Your search keyword '"Demoz, B"' showing total 36 results

1. A Case Study of Mid-Atlantic Nocturnal Boundary Layer Events during WAVES 2006

Author

Rabenhorst, S., Whiteman, D. N., Zhang, D.-L., and Demoz, B.

Published

2014

2. The National Weather Service Ceilometer Planetary Boundary Layer Project

Author

Hicks M., Atkinson D., Demoz B., Vermeesch K., and Delgado R.

Subjects

Physics, QC1-999

Abstract

The National Weather Service (NWS) is investigating the potential of utilizing the Automatic Surface Observing System’s (ASOS) cloud base height indicator, the Vaisala CL31 ceilometer, to profile aerosols in the atmosphere. Field test sites of stand-alone CL31 ceilometers have been established, primarily, around the Washington DC metropolitan area, with additional systems in southwest USA and Puerto Rico. The CL31 PBL project examines the CL31 data collected for data quality, mixing height retrieval applicability, and its compliment to satellite data. This paper reviews the topics of the CL31 data quality and mixing height retrieval applicability.

Published

2016

3. Wind Profiling from a New Compact, Pulsed, 2-Micron, Coherent-Detection Doppler Lidar Transceiver during Wind Measurement Intercomparison

Author

Singh, Upendra N, Koch, Grady J, Kavaya, Michael J, Yu, Jirong, Beyon, Jeffrey Y, Demoz, B, and Veneable, D

Subjects

Meteorology And Climatology

Abstract

NASA Langley Research Center has a long history of developing 2-micron laser transmitter for wind sensing. With support from NASA Laser Risk Reduction Program (LRRP) and Instrument Incubator Program (IIP), NASA Langley Research Center has developed a state-of-the-art compact lidar transceiver for a pulsed coherent Doppler lidar system for wind measurement. This lidar system was recently deployed at Howard University facility in Beltsville, Maryland, along with other wind lidar systems. Coherent Doppler wind lidar ground-based wind measurements and comparisons with other lidars and other sensors will be presented.

Published

2009

4. Water Vapor Measurements by Howard University Raman Lidar during the WAVES 2006 Campaign

Author

Adam, M, Demoz, B. B, Whiteman, D. N, Venable, D. D, Joseph E, Gambacorta, A, Wei, J, Shephard, M. W, Miloshevich, L. M, Barnet, C. D, Herman, R. L, Fitzgibbon, J, and Connell, R

Subjects

Oceanography

Abstract

Retrieval of water vapor mixing ratio using the Howard University Raman Lidar is presented with emphasis on three aspects: i) performance of the lidar against collocated radiosondes and Raman lidar, ii) investigation of the atmospheric state variables when poor agreement between lidar and radiosondes values occurred and iii) a comparison with satellite-based measurements. The measurements were acquired during the Water Vapor Validation Experiment Sondes/Satellites 2006 field campaign. Ensemble averaging of water vapor mixing ratio data from ten night-time comparisons with Vaisala RS92 radiosondes shows on average an agreement within 10 % up to approx. 8 km. A similar analysis of lidar-to-lidar data of over 700 profiles revealed an agreement to within 20 % over the first 7 km (10 % below 4 km). A grid analysis, defined in the temperature - relative humidity space, was developed to characterize the lidar - radiosonde agreement and quantitatively localizes regions of strong and weak correlations as a function of altitude, temperature or relative humidity. Three main regions of weak correlation emerge: i) regions of low relative humidity and low temperature, ii) moderate relative humidity at low temperatures and iii) low relative humidity at moderate temperatures. Comparison of Atmospheric InfraRed Sounder and Tropospheric Emission Sounder satellites retrievals of moisture with that of Howard University Raman Lidar showed a general agreement in the trend but the formers miss a lot of the details in atmospheric structure due to their low resolution. A relative difference of about 20 % is usually found between lidar and satellites measurements.

Published

2009

5. The Water Vapor Variability - Satellite/Sondes (WAVES) Field Campaigns

Author

Whiteman, D. N, Adam, M, Barnet, C, Bojkov, B, Delgado, R, Demoz, B, Fitzgibbon, J, Forno, R, Herman, R, Hoff, E, Joseph, E, Landulfo, E, McCann, K, McGee, T, Miloshevich, L, Restrepo, I, Schmidlin, F. J, Taubman, B, Thompson, A, Twigg, L, Venable, D, Vomel, H, and Walthall, C

Subjects

Earth Resources And Remote Sensing

Abstract

Three NASA-funded field campaigns have been hosted at the Howard University Research Campus in Beltsville, MD. In each of the years 2006, 2007 and 2008, WAVES field campaigns have coordinated ozonesonde launches, lidar operations and other measurements with A-train satellite overpasses for the purposes of satellite validation. The unique mix of measurement systems, physical location and the interagency, international group of researchers and students has permitted other objectives, such as mesoscale meteorological studies, to be addressed as well. We review the goals and accomplishments of the three WAVES missions with the emphasis on the nonsatellite validation component of WAVES, as the satellite validation activities have been reported elsewhere.

