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1. Long-Term Monitoring of the Stratosphere by Lidars in the Network for the Detection of Atmospheric Composition Change

Author

Steinbrecht, Wolfgang, Leblanc, Thierry, Godin-Beekmann, Sophie, Khaykin, Sergey M., Hauchecorne, Alain, Keckhut, Philippe, Querel, Richard, Swart, Daan P. J., McGee, Thomas J., Sullivan, John T., editor, Leblanc, Thierry, editor, Tucker, Sara, editor, Demoz, Belay, editor, Eloranta, Edwin, editor, Hostetler, Chris, editor, Ishii, Shoken, editor, Mona, Lucia, editor, Moshary, Fred, editor, Papayannis, Alexandros, editor, and Rupavatharam, Krishna, editor

Published
2023
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3. Taehwa Research Forest: a receptor site for severe domestic pollution events in Korea during 2016

Author

Sullivan, John T, McGee, Thomas J, Stauffer, Ryan M, Thompson, Anne M, Weinheimer, Andrew, Knote, Christoph, Janz, Scott, Wisthaler, Armin, Long, Russell, Szykman, James, Park, Jinsoo, Lee, Youngjae, Kim, Saewung, Jeong, Daun, Sanchez, Dianne, Twigg, Laurence, Sumnicht, Grant, Knepp, Travis, and Schroeder, Jason R

Subjects
Climate Action, Astronomical and Space Sciences, Atmospheric Sciences, Meteorology & Atmospheric Sciences
Abstract

During the May-June 2016 International Cooperative Air Quality Field Study in Korea (KORUS-AQ), light synoptic meteorological forcing facilitated Seoul metropolitan pollution outflow to reach the remote Taehwa Research Forest (TRF) site and cause regulatory exceedances of ozone on 24 days. Two of these severe pollution events are thoroughly examined. The first, occurring on 17 May 2016, tracks transboundary pollution transport exiting eastern China and the Yellow Sea, traversing the Seoul Metropolitan Area (SMA), and then reaching TRF in the afternoon hours with severely polluted conditions. This case study indicates that although outflow from China and the Yellow Sea were elevated with respect to chemically unperturbed conditions, the regulatory exceedance at TRF was directly linked in time, space, and altitude to urban Seoul emissions. The second case studied, occurring on 09 June 2016, reveals that increased levels of biogenic emissions, in combination with amplified urban emissions, were associated with severe levels of pollutions and a regulatory exceedance at TRF. In summary, domestic emissions may be causing more pollution than by trans-boundary pathways, which have been historically believed to be the major source of air pollution in South Korea. The case studies are assessed with multiple aircraft, model (photochemical and meteorological) simulations, in-situ chemical sampling, and extensive ground-based profiling at TRF. These observations clearly identify TRF and the surrounding rural communities as receptor sites for severe pollution events associated with Seoul outflow, which will result in long-term negative effects to both human health and agriculture in the affected areas.

Published
2019

6. Lidar Validation Measurements at the NOAA Mauna Loa Observatory NDACC Station

Author

McGee, Thomas J, Twigg, Laurence W, Sullivan, John T, Leblanc, Thierry, Barnes, John E, Sumnicht, Grant K, and McDermid, Stuart

Subjects
Earth Resources And Remote Sensing
Abstract

NASA's Goddard Space Flight Center (GSFC) transported two lidar instruments to the NOAA facility at the Mauna Loa Observatory (MLO) on the Big Island of Hawaii, to participate in an official, extended validation campaign. This site is situated 11,141 ft. above sea level on the side of the mountain. The observatory has been making atmospheric measurements regularly since the 1950's, and has hosted the GSFC Stratospheric Ozone (STROZ) Lidar and the GSFC Aerosol and Temperature (AT) Lidar on several occasions, most recently between November, 2012 and November, 2015. The purpose of this extended deployment was to participate in Network for the Detection of Atmospheric Composition Change (NDACC) Validation campaigns with the JPL Stratospheric Ozone Lidar and the NOAA Temperature, Aerosol and Water Vapor instruments as part of the routine NDACC Validation Protocol.

Published
2018

7. The Network for the Detection of Atmospheric Composition Change (NDACC): History, Status and Perspectives

Author

De Maziere, Martine, Thompson, Anne M, Kurylo, Michael J, Wild, Jeannette D, Bernhard, Germar, Blumenstock, Thomas, Braathen, Geir O, Hannigan, James W, Lambert, Jean-Christopher, Leblanc, Thierry, McGee, Thomas J, Nedoluha, Gerald, Petropavlovskikh, Irina, Seckmeyer, Gunther, Simon, Paul C, Steinbrecht, Wolfgang, and Strahan, Susan E

Subjects
Meteorology And Climatology
Abstract

The Network for the Detection of Atmospheric Composition Change (NDACC) is an international global network of more than 90 stations making high-quality measurements of atmospheric composition that began official operations in 1991 after 5 years of planning. Apart from sonde measurements, all measurements in the network are performed by ground-based remote-sensing techniques. Originally named the Network for the Detection of Stratospheric Change (NDSC), the name of the network was changed to NDACC in 2005 to better reflect the expanded scope of its measurements. The primary goal of NDACC is to establish long-term databases for detecting changes and trends in the chemical and physical state of the atmosphere (mesosphere, stratosphere, and troposphere) and to assess the coupling of such changes with climate and air quality. NDACC's origins, station locations, organizational structure, and data archiving are described. NDACC is structured around categories of ground-based observational techniques (sonde, lidar, microwave radiometers, Fourier-transform infrared, UV-visible DOAS (differential optical absorption spectroscopy)-type, and Dobson-Brewer spectrometers, as well as spectral UV radiometers), timely cross-cutting themes (ozone, water vapour, measurement strategies, cross-network data integration), satellite measurement systems, and theory and analyses. Participation in NDACC requires compliance with strict measurement and data protocols to ensure that the network data are of high and consistent quality. To widen its scope, NDACC has established formal collaborative agreements with eight other cooperating networks and Global Atmosphere Watch (GAW). A brief history is provided, major accomplishments of NDACC during its first 25 years of operation are reviewed, and a forward-looking perspective is presented.

