; Rublev, A. N. and Plokhenko, Yu. V.. Progress and promise for observing tropospheric gas variations with satellite advanced IR sounders. Darmstadt, Germany, European Organization for the Exploitation of Meteorological Satellites (EUMETSAT), 2005, pp.507-514. Reprint # 5100. 

7574. Uspensky, A. B.; Plokhenko, Ju.V.; Soloviev, V. I. and Kuharsky, A. V.. Generation of sounding products from TOVS data: Recent algorithm developments and application in real-time data processing. Melbourne, Australia, Bureau of Meteorology Research Centre (BMRC), 2001, pp.68. 
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7575. Uthe, Edward E. and Smith, William L.. Airborne lidar/radiometric detection and measurement of chemical agents for location of manufacturing targets. Menlo Park, CA, SRI International, 1983. Reprint # 6960.