Published

2008

6. Analysis of Raman Lidar and Radiosonde Measurements from the AWEX-G Field Campaign and Its Relation to Aqua Validation

Author

Whiteman, D. N, Russo, F, Demoz, B, Miloshevich, L. M, Veselovskii, I, Hannon, S, Wang, Z, Vomel, H, Schmidlin, F, Lesht, B, Moore, P. J, Beebe, A. S, Gambacorta, A, and Barnet, C

Subjects

Geophysics

Abstract

Early work within the Aqua validation activity revealed there to be large differences in water vapor measurement accuracy among the various technologies in use for providing validation data. The validation measurements were made at globally distributed sites making it difficult to isolate the sources of the apparent measurement differences among the various sensors, which included both Raman lidar and radiosonde. Because of this, the AIRS Water Vapor Experiment-Ground (AWEX-G) was held in October-November 2003 with the goal of bringing validation technologies to a common site for intercomparison and resolving the measurement discrepancies. Using the University of Colorado Cryogenic Frostpoint Hygrometer (CFH) as the water vapor reference, the AWEX-G field campaign permitted correction techniques to be validated for Raman lidar, Vaisala RS80-H and RS90/92 that significantly improve the absolute accuracy of water vapor measurements from these systems particularly in the upper troposphere. Mean comparisons of radiosondes and lidar are performed demonstrating agreement between corrected sensors and the CFH to generally within 5% thereby providing data of sufficient accuracy for Aqua validation purposes. Examples of the use of the correction techniques in radiance and retrieval comparisons are provided and discussed.

Published

2006

7. Analysis of Raman Lidar and radiosonde measurements from the AWEX-G field campaign and its relation to Aqua validation

Author

Whiteman, D. N, Russo, F, Demoz, B, Miloshevich, L. M, Veselovskii, I, Hannon, S, Wang, Z, Vomel, H, Schmidlin, F, and Lesht, B

Subjects

Fluid Mechanics And Thermodynamics

Abstract

Early work within the Aqua validation activity revealed there to be large differences in water vapor measurement accuracy among the various technologies in use for providing validation data. The validation measurements were made at globally distributed sites making it difficult to isolate the sources of the apparent measurement differences among the various sensors, which included both Raman lidar and radiosonde. Because of this, the AIRS Water Vapor Experiment-Ground (AWEX-G) was held in October - November, 2003 with the goal of bringing validation technologies to a common site for intercomparison and resolution of the measurement discrepancies. Using the University of Colorado Cryogenic Frostpoint Hygrometer (CFH) as the water vapor reference, the AWEX-G field campaign resulted in new correction techniques for both Raman lidar, Vaisala RS80-H and RS90/92 measurements that significantly improve the absolute accuracy of those measurement systems particularly in the upper troposphere. Mean comparisons of radiosondes and lidar are performed demonstrating agreement between corrected sensors and the CFH to generally within 5% thereby providing data of sufficient accuracy for Aqua validation purposes. Examples of the use of the correction techniques in radiance and retrieval comparisons are provided and discussed.

Published

2005

8. Raman Lidar Measurements during the International HZO Project

Author

Whiteman, D. N, Demoz, B, DiGirolamo, P, Comer, J, Veselovskii, I, Evans, K, Wang, Z, Cadirola, M, Rush, K, Schwemmer, G, and Gentry, B

Subjects

Astronautics (General)

Abstract

The amount of water vapor in the atmosphere helps to determine the likelihood that severe storms may develop. The concentration of water vapor, though, is highly variable in space and time. And yet small changes in water vapor concentration over a short period of time or over a short spatial distance can determine whether a storm may or may not develop. Therefore, in order to improve the ability to forecast severe weather such as thunderstorms it is important to measure water vapor in the atmosphere with high spatial and temporal resolution. One of the most attractive research tools for measuring water vapor in the atmosphere with high spatial and temporal resolution is a Raman lidar. A Raman lidar consists of a laser transmitter, a telescope receiver and optics and electronics for processing opticand electronic signals. A laser pulse is emitted into the atmosphere and it interacts with molecules in the atmosphere causing them to become excited and to emit, through the Raman process, photons of different wavelength than emitted by the laser. The molecule that emitted these emitted. This is the way that a Raman lidar identifies water vapor molecules in the atmosphere. can be identified based on the wavelength of the photons One of the great challenges in Raman lidar measurements has been to make useful daytime measurements of the water vapor profile under bright daytime conditions. In this first of two papers, we describe the instrumentation and analysis of the first documented Raman lidar that is able to measure water vapor in the daytime with sufficient quality to permit the study of developing storm systems.