Published
2018
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8. Tropospheric and stratospheric ozone profiles during the 2019 TROpomi vaLIdation eXperiment (TROLIX-19)

Author

Sullivan, John T., primary, Apituley, Arnoud, additional, Mettig, Nora, additional, Kreher, Karin, additional, Knowland, K. Emma, additional, Allaart, Marc, additional, Piters, Ankie, additional, Van Roozendael, Michel, additional, Veefkind, Pepijn, additional, Ziemke, Jerry R., additional, Kramarova, Natalya, additional, Weber, Mark, additional, Rozanov, Alexei, additional, Twigg, Laurence, additional, Sumnicht, Grant, additional, and McGee, Thomas J., additional

Published
2022
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9. Quantifying TOLNet Ozone Lidar Accuracy During the 2014 DISCOVER-AQ and FRAPPE Campaigns

Author

Wang, Lihua, Newchurch, Michael J, Alvarez, Raul J., II, Berkoff, Timothy A, Brown, Steven S, Carrion, William, De Young, Russell J, Johnson, Bryan J, Ganoe, Rene, Gronoff, Guillaume, Kirgis, Guillaume, Kuang, Shi, Langford, Andrew O, Leblanc, Thierry, McDuffie, Erin E, McGee, Thomas J, Pliutau, Denis, Senff, Christoph J, Sullivan, John T, Sumnicht, Grant, Twigg, Laurence W, and Weinheimer, Andrew J

Subjects
Earth Resources And Remote Sensing
Abstract

The Tropospheric Ozone Lidar Network (TOLNet) is a unique network of lidar systems that measure high-resolution atmospheric profiles of ozone. The accurate characterization of these lidars is necessary to determine the uniformity of the network calibration. From July to August 2014, three lidars, the TROPospheric OZone (TROPOZ) lidar, the Tunable Optical Profiler for Aerosol and oZone (TOPAZ) lidar, and the Langley Mobile Ozone Lidar (LMOL), of TOLNet participated in the Deriving Information on Surface conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER-AQ) mission and the Front Range Air Pollution and Photochemistry Experiment (FRAPPA) to measure ozone variations from the boundary layer to the top of the troposphere. This study presents the analysis of the intercomparison between the TROPOZ, TOPAZ, and LMOL lidars, along with comparisons between the lidars and other in situ ozone instruments including ozonesondes and a P-3B airborne chemiluminescence sensor. The TOLNet lidars measured vertical ozone structures with an accuracy generally better than +/-15 % within the troposphere. Larger differences occur at some individual altitudes in both the near-field and far-field range of the lidar systems, largely as expected. In terms of column average, the TOLNet lidars measured ozone with an accuracy better than +/-5 % for both the intercomparison between the lidars and between the lidars and other instruments. These results indicate that these three TOLNet lidars are suitable for use in air quality, satellite validation, and ozone modeling efforts.

Published
2017
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11. Evaluating A Priori Ozone Profile Information Used in TEMPO Tropospheric Ozone Retrievals

Author

Johnson, Matthew S, Sullivan, John T, Liu, Xiong, Newchurch, Mike, Kuang, Shi, McGee, Thomas J, Langford, Andrew O'Neil, Senff, Christoph J, Leblanc, Thierry, Berkoff, Timothy, Gronoff, Guillaume, Chen, Gao, and Strawbridge, Kevin B

Subjects
Earth Resources And Remote Sensing
Abstract

Ozone (O3) is a greenhouse gas and toxic pollutant which plays a major role in air quality. Typically, monitoring of surface air quality and O3 mixing ratios is primarily conducted using in situ measurement networks. This is partially due to high-quality information related to air quality being limited from space-borne platforms due to coarse spatial resolution, limited temporal frequency, and minimal sensitivity to lower tropospheric and surface-level O3. The Tropospheric Emissions: Monitoring of Pollution (TEMPO) satellite is designed to address these limitations of current space-based platforms and to improve our ability to monitor North American air quality. TEMPO will provide hourly data of total column and vertical profiles of O3 with high spatial resolution to be used as a near-real-time air quality product. TEMPO O3 retrievals will apply the Smithsonian Astrophysical Observatory profile algorithm developed based on work from GOME, GOME-2, and OMI. This algorithm uses a priori O3 profile information from a climatological data-base developed from long-term ozone-sonde measurements (tropopause-based (TB) O3 climatology). It has been shown that satellite O3 retrievals are sensitive to a priori O3 profiles and covariance matrices. During this work we investigate the climatological data to be used in TEMPO algorithms (TB O3) and simulated data from the NASA GMAO Goddard Earth Observing System (GEOS-5) Forward Processing (FP) near-real-time (NRT) model products. These two data products will be evaluated with ground-based lidar data from the Tropospheric Ozone Lidar Network (TOLNet) at various locations of the US. This study evaluates the TB climatology, GEOS-5 climatology, and 3-hourly GEOS-5 data compared to lower tropospheric observations to demonstrate the accuracy of a priori information to potentially be used in TEMPO O3 algorithms. Here we present our initial analysis and the theoretical impact on TEMPO retrievals in the lower troposphere.

Published
2016

12. Quantifying the Contribution of Thermally Driven Recirculation to a High-Ozone Event Along the Colorado Front Range Using Lidar

Author

Sullivan, John T, McGee, Thomas J, Langford, Andrew O, Alvarez, Raul J., II, Senff, Christoph, Reddy, Patrick J, Thompson, Anne M, Twigg, Laurence W, Sumnicht, Grant K, Lee, Pius, Weinheimer, Andrew, Knote, Christop, Long, Russell W, and Hoff, Raymond M

Subjects
Geosciences (General)
Abstract

A high-ozone (O3) pollution episode was observed on 22 July 2014 during the concurrent Deriving Information on Surface Conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER-AQ) and Front Range Air Pollution and Photochemistry Experiment (FRAPPE) campaigns in northern Colorado. Surface O3 monitors at three regulatory sites exceeded the Environmental Protection Agency (EPA) 2008 National Ambient Air Quality Standard (NAAQS) daily maximum 8h average (MDA8) of 75ppbv. To further characterize the polluted air mass and assess transport throughout the event, measurements are presented from O3 and wind profilers, O3-sondes, aircraft, and surface-monitoring sites. Observations indicate that thermally driven upslope flow was established throughout the Colorado Front Range during the pollution episode. As the thermally driven flow persisted throughout the day, O3 concentrations increased and affected high-elevation Rocky Mountain sites. These observations, coupled with modeling analyses, demonstrate a westerly return flow of polluted air aloft, indicating that the mountain-plains solenoid circulation was established and impacted surface conditions within the Front Range.

Published
2016
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13. Results of a Longer Term NDACC Measurements Comparison Campaign at Mauna Loa Observatory

Author

McGee, Thomas J, Twigg, Laurence W, Sumnicht, Grant K, Leblanc, Thierry, and Barnes, John

Subjects
Environment Pollution, Meteorology And Climatology
Abstract

Between November, 2015 and January, 2015, the Goddard Space Flight Center (GSFC) operated a pair of lidar instruments at the NOAA (National Oceanic and Atmospheric Administration) facility at Mauna Loa on the Big Island of Hawaii (Latitude 19.5 degrees North, Longitude 155.5 degrees West, altitude 3.397 kilometers). Measurements were made during six different four week periods during this time period by both the NASA GSFC Stratospheric Ozone Lidar (STROZ) and the Aerosol and Temperature (ATL) lidar. Also making measurements were the JPL Stratospheric Ozone Lidar and the NOAA Aerosol and Water Vapor Lidar. All instruments participate and archive data with the Network for the Detection of Atmospheric Composition Change (NDACC). Measurement comparisons were made among various instruments in accordance with the standard intercomparison protocols of the NDACC.

Published
2016
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14. TOLNet ozone lidar intercomparison during the discover-aq and frappé campaigns

Author

Newchurch Michael J., Alvarez Raul J., Berkoff Timothy A., Carrion William, DeYoung Russell J., Ganoe Rene, Gronoff Guillaume, Kirgis Guillaume, Kuang Shi, Langford Andy O., Leblanc Thierry, McGee Thomas J., Pliutau Denis, Senff Christoph, Sullivan John T., Sumnicht Grant, Twigg Laurence W., and Wang Lihua

Subjects
Physics, QC1-999
Abstract

The Tropospheric Ozone Lidar Network (TOLNet) is a unique network of lidar systems that measure atmospheric profiles of ozone and aerosols, to contribute to air-quality studies, atmospheric modeling, and satellite validation efforts. The accurate characterization of these lidars is of critical interest, and is necessary to determine cross-instrument calibration uniformity. From July to August 2014, three lidars, the TROPospheric OZone (TROPOZ) lidar, the Tunable Optical Profiler for Aerosol and oZone (TOPAZ) lidar, and the Langley Mobile Ozone Lidar (LMOL), of TOLNet participated in the “Deriving Information on Surface conditions from Column and Vertically Resolved Observations Relevant to Air Quality” (DISCOVER-AQ) mission and the “Front Range Air Pollution and Photochemistry Éxperiment” (FRAPPÉ) to measure sub-hourly ozone variations from near the surface to the top of the troposphere. Although large differences occur at few individual altitudes in the near field and far field range, the TOLNet lidars agree with each other within ±4%. These results indicate excellent measurement accuracy for the TOLNet lidars that is suitable for use in air-quality and ozone modeling efforts.

Published
2018
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15. Ozone Lidar Observations for Air Quality Studies

Author

Wang, Lihua, Newchurch, Mike, Kuang, Shi, Burris, John F, Huang, Guanyu, Pour-Biazar, Arastoo, Koshak, William, Follette-Cook, Melanie B, Pickering, Kenneth E, McGee, Thomas J, Sullivan, John T, Langford, Andrew O, Senff, Christoph J, Alvarez, Raul, and Eloranta, Edwin

Subjects
Geophysics
Abstract

Tropospheric ozone lidars are well suited to measuring the high spatio-temporal variability of this important trace gas. Furthermore, lidar measurements in conjunction with balloon soundings, aircraft, and satellite observations provide substantial information about a variety of atmospheric chemical and physical processes. Examples of processes elucidated by ozone-lidar measurements are presented, and modeling studies using WRF-Chem, RAQMS, and DALES/LES models illustrate our current understanding and shortcomings of these processes.

Published
2015

16. TOLNet - A Tropospheric Ozone Lidar Profiling Network for Satellite Continuity and Process Studies

Author

Newchurch, Michael J, Kuang, Shi, Wang, Lihua, LeBlanc, Thierry, Alvarez II, Raul J, Langford, Andrew O, Senff, Christoph J, Brown, Steve, Johnson, Bryan, Burris, John F, McGee, Thomas J, and Sullivan, John T

Subjects
Communications And Radar
Abstract

NASA initiated an interagency ozone lidar observation network under the name TOLNet to promote cooperative multiple-station ozone-lidar observations to provide highly time-resolved (few minutes) tropospheric-ozone vertical profiles useful for air-quality studies, model evaluation, and satellite validation.

Published
2015

17. Characterizing the Vertical Processes of Ozone in Colorado's Front Range Using the GSFC Ozone Dial

Author

Sullivan, John T, McGee, Thomas J, Hoff, Raymond M, Sumnicht, Grant, and Twigg, Laurence

Subjects
Geosciences (General)
Abstract

Although characterizing the interactions of ozone throughout the entire troposphere are important for health and climate processes, there is a lack of routine measurements of vertical profiles within the United States. In order to monitor this lower ozone more effectively, the National Aeronautics and Space Administration (NASA) Goddard Space Flight Center TROPospheric OZone DIfferential Absorption Lidar (GSFC TROPOZDIAL) has been developed and validated within the Tropospheric Ozone Lidar Network (TOLNet). Two scientifically interesting ozone episodes are presented that were observed during the 2014 Deriving Information on Surface Conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER AQ) campaign at Ft. Collins,Colorado.The first case study, occurring between 22-23 July 2014, indicates enhanced concentrations of ozone at Ft. Collins during nighttime hours, which was due to the complex recirculation of ozone within the foothills of the Rocky Mountain region. Although quantifying the ozone increase a loft during recirculation episodes has been historically difficult, results indicate that an increase of 20 -30 ppbv of ozone at the Ft. Collins site has been attributed to this recirculation. The second case, occurring between Aug 4-8th 2014, characterizes a dynamical exchange of ozone between the stratosphere and the troposphere. This case, along with seasonal model parameters from previous years, is used to estimate the stratospheric contribution to the Rocky Mountain region. Results suggest that a large amount of stratospheric air is residing in the troposphere in the summertime near Ft. Collins, CO. The results also indicate that warmer tropopauses are correlated with an increase in stratospheric air below the tropopause in the Rocky Mountain Region.

Published
2015
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19. TOLNET – A Tropospheric Ozone Lidar Profiling Network for Satellite Continuity and Process Studies

Author

Newchurch Michael J., Kuang Shi, Leblanc Thierry, Alvarez Raul J., Langford Andrew O., Senff Christoph J., Burris John F., McGee Thomas J., Sullivan John T., DeYoung Russell J., Al-Saadi Jassim, Johnson Matthew, and Pszenny Alex

Subjects
Physics, QC1-999
Abstract

Ozone lidars measure continuous, high-resolution ozone profiles critical for process studies and for satellite validation in the lower troposphere. However, the effectiveness of lidar validation by using single-station data is limited. Recently, NASA initiated an interagency ozone lidar observation network under the name TOLNet to promote cooperative multiple-station ozone-lidar observations to provide highly timeresolved (few minutes) tropospheric-ozone vertical profiles useful for air-quality studies, model evaluation, and satellite validation. This article briefly describes the concept, stations, major specifications of the TOLNet instruments, and data archiving.