Published

2005

9. Subtropical Cirrus Properties Derived from GSFC Scanning Raman Lidar Measurements during CAMEX 3

Author

Whiteman, D. N, Wang, Z, and Demoz, B

Subjects

Meteorology And Climatology

Abstract

The NASA/GSFC Scanning Raman Lidar (SRL) was stationed on Andros Island, Bahamas for the third Convection and Moisture Experiment (CAMEX 3) held in August - September, 1998 and acquired an extensive set of water vapor and cirrus cloud measurements (Whiteman et al., 2001). The cirrus data studied here have been segmented by generating mechanism. Distinct differences in the optical properties of the clouds are found when the cirrus are hurricane-induced versus thunderstom-induced. Relationships of cirrus cloud optical depth, mean cloud temperature, and layer mean extinction-to-backscatter ratio (S) are presented and compared with mid-latitude and tropical results. Hurricane-induced cirrus clouds are found to generally possess lower values of S than thunderstorm induced clouds. Comparison of these measurements of S are made with other studies revealing at times large differences in the measurements. Given that S is a required parameter for spacebased retrievals of cloud optical depth using backscatter lidar, these large diffaences in S measurements present difficulties for space-based retrievals of cirrus cloud extinction and optical depth.

Published

2004

10. Moisture, Wind, and Boundary Layer Evolution During a Dryline in IHOP-2002: May 22, 2002

Author

Demoz, B, Miller, D, Evans, K, Whiteman, D, DiGirolamo, P, Schwemmer, G, Gentry, B, Starr, D, and Wang, Z

Subjects

Meteorology And Climatology

Abstract

As part of the International H2O Project (MOP-2002), three NASNGSFC lidars acquired high-resolution clear air data of wind, CBL evolution, and water vapor mixing ratio profiles during a dryline event that occurred on 22 May 2002. Together with the anciliary suite of instruments deployed in MOP-2002, these lidar data sets offer a unique look into the mesoscale evolution and convective scale dynamics in and around a dryline.

Published

2003

11. Preliminary Analysis and Simulations of July 23rd Extended Anvil Case

Author

Lin, R.-F, Demoz, B, McGill, M, Heymsfield, G, Sassen, K, Bui, P, Heymsfield, A, Halverson, J, Rickenbach, T, Poellot, M, and Lare, A

Subjects

Meteorology And Climatology

Abstract

A key focus of CRYSTAL-FACE (Cirrus Regional Study of Tropical Anvils and cirrus Layers - Florida Area Cirrus Experiment) was the generation and subsequent evolution of cirrus outflow from deep convective cloud systems. A preliminary integrated look at the observations of an extended cirrus anvil cloud system observed on 23 July 2002 will be presented, including lidar and millimeter radar observations from NASA's ER-2 and in- situ observations from NASA's WB-57 and University of North Dakota Citation. The observations will be compared to preliminary results of simulations using 1-D and 2-D high-resolution (100 meter) cloud resolving models. The CRMs explicitly account for cirrus microphysical development by resolving the evolving ice crystal size distribution (bin model) in time and space. Both homogeneous and heterogeneous nucleation are allowed in the model. The CRM simulations are driven using the output of regional simulations using MM5 that produces deep convection similar to what was observed. The MM5 model employs a 2 km inner grid (32 layers) over a 360 km domain, nested within a 6 km grid over a 600 km domain. Initial and boundary conditions for the 36- hour MM5 simulation are taken from NCEP Eta model analysis at 32 km resolution. Key issues to be explored are the settling of the observed anvil versus the model simulations, and comparisons of dynamical properties, such as vertical motions, occurring in the observations and models. The former provides an integrated measure of the validity of the model microphysics (fallspeed) while the latter is the key factor in forcing continued ice generation.