Published
2016
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20. Three-signal method for accurate measurements of depolarization ratio with lidar

Author

Reichardt, Jens, Baumgart, Rudolf, and McGee, Thomas J.

Subjects
Optical radar -- Research, Astronomy, Physics
Abstract

A method is presented that permits the determination of atmospheric depolarization-ratio profiles from three elastic-backscatter lidar signals with different sensitivity to the state of polarization of the backscattered light. The three-signal method is far less sensitive to experimental errors and does not require calibration of the measurement, as is the case of the two-signal lidar technique conventionally used for the observation of depolarization ratios. The three-signal method is applied to a polar stratospheric cloud observation. In the analysis we show that, depending on the statistical error of the measurement and on the lidar system parameters, the new method requires minimum cloud volume depolarization ratios to be applicable; in the case study presented, this threshold is ~0.2. Depolarization ratios determined with the three-signal method can be used to accurately calibrate measurements with the conventional two-signal technique. OCIS codes: 280.3640, 290.1350, 290.1090, 280.1310.

Published
2003

22. Intercomparison and evaluation of ground- and satellite-based stratospheric ozone and temperature profiles above Observatoire de Haute-Provence during the Lidar Validation NDACC Experiment (LAVANDE)

Author

Wing, Robin, primary, Steinbrecht, Wolfgang, additional, Godin-Beekmann, Sophie, additional, McGee, Thomas J., additional, Sullivan, John T., additional, Sumnicht, Grant, additional, Ancellet, Gérard, additional, Hauchecorne, Alain, additional, Khaykin, Sergey, additional, and Keckhut, Philippe, additional

Published
2020
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23. Intercomparison and Evaluation of Ground- and Satellite-Based Stratospheric Ozone and Temperature profiles above Observatoire Haute Provence during the Lidar Validation NDACC Experiment (LAVANDE)

Author

Wing, Robin, primary, Steinbrecht, Wolfgang, additional, Godin-Beekmann, Sophie, additional, McGee, Thomas J., additional, Sullivan, John T., additional, Sumnicht, Grant, additional, Ancellet, Gerard, additional, Hauchecorne, Alain, additional, Khaykin, Sergey, additional, and Keckhut, Philippe, additional

Published
2020
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24. NDACC Lidar Validation Activities in Europe

Author

Wing, Robin, primary, Steinbrecht, Wolfgang, additional, Godin-Beekmann, Sophie, additional, McGee, Thomas J., additional, Sullivan, John, additional, Sumnicht, Grant, additional, Ancellet, Gérard, additional, Hauchecorne, Alain, additional, Khaykin, Sergey, additional, and Keckhut, Philippe, additional

Published
2020
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26. Ozone differential absorption lidar algorithm intercomparison

Author

Godin, Sophie, Carswell, Allen I., Donovan, David P., Claude, Hans, Steinbrecht, Wolfgang, McDermid, I. Stuart, McGee, Thomas J., Gross, Michael R., Nakane, Hideaki, Swart, Daan P. J., Bergwerff, Hans B., Uchino, Osamu, Gathen, Peter von der, and Neuber, Roland

Subjects
Ozone -- Research, Optical radar -- Usage, Stratosphere -- Research, Astronomy, Physics
Abstract

An intercomparison of ozone differential absorption lidar algorithms was performed in 1996 within the framework of the Network for the Detection of Stratospheric Changes (NDSC) lidar working group. The objective of this research was mainly to test the differentiating techniques used by the various lidar teams involved in the NDSC for the calculation of the ozone number density from the lidar signals. The exercise consisted of processing synthetic lidar signals computed from simple Rayleigh scattering and three initial ozone profiles. Two of these profiles contained perturbations in the low and the high stratosphere to test the vertical resolution of the various algorithms. For the unperturbed profiles the results of the simulations show the correct behavior of the lidar processing methods in the low and the middle stratosphere with biases of less than 1% with respect to the initial profile to as high as 30 km in most cases. In the upper stratosphere, significant biases reaching 10% at 45 km for most of the algorithms are obtained. This bias is due to the decrease in the signal-to-noise ratio with altitude, which makes it necessary to increase the number of points of the derivative low-pass filter used for data processing. As a consequence the response of the various retrieval algorithms to perturbations in the ozone profile is much better in the lower stratosphere than in the higher range. These results show the necessity of limiting the vertical smoothing in the ozone lidar retrieval algorithm and questions the ability of current lidar systems to detect long-term ozone trends above 40 km. Otherwise the simulations show in general a correct estimation of the ozone profile random error and, as shown by the tests involving the perturbed ozone profiles, some inconsistency in the estimation of the vertical resolution among the lidar teams involved in this experiment.

Published
1999

27. Measurement Report: Tropospheric and Stratospheric Ozone Profiles during the 2019 TROpomi vaLIdation eXperiment (TROLIX-19).

Author

Sullivan, John T., Apituley, Arnoud, Mettig, Nora, Kreher, Karin, Knowland, K. Emma, Allaart, Marc, Piters, Ankie, Roozendael, Michel Van, Veefkind, Pepijn, Ziemke, Jerry R., Kramarova, Natalya, Weber, Mark, Rozanov, Alexei, Twigg, Laurence, Sumnicht, Grant, and McGee, Thomas J.