Published

2003

12. NASA/GSFC Scanning Raman Lidar Measurements of Water Vapor and Cirrus Clouds during WVIOP2000 and AFWEX

Author

Whiteman, D. N, Evans, K. D, DiGirolamo, P, Demoz, B. B, Turner, D, Comstock, J, Ismail, S, Ferrare, R. A, Browell, E. V, Goldsmith, J. E. M, and Abshire, James B

Subjects

Geophysics

Abstract

The NASA/GSFC Scanning Raman Lidar (SRL) was deployed to the Southern Great Plains CART site from September - December, 2000 and participated in two field campaigns devoted to comparisons of various water vapor measurement technologies and calibrations. These campaigns were the Water Vapor Intensive Operations Period 2000 (WVIOP2000) and the ARM FIRE Water Vapor Experiment (AFWEX). WVIOP2000 was devoted to validating water vapor measurements in the lower atmosphere while AFWEX had similar goals but for measurements in the upper troposphere. The SRL was significantly upgraded both optically and electronically prior to these field campaigns. These upgrades enabled the SRL to demonstrate the highest resolution lidar measurements of water vapor ever acquired during the nighttime and the highest S/N Raman lidar measurements of water vapor in the daytime; more than a factor of 2 increase in S/N versus the DOE CARL Raman Lidar. Examples of these new measurement capabilities along with comparisons of SRL and CARL, LASE, MPI-DIAL, in-situ sensors, radiosonde, and others will be presented. The profile comparisons of the SRL and CARL have revealed what appears to be an overlap correction or countrate correction problem in CARL. This may be involved in an overall dry bias in the precipitable water calibration of CARL with respect to the MWR of approx. 4%. Preliminary analysis indicates that the application of a temperature dependent correction to the narrowband Raman lidar measurements of water vapor improves the lidar/Vaisala radiosonde comparisons of upper tropospheric water vapor. Other results including the comparison of the first-ever simultaneous measurements from four water vapor lidar systems, a bore-wave event captured at high resolution by the SRL and cirrus cloud optical depth studies using the SRL and CARL will be presented at the meeting.

Published

2002

13. Water Measurements using a Raman Lidar

Author

Whiteman, D. N, Demoz, B, Wang, Z, Veselovskii, I, Evans, K, and DiGirolamo, P

Subjects

Meteorology And Climatology

Abstract

The research record for the usefulness of Raman Lidar in addressing a broad range of important atmospheric research topics is well established. Raman lidar technology has been used to measure tropospheric aerosols, stratospheric aerosols and cirrus clouds. Arguably the most important measurements offered by Raman lidar for both dynamic and radiative studies, however, is that of water vapor. We will describe large improvements in Raman lidar measurements of water vapor made possible through recent technology upgrades. Furthermore, we will present the use of Raman lidar to study liquid water in the atmosphere and describe current research into the use of Raman lidar measurements to estimate ice water content of cirrus clouds.

Published

2002

14. Advances in Raman Lidar Measurements of Water Vapor

Author

Whiteman, D. N, Evans, K, Demoz, B, DiGirolamo, P, Mielke, B, Stein, B, Goldsmith, J. E. M, Tooman, T, Turner, D, and Starr, David OC

Subjects

Meteorology And Climatology

Abstract

Recent technology upgrades to the NASA/GSFC Scanning Raman Lidar have permitted significant improvements in the daytime and nighttime measurement of water vapor using Raman lidar. Numerical simulation has been used to study the temperature sensitivity of the narrow spectral band measurements presented here.

Published

2002

15. Scanning Raman Lidar Measurements During the WVIOP2000 and AFWEX Field Experiments

Author

Whiteman, David N, Evans, K. D, Berkoff, T. B, Demoz, B. D, DiGirolamo, P, and Smith, David E

Subjects

Meteorology And Climatology

Abstract

The NASA/Goddard Space Flight Center Scanning Raman Lidar (SRL) participated in the Water Vapor IOP 2000 (WVIOP2000) and ARM FIRE Water Vapor Experiment (AFWEX) at the DOE SGP CART site in northern Oklahoma. These experiments occurred during the period of September and December, 2000. The goals of both the WVIOP2000 and AFWEX were to better characterize the water vapor measurement capability of numerous sensors in the lower atmosphere and upper troposphere, respectively. The SRL received several hardware upgrades in anticipation of these experiments that permitted improved measurements of water vapor during the daytime and in the upper troposphere (UT). The daytime SRL water vapor error statistics were demonstrated a factor of 2-3 improvement compared to the permanently stationed CART Raman lidar (CARL). The performance of the SRL in the UT showed improvements as well. The technological upgrades that permitted these improved SRL measurements could also be implemented in the CARL system. Data examples demonstrating the new daytime and upper tropospheric measurement capability of the SRL will be shown at the meeting. In addition, preliminary analysis will be presented on several topics: 1) inter comparison of the water vapor measurements for several water vapor sensors including SRL, CARL, the NASA/Langley Lidar Atmospheric Sensing Experiment (LASE) flown onboard the NASA DC-8, in-situ sensors flown on the DC-8, and the Max Planck Institute Differential Absorption Lidar 2) comparison of cirrus cloud measurements using SRL and CARL and 3) case studies of meteorological events that occurred during the IOPs such as a cold frontal passage on the night of September 23.