Abstract

A TROPOspheric Monitoring Instrument (TROPOMI) validation campaign was held in the Netherlands based at the CESAR (Cabauw Experimental Site for Atmospheric Research) Observatory during September 2019. The TROpomi vaLIdation eXperiment (TROLIX-19) consisted of active and passive remote sensing platforms in conjunction with several balloon-borne and surface chemical (e.g. ozone and nitrogen dioxide) measurements. The goal of this joint NASA-KNMI geophysical validation campaign was to make intensive observations in the TROPOMI domain in order to be able to establish the quality of the L2 satellite data products under realistic conditions, such as non-idealized conditions with varying cloud cover and a range of atmospheric conditions at a rural site. The research presented here focuses on using ozone lidars from NASA’s Goddard Space Flight Center to better evaluate the characterization of ozone throughout TROLIX-19. Results of comparisons to the lidar systems with balloon, space-borne, and ground-based passive measurements are shown. In addition, results are compared to a global coupled chemistry meteorology model to illustrate the vertical variability and columnar amounts of both tropospheric and stratospheric ozone during the campaign period. [ABSTRACT FROM AUTHOR]

Published
2022
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28. Temperature measurements made with a combined Rayleigh-Mie and Raman lidar

Author

Gross, Michael R., McGee, Thomas J., Ferrare, Richard A., Singh, Upendra N., and Kimvilakani, Patrick

Subjects
Optical radar -- Usage, Temperature measurements -- Methods, Rayleigh scattering -- Research, Raman effect -- Research, Astronomy, Physics
Abstract

The NASA Goddard Space Flight Center stratospheric ozone lidar system has the capability of collecting both Rayleigh-Mie and Raman backscatter data simultaneously at a number of wavelengths. Here we report on an improved method by which temperature can be derived from a combination of the RayleighMie return at 351-nm lidar channels and the Raman nitrogen return at 382-nm lidar channels. We also examine some common techniques by which temperatures are retrieved from lidar data. Finally, we show results obtained in 1995 during two Network for the Detection of Stratospheric Change intercomparison campaigns at Lauder, New Zealand and Mauna Loa, Hawaii. Key words: Lidar; Rayleigh, Mie, and Raman backscatter; tropospheric, stratospheric, and mesospheric temperature profiles.

Published
1997

30. AROTAL Ozone and Temperature Vertical Profile Measurements from the NASA DC-8 during the SOLVE II Campaign

Author

McGee, Thomas J, Twigg, Laurence, Sumnicht, Grant, Hoegy, Walter, Burris, John, Silbert, Donald, Heaps, William, Neuber, R, and Trepte, C. R

Subjects
Meteorology And Climatology
Abstract

The AROTAL instrument (Airborne Raman Ozone Temperature and Aerosol Lidar) - a collaboration between scientists at NASA Goddard Space Flight Center, and Langley Research Center - was flown on the NASA DC-8 during the SOLVE II Campaign during January and February, 2003. The flights were flown from the Arena Arctica in Kiruna, Sweden. We report measurements of temperature and ozone profiles showing approximately a 600 ppbv loss in ozone near 17.5 km, over the time frame of the aircraft campaign. Comparisons of ozone profiles from AROTAL are made with the SAGE III instrument.

Published
2004

31. Mobile Lidar Operations at GSFC

Author

McGee, Thomas J

Subjects
Meteorology And Climatology
Abstract

Since the last meeting, the GSFC Stratospheric Ozone Lidar has participated in two campaigns at MLO - an ozone and temperature comparison and a water vapor comparison. The trailer has been returned to GSFC to begin transfer into a sea container, before deployment to Reunion Island in Spring, 2004.

Published
2003

32. A Comparison of Co-located Ozonesonde and Lidar Measurements

Author

McGee, Thomas J, Twigg, L, Sumnicht, G, Gross, M, and Bhartia, P. K

Subjects
Environment Pollution
Abstract

As part of the NDSC, the GSFC mobile Ozone Lidar instrument has participated in numerous validation campaigns around the world. During all of these campaigns, ozonesondes were flown as part of the intercomparisons. This poster summarizes the results of these campaigns, and indicates that there are some biases between the sonde and lidar measurements.

Published
2001

33. Microphysical Interpretation of Cirrus Measurements With Lidar

Author

Reichardt, Jens, Lin, Ruei-Fong, Reichardt, Susanne, McGee, Thomas J, Starr, David OC, and Einaudi, Franco

Subjects
Meteorology And Climatology
Abstract

Cirrus measurements obtained with a ground-based polarization Raman lidar at 67.9 N in January 1997 reveal a strong correlation between the particle optical properties, specifically depolarization ratio delta and extinct ion-to-backscatter ratio S, for ambient cloud temperatures above approximately -45 C (delta less than approximately 40%), and an anti-correlation for colder temperatures (delta greater than approximately 40%). Over the length of the measurements (4-7.5 hours) the particle properties vary systematically: Initially, delta approximately equal to 60% and S approximately equal to 10sr are observed. Then, with decreasing delta, S first increases to approximately 27 sr(delta approximately equal to 40%) before decreasing to values around 10 sr again (delta approximately equal to 20%). The particle optical properties distinctly depend on the ambient temperature. For the microphysical analysis of the lidar observations. ray-tracing computations of particle scattering properties and a size-distribution resolving cirrus model with explicit microphysics have been used. The theoretical studies show that the optical properties and their temporal evolution can be interpreted in terms of size, shape, and growth of the cirrus particles: Near the cloud top in the early stage of the cirrus development, light scattering by small hexagonal columns with aspect ratios close to one is dominant. Over time the cloud base height extends to lower altitudes with warmer temperatures, the ice particles grow and get morphologically diverse (the scattering contributions of hexagonal columns and plates are roughly the same for large S and depolarization values of approximately 40%). In the lower ranges of the cirrus clouds, light scattering is predominantly by plate-like or complex ice particles. Mid-latitude cirrus data measured with the same instrument at 53.4 N between 1994 and 1996 follow closely the correlation between delta and S found in the warmer regions of the Arctic cirrus clouds (delta less than approximately 40%). Cirrus clouds with higher depolarization ratios are rarely observed, even for very cold ambient temperatures. Atmospheric parameters other than temperature, e.g., the availability of water vapor, are also important for the growth and the morphology of cirrus particles.

Published
2001

34. An Assessment of the Ozone Loss During the 1999-2000 SOLVE Arctic Campaign

Author

Schoeberl, Mark R, Newman, Paul A, Lait, Leslie R, McGee, Thomas J, Burris, John F, Browell, Edward V, Grant, William B, Richard, Eric, VonderGathen, Peter, Bevilacqua, Richard, and Einaudi, Franco