Published

2001

16. Raman Lidar Measurements of Water Vapor and Cirrus Clouds During The Passage of Hurricane Bonnie

Author

Whiteman, D. N, Evans, K. D, Demoz, B, Starr, D OC, Eloranta, E. W, Tobin, D, Feltz, W, Jedlovec, G. J, Gutman, S. I, Schwemmer, G. K, and Smith, David E

Subjects

Meteorology And Climatology

Abstract

The NASA/GSFC Scanning Raman Lidar (SRL) was stationed on Andros Island in the Bahamas during August - September, 1998 as a part of the third Convection and Moisture Experiment (CAMEX-3) which focussed on hurricane development and tracking. During the period August 21 - 24, hurricane Bonnie passed near Andros Island and influenced the water vapor and cirrus cloud measurements acquired by the SRL. Two drying signatures related to the hurricane were recorded by the SRL and other sensors. Cirrus cloud optical depths (at 351 nm) were also measured during this period. Optical depth values ranged from less than 0.01 to 1.5. The influence of multiple scattering on these optical depth measurements was studied. A correction technique is presented which minimizes the influences of multiple scattering and derives information about cirrus cloud optical and physical properties. The UV/IR cirrus cloud optical depth ratio was estimated based on a comparison of lidar and GOES measurements. Simple radiative transfer model calculations compared with GOES satellite brightness temperatures indicate that satellite radiances are significantly affected by the presence of cirrus clouds if IR optical depths are approximately 0.005 or greater. Using the ISCCP detection threshold for cirrus clouds on the GOES data presented here, a high bias of up to 40% in the GOES precipitable water retrieval was found.

Published

2000

17. Towards quantifying mesoscale flows in the troposphere using Raman lidar and Sondes

Author

Demoz, B, Starr, D, Evans, K, Whiteman, D, Melfi, S, Turner, D, Ferrare, R, Goldsmith, J, Schwemmer, G, and Cadirola, M

Subjects

Geophysics

Abstract

Water vapor plays an important role in the energetics of the boundary layer processes which in turn play a key role in regulating regional and global climate. It plays a primary role in Earth's hydrological cycle, in radiation balance as a direct absorber of infrared radiation, and in atmospheric circulation as a latent heat energy source, as well as in determining cloud development and atmospheric stability. Water vapor concentration, expressed as a mass mixing ratio (g kg(exp -l)), is conserved in all meteorological processes except condensation and evaporation. This property makes it an ideal choice for studying many of the atmosphere's dynamic features. Raman scattering measurements from lidar also allow retrieval of water vapor mixing ratio profiles at high temporal and vertical resolution. Raman lidars sense water vapor to altitudes not achievable with towers and surface systems, sample the atmosphere at much higher temporal resolution than radiosondes or satellites, and do not require strong vertical gradients or turbulent fluctuations in temperature that is required by acoustic sounders and radars. Analysis of highly-resolved water vapor profiles are used here to characterize two important mesoscale flows: thunderstorm outflows and a cold front passage. The data were obtained at the Atmospheric Radiation Measurement Site (CART) by the groundbased Department of Energy/Sandia National Laboratories lidar (CART Raman lidar or CARL) and Goddard Space Flight Center Scanning Raman Lidar (SRL). A detailed discussion of the SRL and CARL performance during the IOPs is given by others in this meeting.

Published

1998

18. GCOS reference upper air network (GRUAN) : Steps towards assuring future climate records

Author

Thorne, P. W., Vömel, H., Bodeker, G., Sommer, M., Apituley, A., Berger, F., Bojinski, S., Braathen, G., Calpini, B., Demoz, B., Diamond, H. J., Dykema, J., Fassò, A., Fujiwara, M., Gardiner, T., Hurst, D., Leblanc, T., Madonna, F., Merlone, A., Mikalsen, A., Miller, C. D., Reale, T., Rannat, K., Richter, C., Seidel, D. J., Shiotani, M., Sisterson, D., Tan, D. G. H., Vose, R. S., Voyles, J., Wang, J., Whiteman, D. N., Williams, S., Thorne, P. W., Vömel, H., Bodeker, G., Sommer, M., Apituley, A., Berger, F., Bojinski, S., Braathen, G., Calpini, B., Demoz, B., Diamond, H. J., Dykema, J., Fassò, A., Fujiwara, M., Gardiner, T., Hurst, D., Leblanc, T., Madonna, F., Merlone, A., Mikalsen, A., Miller, C. D., Reale, T., Rannat, K., Richter, C., Seidel, D. J., Shiotani, M., Sisterson, D., Tan, D. G. H., Vose, R. S., Voyles, J., Wang, J., Whiteman, D. N., and Williams, S.

Published

2019

19. Rain Evaporation Rate Estimates from Dual-Wavelength Lidar Measurements and Intercomparison against a Model Analytical Solution

Author

Lolli, S., primary, Di Girolamo, P., additional, Demoz, B., additional, Li, X., additional, and Welton, E. J., additional

Published

2017

20. Statistical modelling of collocation uncertainty in atmospheric thermodynamic profiles

Author

Fassò, A., primary, Ignaccolo, R., additional, Madonna, F., additional, Demoz, B. B., additional, and Franco-Villoria, M., additional

Published

2014

21. Vibrio cholerae in waters of the Sunderban mangrove: relationship with biogeochemical parameters and chitin in seston size fractions

Author

Lara, R. J., Neogi, S. B., Islam, M. S., Mahmud, Z. H., Islam, Shahidul, Paul, D., Demoz, B. B., Yamasaki, S., Nair, G. B., Kattner, Gerhard, Lara, R. J., Neogi, S. B., Islam, M. S., Mahmud, Z. H., Islam, Shahidul, Paul, D., Demoz, B. B., Yamasaki, S., Nair, G. B., and Kattner, Gerhard

Published

2011

22. First Report of Blackleg Caused by Leptosphaeria maculans on Canola in Idaho

Author

Agostini, A., primary, Johnson, D. A., additional, Hulbert, S., additional, Demoz, B., additional, Fernando, W. G. D., additional, and Paulitz, T., additional

Published

2013

23. Water Vapor Measurements by Howard University Raman Lidar during the WAVES 2006 Campaign

Author

Adam, M., primary, Demoz, B. B., primary, Venable, D. D., primary, Joseph, E., primary, Connell, R., primary, Whiteman, D. N., additional, Gambacorta, A., additional, Wei, J., additional, Shephard, M. W., additional, Miloshevich, L. M., additional, Barnet, C. D., additional, Herman, R. L., additional, and Fitzgibbon, J., additional

Published

2010

24. Raman Lidar Measurements during the International H2O Project. Part II: Case Studies

Author

Whiteman, D. N., primary, Demoz, B., primary, Schwemmer, G., primary, Gentry, B., primary, Di Girolamo, P., additional, Sabatino, D., additional, Comer, J., additional, Veselovskii, I., additional, Evans, K., additional, Lin, R-F., additional, Wang, Z., additional, Behrendt, A., additional, Wulfmeyer, V., additional, Browell, E., additional, Ferrare, R., additional, Ismail, S., additional, and Wang, J., additional

Published

2006

25. Raman Lidar Measurements during the International H2O Project. Part I: Instrumentation and Analysis Techniques

Author

Whiteman, D. N., primary, Demoz, B., primary, Rush, K., primary, Schwemmer, G., primary, Gentry, B., primary, Di Girolamo, P., additional, Comer, J., additional, Veselovskii, I., additional, Evans, K., additional, Melfi, S. H., additional, Wang, Z., additional, Cadirola, M., additional, Mielke, B., additional, Venable, D., additional, and Van Hove, T., additional

Published

2006

26. The Cold Front of 15 April 1994 over the Central United States. Part I: Observations

Author

Demoz, B. B., primary, Starr, D. O’C., primary, Evans, K. D., primary, Lare, A. R., primary, Whiteman, D. N., primary, Schwemmer, G., primary, Ferrare, R. A., primary, Goldsmith, J. E. M., primary, and Bisson, S. E., primary

Published

2005

27. Characterization of Upper-Troposphere Water Vapor Measurements during AFWEX Using LASE

Author

Ferrare, R. A., primary, Browell, E. V., primary, Ismail, S., primary, Kooi, S. A., primary, Brasseur, L. H., primary, Brackett, V. G., primary, Clayton, M. B., primary, Barrick, J. D. W., primary, Diskin, G. S., primary, Goldsmith, J. E. M., primary, Lesht, B. M., primary, Podolske, J. R., primary, Sachse, G. W., primary, Schmidlin, F. J., primary, Turner, D. D., primary, Whiteman, D. N., primary, Tobin, D., primary, Miloshevich, L. M., primary, Revercomb, H. E., primary, Demoz, B. B., primary, and Di Girolamo, P., primary

Published

2004

28. Subtropical cirrus cloud extinction to backscatter ratios measured by Raman Lidar during CAMEX-3

Author

Whiteman, D. N., primary, Demoz, B., additional, and Wang, Z., additional

Published

2004

29. A three-stage cloud impactor for size-resolved measurement of cloud drop chemistry

Author

Collett, J., primary, Iovinelli, R., additional, and Demoz, B., additional

Published

1995

30. Statistical modelling of collocation uncertainty in atmospheric thermodynamic profiles.

Author

Fassò, A., Ignaccolo, R., Madonna, F., and Demoz, B. B.