Subjects
Environment Pollution
Abstract

Ozone observations from ozonesondes, the lidars aboard the DC-8, in situ ozone measurements from the ER-2, and satellite ozone measurements from Polar Ozone and Aerosol Measurement III (POAM) were used to assess ozone loss during the Sage III Ozone Loss and Validation Experiment (SOLVE) 1999-2000 Arctic campaign. Two methods of analysis were used. In the first method a simple regression analysis is performed on the ozonesonde and POAM measurements within the vortex. In the second method, the ozone measurements from all available ozone data were injected into a free running diabatic trajectory model and carried forward in time from December 1 to March 15. Vortex ozone loss was then estimated by comparing the ozone values of those parcels initiated early in the campaign with those parcels injected later in the campaign. Despite the variety of observational techniques used during SOLVE, the measurements provide a fairly consistent picture. Over the whole vortex, the largest ozone loss occurs between 550 and 400 K potential temperatures (approximately 23-16 km) with over 1.5 ppmv lost by March 15, the end of the SOLVE mission period. An ozone loss rate of 0.04-0.05 ppmv/day was computed for March 15. Ozonesondes launched after March 15 suggest that an additional 0.5 ppmv or more ozone was lost between March 15 and April 1. The small disagreement between ozonesonde and POAM analysis of January ozone loss is found to be due to biases in vortex sampling. POAM makes most of its solar occultation measurements at the vortex edge during January 2000 which bias samples toward air parcels that have been exposed to sunlight and likely do experience ozone loss. Ozonesonde measurements and the trajectory technique use observations that are more distributed within the interior of the vortex. Thus the regression analysis of the POAM measurements tends to overestimate mid-winter vortex ozone loss. Finally, our loss calculations are broadly consistent with other loss computations using ER-2 tracer data and MLS satellite data, but we find no evidence for the 1992 high mid-January loss reported using the Match technique.

Published
2001

35. Retrieval of Polar Stratospheric Cloud Microphysical Properties From Lidar Measurements: Dependence on Particle Shape Assumptions

Author

Reichardt, Susanne, Reichardt, Jens, Yang, Ping, McGee, Thomas J, and Einaudi, Franco

Subjects
Environment Pollution
Abstract

Knowledge of particle sizes and number densities of polar stratospheric clouds (PSCs) is highly important, because they are critical parameters for the modeling of the ozone chemistry of the stratosphere. In situ measurements of PSC particles are rare. the main instrument for the accumulation of PSC data are lidar systems. Therefore the derivation of some microphysical properties of PSCS from the optical parameters measured by lidars would be highly beneficial for ozone research. Inversion of lidar data obtained in the presence of PSCs formed from crystalline particles type 11 and the various nitric acid tri Ydrrate (NAT) types cannot be easily accomplished, because a suitable scattering theory for small faceted crystals has not been readily available tip to now. As a consequence, the T-matrix method is commonly used for the interpretation of these PSC lidar data. Here the assumption is made that the optical properties of an ensemble of spheroids resemble those of crystalline PSCs, and microphysical properties of the PSC are inferred from the optical signatures of the PSC at two or more wavelengths. The problem with the T-matrix approach is that the assumption of spheroidal instead of faceted particles can lead to dramatically wrong results: Usually cloud particle properties are deduced from analysis of lidar profiles of backscatter ratio and depolarization ratio. The particle contribution to the backscatter ratio is given by the product of the particle number density and the backscattering cross section. The latter is proportional to the value of the particle's scattering phase function at 180 degrees scattering angle. At 180 degrees however, the phase functions of rough, faceted crystals and of spheroids with same maximum dimension differ by a factor of 6. From this it follows that for a PSC consisting of faceted crystals, the particle number density is underestimated by roughly the same factor if spheroidal particles are unrealistically assumed. We are currently developing a retrieval technique for determining the microphysical parameters of crystalline PSCs that takes into account the faceted shape of the PSC particles. This approach utilizes finite-difference time-domain (FDTD) calculations of particle optical properties. The accuracy and the free choice of the shape of the scattering particle make the FDTD technique a promising tool for the inversion of PSC lidar data. A first comparison of FDTD and T-matrix calculations will be presented.

Published
2001

36. An Intercomparison of Lidar Ozone and Temperature Measurements From the SOLVE Mission With Predicted Model Values

Author

Burris, John, McGee, Thomas J, Hoegy, Walt, Lait, Leslie, Sumnicht, Grant, Twigg, Larry, and Heaps, William

Subjects
Environment Pollution
Abstract

Temperature profiles acquired by Goddard Space Flight Center's AROTEL lidar during the SOLVE mission onboard NASA's DC-8 are compared with predicted values from several atmospheric models (DAO, NCEP and UKMO). The variability in the differences between measured and calculated temperature fields was approximately 5 K. Retrieved temperatures within the polar vortex showed large regions that were significantly colder than predicted by the atmospheric models.

Published
2000

37. Arctic chemical Ozone Loss Observed by the AROTEL Instrument during the SOLVE Campaign, December 1999 - March 2000

Author

McGee, Thomas J, Burris, John F, Hoegy, Walter, Newman, Paul, Heaps,William, Silbert, Donald, Lait, Leslie, Sumnicht, Grant, and Twigg, Laurence

Subjects
Environment Pollution
Abstract

During the winter of 1999-2000, the AROTEL instrument was deployed on the NASA DC-8 at Kiruna, Sweden for the SAGE III Ozone Loss Validation Experiment (SOLVE). Measurements of ozone, temperature and aerosols were made on 18 local science flights from December to March. Extremely low temperatures were observed throughout most of the Arctic vortex and polar stratospheric clouds were observed throughout the Arctic area during January. Significant ozone loss was measured after the sun began to rise on the vortex area in February. Ozone mixing ratios as low as 800 ppbv were observed during flights in March.

Published
2000

38. AROTEL - An Airborne Ozone, Aerosol and Temperature Lidar

Author

McGee, Thomas J, Burris, John F, Hoegy, Walter, Heaps, William, Silbert, Donald, Twigg, Laurence, Sumnicht, Grant, Nueber, Roland, Schmidt, Thomas, and Hostetler, Chris

Subjects
Environment Pollution
Abstract

The AROTEL instrument is a collaboration between scientists at NASA, Goddard Space Flight Center and NASA Langley Research Center. The instrument was designed and constructed to be flown on the NASA DC-8, and to measure vertical profiles of ozone, temperature and aerosol. The instrument transmits radiation at 308, 355, 532, and 1064 nm. Depolarization is measured at 532 nm. In addition to the transmitted wavelengths, Raman scattered signals at 332 nm and 387 nm are also collected. The instrument was installed aboard the DC-8 for the SAGE III Ozone Loss and Validation Experiment (SOLVE) which deployed from Kiruna, Sweden, during the winter of 1999-2000 to study the polar stratosphere. During this time, profile measurements of polar stratospheric clouds, ozone and temperature were made. This paper provides an instrumental overview as an introduction to several data papers to be presented in the poster sessions. In addition to samples of the measurements, examples will be given to establish the quality of the various data products.