Subjects

COLLOCATION methods, ATMOSPHERIC thermodynamics, GLOBAL environmental change, HETEROSCEDASTICITY, REGRESSION analysis

Abstract

The uncertainty of important atmospheric parameters is a key factor for assessing the uncertainty of global change estimates given by numerical prediction models. One of the critical points of the uncertainty budget is related to the collocation mismatch in space and time among different observations. This is particularly important for vertical atmospheric profiles obtained by radiosondes or LIDAR. In this paper we consider a statistical modelling approach to understand at which extent collocation uncertainty is related to environmental factors, height and distance between the trajectories. To do this we introduce a new statistical approach, based on the heteroskedastic functional regression (HFR) model which extends the standard functional regression approach and allows us a natural definition of uncertainty profiles. Moreover, using this modelling approach, a five-folded uncertainty decomposition is proposed. Eventually, the HFR approach is illustrated by the collocation uncertainty analysis of relative humidity from two stations involved in GCOS reference upper-air network (GRUAN). [ABSTRACT FROM AUTHOR]

Published

2013

31. Raman Lidar Measurements during the International H2O Project. Part I: Instrumentation and Analysis Techniques.

Author

Whiteman, D. N., Demoz, B., Di Girolamo, P., Comer, J., Veselovskii, I., Evans, K., Wang, Z., Cadirola, M., Rush, K., Schwemmer, G., Gentry, B., Melfi, S. H., Mielke, B., Venable, D., and Van Hove, T.

Subjects

*OPTICAL radar, *LASER communication systems, *OPTICAL communications, *RADAR, *SPACE flight, *RAMAN effect, *PHYSICAL measurements, *CIRRUS clouds, *ICE clouds

Abstract

The NASA Goddard Space Flight Center (GSFC) Scanning Raman Lidar (SRL) participated in the International H2O Project (IHOP), which occurred in May and June 2002 in the midwestern part of the United States. The SRL received extensive optical modifications prior to and during the IHOP campaign that added new measurement capabilities and enabled unprecedented daytime water vapor measurements by a Raman lidar system. Improvements were also realized in nighttime upper-tropospheric water vapor measurements. The other new measurements that were added to the SRL for the IHOP deployment included rotational Raman temperature, depolarization, cloud liquid water, and cirrus cloud ice water content. In this first of two parts, the details of the operational configuration of the SRL during IHOP are provided along with a description of the analysis and calibration procedures for water vapor mixing ratio, aerosol depolarization, and cirrus cloud extinction-to-backscatter ratio. For the first time, a Raman water vapor lidar calibration is performed, taking full account of the temperature sensitivity of water vapor and nitrogen Raman scattering. Part II presents case studies that permit the daytime and nighttime error statistics to be quantified. [ABSTRACT FROM AUTHOR]

Published

2006

32. Raman Lidar Measurements during the International H2O Project. Part II: Case Studies.

Author

Whiteman, D. N., Demoz, B., Di Girolamo, P., Comer, J., Veselovskii, I., Evans, K., Wang, Z., Sabatino, D., Schwemmer, G., Gentry, B., Lin, R-F., Behrendt, A., Wulfmeyer, V., Browell, E., Ferrare, R., Ismail, S., and Wang, J.

Subjects

*RAMAN effect, *OPTICAL radar, *FLUID dynamics, *HUMIDITY control, *RADIOSONDES, *METEOROLOGICAL instruments, *RADIOSONDE observations of the upper atmosphere, *PHYSICS instruments, *GEOPHYSICAL instruments

Abstract

The NASA GSFC Scanning Raman Lidar (SRL) participated in the International H2O Project (IHOP) that occurred in May and June 2002 in the midwestern part of the United States. The SRL system configuration and methods of data analysis were described in Part I of this paper. In this second part, comparisons of SRL water vapor measurements and those of Lidar Atmospheric Sensing Experiment (LASE) airborne water vapor lidar and chilled-mirror radiosonde are performed. Two case studies are then presented: one for daytime and one for nighttime. The daytime case study is of a convectively driven boundary layer event and is used to characterize the daytime SRL water vapor random error characteristics. The nighttime case study is of a thunderstorm-generated cirrus cloud case that is studied in its meteorological context. Upper-tropospheric humidification due to precipitation from the cirrus cloud is quantified as is the cirrus cloud optical depth, extinction-to-backscatter ratio, ice water content, cirrus particle size, and both particle and volume depolarization ratios. A stability and back-trajectory analysis is performed to study the origin of wave activity in one of the cloud layers. These unprecedented cirrus cloud measurements are being used in a cirrus cloud modeling study. [ABSTRACT FROM AUTHOR]

Published

2006

33. Assessment of Planetary Boundary Layer parametrizations and urban heat island comparison: Impacts and implications for tracer transport.

Author

Lopez-Coto I, Hicks M, Karion A, Sakai RK, Demoz B, Prasad K, and Whetstone J

Abstract

Accurate simulation of planetary boundary layer height (PBLH) is key to greenhouse gas emission estimation, air quality prediction and weather forecasting. This manuscript describes an extensive performance assessment of several Weather Research and Forecasting (WRF) model configurations where novel observations from ceilometers, surface stations and a flux tower were used to study their ability to reproduce planetary boundary layer heights (PBLH) and the impact that the urban heat island (UHI) has on the modeled PBLHs in the greater Washington, D.C. area. In addition, CO 2 measurements at two urban towers were compared to tracer transport simulations. The ensemble of models used 4 PBL parameterizations, 2 sources of initial and boundary conditions and 1 configuration including the building energy parameterization (BEP) urban canopy model. Results have shown low biases over the whole domain and period for wind speed, wind direction and temperature with no drastic differences between meteorological drivers. We find that PBLH errors are mostly positively correlated with sensible heat flux errors, and that modeled positive UHI intensities are associated with deeper modeled PBLs over the urban areas. In addition, we find that modeled PBLHs are typically biased low during nighttime for most of the configurations with the exception of those using the MYNN parametrization and that these biases directly translate to tracer biases. Overall, the configurations using MYNN scheme performed the best, reproducing the PBLH and CO 2 molar fractions reasonably well during all hours, thus opening the door to future nighttime inverse modeling.

Published

2020

34. Characteristics of Lake Chad level variability and links to ENSO, precipitation, and river discharge.

Author

Okonkwo C, Demoz B, and Gebremariam S

Subjects

Chad, Lakes, Rain, Rivers

Abstract

This study used trend, correlation, and wavelet analysis to characterize Lake Chad (LC) level fluctuations, river discharge, El Niño Southern Oscillation (ENSO), and precipitation regimes and their interrelationships. Linear correlation results indicate a negative association between ENSO and LC level, river discharge and precipitation. Trend analysis shows increasing precipitation in the Lake Chad Basin (LCB) but decreasing LC level. The mode of interannual variability in LC level, rainfall, and ENSO analyzed using wavelet analysis is dominated by 3-4-year periods. Results show that variability in ENSO could explain only 31% and 13% of variations in LC level at Kindjeria and precipitation in the northern LCB, respectively. The wavelet transform coherency (WTC) between LC level of the southern pool at Kalom and ENSO is statistically significant at the 95% confidence level and phase-locked, implying a cause-and-effect association. These strong coherencies coincide with the La Niña years with the exception of 1997-1998 El Niño events. The WTC shows strong covariance between increasing precipitation and LC level in the northern pool at a 2- to 4-year band and 3- to 4-year band localized from 1996 to 2010. Implications for water resource planning and management are discussed.

Published

2014

35. Validation of the Raman lidar algorithm for quantifying aerosol extinction.

Author

Russo F, Whiteman DN, Demoz B, and Hoff RM

Abstract

To calculate aerosol extinction from Raman lidar data, it is necessary to evaluate the derivative of a molecular Raman signal with respect to range. The typical approach taken in the lidar community is to make an a priori assumption about the functional behavior of the data to calculate the derivative. It has previously been shown that the use of the chi-squared technique to determine the most likely functional behavior of the data prior to actually calculating the derivative eliminates the need for making a priori assumptions. Here that technique is validated through numerical simulation and by application to a significant body of Raman lidar measurements. In general, we show that the chi-squared approach for evaluating extinction yields lower extinction uncertainty than traditional techniques. We also use the technique to study the feasibility of developing a general characterization of the extinction uncertainty that could permit the uncertainty in Raman lidar aerosol extinction measurements to be estimated accurately without the need of the chi-squared technique.

Published

2006

36. Numerical simulation of light backscattering by spheres with off-center inclusion. Application to the lidar case.

Author

Griaznov V, Veselovskii I, Di Girolamo P, Demoz B, and Whiteman DN

Abstract

A Mie backscattering model for spherical particles with off-center inclusion has been developed and tested. The program is capable of dealing with size parameter values up to approximately 1000, thus allowing one to simulate the optical behavior of a large variety of atmospheric aerosols, as well as cloud and precipitation particles. On the basis of this model, we simulated the optical properties of polydisperse composite atmospheric particles as observed by ground-based and airborne lidar systems. We have characterized optical properties in terms of host and inclusion radii, considering water particles with different composition inclusions. The performed modeling provides some insight into the so-called lidar bright- and dark-band phenomenon.

Published

2004