Published
2000

39. Comparison of Temperature and Ozone Measured by the AROTEL Instrument on DC8 Overflights of Ny Aalesund during the SOLVE Mission

Author

Hoegy, Walter R, McGee, Thomas J, Burris, John F, Heaps, William, Silbert, Donald, Sumnicht, Grant, Twigg, Laurence, and Neuber, Roland

Subjects
Meteorology And Climatology
Abstract

The AROTEL instrument, deployed on the NASA DC-8 at Kiruna, Sweden for the SAGE III Ozone Loss and Validation Experiment (SOLVE), flew over the NDSC station operated by the Alfred Wegner Institute at Ny Aalesund, Spitsbergen. AROTEL ozone and temperature measurements made during near overflights of Ny Aalesund are compared with sonde ozone and temperature, and lidar ozone measurements from the NDSC station. Nine of the seventeen science flights during the December through March measurement period overflew near Ny Aalesund. Agreement of AROTEL with the ground-based temperature and ozone values at altitudes from just above the aircraft to about 30 km gives strong confidence in using AROTEL temperature and ozone mixing ratio to study the mechanisms of ozone loss in the winter arctic polar region.

Published
2000

40. Correlative Stratospheric Ozone Measurements with the Airborne UV DIAL System during TOTE/VOTE

Author

Grant, William B, Fenn, Marta A, Browell, Edward V, McGee, Thomas J, Singh, Upendra N, Gross, Michael R, McDermid, I. Stuart, Froidevaux, Lucien, and Wang, Pi-Huang

Subjects
Environment Pollution
Abstract

The airborne UV differential absorption lidar (DIAL) system participated in the Tropical Ozone Transport Experiment/Vortex Ozone Transport Experiment (TOTE/VOTE) in late 1995/early 1996. This mission afforded the opportunity to compare the DIAL system's stratospheric ozone measuring capability with other remote-sensing instruments through correlative measurements over a latitude range from the tropics to the Arctic. These instruments included ground-based DIAL and space-based stratospheric instruments: HALOE; MLS; and SAGE II. The ozone profiles generally agreed within random error estimates for the various instruments in the middle of the profiles in the tropics, but regions of significant systematic differences, especially near or below the tropopause or at the higher altitudes were also found. The comparisons strongly suggest that the airborne UV DIAL system can play a valuable role as a mobile lower-stratospheric ozone validation instrument.

Published
1998
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41. NDSC Lidar Intercomparisons and Validation: OPAL and MLO3 Campaigns in 1995

Author

McDermid, Stuart, McGee, Thomas J, and Stuart, Daan P. J

Abstract

The Network for the Detection of Stratospheric Change (NDSC) has developed and adopted a Validation Policy in order to ensure that the results submitted and stored in its archives are of a known, high quality. As a part of this validation policy, blind instrument intercomparisons are considered an essential element in the certification of NDSC instruments and a specific format for these campaigns has been recommended by the NDSC-Steering Committee.

Published
1996

42. Lidar measurements at Lauder, NZ

Author

McGee, Thomas J, Gross, Michael, Singh, Upendra, and Kimvilakani, Patrick

Subjects
Geophysics
Abstract

In March of 1994, the GSFC Stratospheric Ozone Lidar was deployed to the Network for the Detection of Stratospheric Change (NDSC) site at Lauder, NZ. This was in conjunction with a series of NASA ER-2 flights from Christchurch, NZ south to the Antarctic Circle. These flights were organized to study the chemistry of the stratosphere before, during and after the formation of the well-known 'ozone hole'. Lidar measurements were made at four different time periods corresponding to the times of the ER-2 flights. Lauder is situated nearly along the flight path as the aircraft flew south and so the lidar measurements provide a checkpoint for the ozone, aerosol and temperature instruments onboard the aircraft. Whenever the weather permitted, lidar measurements were made as near to dawn, prior to the flight, and as near to sunset, after the flight. This provided data as close to the aircraft transit time as possible. More than 70 individual lidar measurements were made, each consisting of a vertical profile of ozone, temperature, and aerosol. These were made over three different seasons and show seasonal variation. Of particular interest in the lidar data base is the wintertime stratospheric - mesospheric temperature profiles, which show large variations at the stratopause and also some significant wave activity.

Published
1995

43. Correlation of ozone loss with the presence of volcanic aerosols

Author

Mcgee, Thomas J, Newman, Paul, Gross, Michael, Singh, Upendra, Godin, Sophie, Lacoste, Anne-Marie, and Megie, Gerard

Subjects
Geophysics
Abstract

Statistically significant reductions of ozone compared to a climatological profile have been measured above the Observatoire de Haute Provence (OHP) in Southern France (43.9 deg N, 5.7 deg E) during the months of July and August, 1992. Lidar profiles of ozone, temperature and aerosols were recorded on 25 separate nights during that time. The change in the ozone profile is correlated with the presence of volcanic aerosols from the eruption of Mt. Pinatubo. The total ozone loss amounts to approximately a 10% reduction in the total ozone column over OHP.

Published
1994
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44. Raman DIAL measurements of stratospheric ozone in the presence of volcanic aerosols

Author

Mcgee, Thomas J, Gross, Michael, Ferrare, Richard, Heaps, William, and Singh, Upendra

Subjects
Meteorology And Climatology
Abstract

Since the eruption of Mt. Pinatubo in June, 1991, measurements of atmospheric species which depend on Rayleigh scattering of radiation, have been severely compromised where the volcanic aerosol cloud exists. For the GSFC stratospheric ozone lidar, this has meant that ozone determination has been impossible below approximately 30 km. The GSFC lidar has been modified to detect Raman scattering from nitrogen molecules from transmitted laser wavelengths. The instrument transmits two laser wavelengths at 308 nm and 351 nm, and detects returns at four wavelengths; 308 nm, 332 nm, 351 nm, and 382 nm. Using this technique in conjunction with the Rayleigh DIAL measurement, ozone profiles have been measured between 15 and 50 km.

Published
1993

45. Lidar Measurements of Stratospheric Ozone, Temperature and Aerosol During 1992 UARS Correlative Measurement Campaign

Author

Mcgee, Thomas J, Singh, Upendra N, Gross, Michael, Heaps, William S, and Ferrare, Richard

Subjects
Environment Pollution
Abstract

Measurements of stratospheric ozone, temperature, and aerosols were made by the NASA/GSFC mobile stratospheric lidar during the UARS (Upper Atmospheric Research Satellite) Correlative Measurement Campaign at the JPL-Table Mountain Facility in Feb. and Mar. 1992. Due to the presence of substantial amounts of residual volcanic aerosol from the eruption of Mt. Pinatubo, the GSFC lidar system was modified for an accurate measurement of ozone concentration in the stratosphere. While designed primarily for the measurement of stratospheric ozone, this lidar system was also used to measure middle atmosphere temperature and density from 30 to 65 km and stratospheric aerosol from 15 to 35 km. In the following sections, we will briefly describe and present some typical measurements made during this campaign. Stratospheric ozone, temperature, and aerosols profiles derived from data taken between 15 Feb. and 20 Mar., 1992 will be presented at the conference.

Published
1992

46. A New Raman DIAL Technique for Measuring Stratospheric Ozone in the Presence of Volcanic Aerosols

Author

Singh, Upendra N, Mcgee, Thomas J, Gross, Michael, Heaps, William S, and Ferrare, Richard

Subjects
Environment Pollution
Abstract

This paper describes a new lidar scheme to measure stratospheric ozone in the presence of heavy volcanic aerosol loading. The eruptions of the Philippine volcano Pinatubo during June 1991 ejected large amounts of sulfur dioxide into the atmosphere to altitudes of at least 30 km. The resulting aerosols have severely affected the measurements of stratospheric ozone when using traditional Rayleigh differential absorption lidar (DIAL) technique, in which the scattering mechanism is almost entirely Rayleigh and which assumes a small amount or no aerosols. In order to extract an ozone profile in the regions below about 30 km where the Rayleigh lidar returns are contaminated by aerosol scattering from Mt. Pinatubo cloud, we have used a Raman lidar technique, where the scattering mechanism depends solely on molecular nitrogen. In this scheme there is no aerosol scattering component to the backscattered lidar return. Using this technique in conjunction with the Rayleigh DIAL measurement, the GSFC stratospheric ozone lidar has measured ozone profiles between 15 and 50 km during the recently held UARS correlative measurement campaign (February-March 1992) at JPL's Table Mountain Facility in California.

Published
1992

47. Recent lidar measurements of stratospheric ozone and temperature within the network for the detection of stratospheric change

Author

Mcgee, Thomas J, Ferrare, Richard, Butler, James J, Frost, Robert L, Gross, Michael, and Margitan, James

Subjects
Instrumentation And Photography
Abstract

The Goddard mobile lidar was deployed at Cannon Air Force Base near Clovis, New Mexico during the Spring of 1990. Measurements of stratospheric ozone and temperature were made over a period of six weeks. Data from the lidar system is compared with data from a balloon-borne, ultraviolet instrument launched from nearby Ft. Sumner, New Mexico. Along with several improvements to this instrument which are now underway, a second lidar dedicated to temperature and aerosol measurements is now being developed.

Published
1991

48. STROZ LITE - Stratospheric Ozone Lidar Trailer Experiment

Author

Mcgee, Thomas J, Whiteman, David, Ferrare, Richard, Burris, John F, and Butler, James J

Subjects
Lasers And Masers
Abstract

A mobile dual-wavelength differential absorption lidar capable of making precise measurements of stratospheric ozone between 20 and 45 km has been developed at the Goddard Space Flight Center as part of the international Network for the Detection of Stratospheric Change. The system is installed in a 46-ft trailer, which enables the instrument to act as a network transfer standard and to be set up at any location where power can be obtained. A description of the instrument is presented, along with a discussion of the data analysis. Some results from an intercomparison held at JPL's Table Mountain Observatory in California during October and November 1988 are also presented.

Published
1991

49. Taehwa Research Forest: A receptor site for severe pollution events in Korea during 2016

Author

Sullivan, John T., primary, McGee, Thomas J., additional, Stauffer, Ryan M., additional, Thompson, Anne M., additional, Weinheimer, Andrew, additional, Knote, Christoph, additional, Janz, Scott, additional, Wisthaler, Armin, additional, Long, Russell, additional, Szykman, James, additional, Park, Jinsoo, additional, Lee, Youngjae, additional, Kim, Saewung, additional, Jeong, Daun, additional, Sanchez, Dianne, additional, Twigg, Laurence, additional, Sumnicht, Grant, additional, Knepp, Travis, additional, and Schroeder, Jason R., additional

Published
2019
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50. Evaluation of the New NDACC Ozone and Temperature Lidar at Hohenpeißenberg and Comparison of Results with Previous NDACC Campaigns.

Author

Wing, Robin, Godin-Beekmann, Sophie, Steinbrecht, Wolfgang, McGee, Thomas J., Sullivan, John T., Khaykin, Sergey, Sumnicht, Grant, and Twigg, Larry

Subjects
TROPOSPHERIC ozone, OZONE, LIDAR, METEOROLOGICAL stations, OZONESONDES, ATMOSPHERIC composition
Abstract

A newly upgraded German Weather Service (DWD) ozone and temperature lidar (HOH) located at the Hohenpeißenberg Meteorological Observatory (47.8° N, 11.0° E) has been evaluated through comparison with the travelling standard lidar operated by NASA's Goddard Space Flight Center (NASA STROZ), satellite overpasses from the Microwave Limb Sounder (MLS), the Sounding of the Atmosphere using Broadband Emission Radiometry (SABER), the Ozone Mapping and Profiler Suite (OMPS), meteorological radiosondes launched from München (65 km north-east), and locally launched ozonesondes. The blind evaluation was conducted under the framework of the Network for the Detection of Atmospheric Composition Change (NDACC) using 10 clear nights of measurements in 2018 and 2019. This campaign was conducted within the larger context of NDACC validation activities for European lidar stations. The previous 2017-2018 validation campaign took place at the French Observatoire de Haute Provence and and showed a high degree of fidelity between participating instruments. The results are reported in the companion article (Wing et al., 2020). There was good agreement between all ozone lidar measurements in the range of 15 to 41 km with relative differences between co-located ozone profiles of less than ±;10 %. Differences in the measured ozone numbers densities between the lidars and the locally launched ozone sondes were also generally less than 5 % below 30 km. The satellite ozone profiles demonstrated some differences with respect to the ground based lidars which are due to sampling differences and geophysical variation. Temperatures differences for all instruments were less than ±;5 K below 60 km, with larger differences present in the lidar-satellite comparisons above this region. Temperature differences between the lidars met the NDACC accuracy requirements of ±;1 K between 17 and 78 km. The NASA lidar exhibited slightly colder temperatures, between 5 and 10 K, than the other instruments below 20 km and slightly warmer temperatures, 5 to 10 K, above 70 km. These differences are likely due to algorithm initialisation choices and photon count saturation corrections. [ABSTRACT FROM AUTHOR]

Published
2020
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