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1. Limb Temperature Observations in the Stratosphere and Mesosphere Derived from the OMPS Sensor.

Author

Da Costa Louro, Pedro, Keckhut, Philippe, Hauchecorne, Alain, Meftah, Mustapha, Jaross, Glen, and Mangin, Antoine

Subjects
ATMOSPHERIC temperature, MIDDLE atmosphere, RAYLEIGH scattering, RADIATIVE transfer, STRATOSPHERE
Abstract

Molecular scattering (Rayleigh scattering) has been extensively used from the ground with lidars and from space to observe the limb, thereby deriving vertical temperature profiles between 30 and 80 km. In this study, we investigate how temperature can be measured using the new Ozone Mapping and Profiler Suite (OMPS) sensor, aboard the Suomi NPP and NOAA-21 satellites. The OMPS consists of three instruments whose main purpose is to study the composition of the stratosphere. One of these, the Limb Profiler (LP), measures the radiance of the limb of the middle atmosphere (stratosphere and mesosphere, 12 to 90 km altitude) at wavelengths from 290 to 1020 nm. This new data set has been used with a New Simplified Radiative Transfer Model (NSRTM) to derive temperature profiles with a vertical resolution of 1 km. To validate the method, the OMPS-derived temperature profiles were compared with data from four ground-based lidars and the ERA5 and MSIS models. The results show that OMPS and the lidars are in agreement within a range of about 5 K from 30 to 80 km. Comparisons with the models also show similar results, except for ERA5 beyond 50 km. We investigated various sources of bias, such as different attenuation sources, which can produce errors of up to 120 K in the UV range, instrumental errors around 0.8 K and noise problems of up to 150 K in the visible range for OMPS. This study also highlighted the interest in developing a new miniaturised instrument that could provide real-time observation of atmospheric vertical temperature profiles using a constellation of CubeSats with our NSRTM. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Decade-long Ozone Profile Record from Suomi NPP OMPS Limb Profiler: Assessment of Version 2.6 Data

Author

Kramarova, Natalya A, primary, Xu, Philippe, additional, Mok, Jungbin, additional, Bhartia, Pawan, additional, Jaross, Glen, additional, Moy, Leslie, additional, Chen, Zhong, additional, Frith, Stacey M, additional, DeLand, Matthew Todd, additional, Kahn, Daniel, additional, Labow, Gordon Jay, additional, Li, Jason, additional, Nyaku, Ernest, additional, Weaver, Clark, additional, Ziemke, Jerald R., additional, Davis, Sean M., additional, and Jia, Yue, additional

Published
2024
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3. New Era of Air Quality Monitoring from Space : Geostationary Environment Monitoring Spectrometer (GEMS)

Author

Kim, Jhoon, Jeong, Ukkyo, Ahn, Myoung-Hwan, Kim, Jae H., Park, Rokjin J., Lee, Hanlim, Song, Chul Han, Choi, Yong-Sang, Lee, Kwon-Ho, Yoo, Jung-Moon, Jeong, Myeong-Jae, Park, Seon Ki, Lee, Kwang-Mog, Song, Chang-Keun, Kim, Sang-Woo, Kim, Young Joon, Kim, Si-Wan, Kim, Mijin, Go, Sujung, Liu, Xiong, Chance, Kelly, Miller, Christopher Chan, Al-Saadi, Jay, Veihelmann, Ben, Bhartia, Pawan K., Torres, Omar, Abad, Gonzalo González, Haffner, David P., Ko, Dai Ho, Lee, Seung Hoon, Woo, Jung-Hun, Chong, Heesung, Park, Sang Seo, Nicks, Dennis, Choi, Won Jun, Moon, Kyung-Jung, Cho, Ara, Yoon, Jongmin, Kim, Sang-kyun, Hong, Hyunkee, Lee, Kyunghwa, Lee, Hana, Lee, Seoyoung, Choi, Myungje, Veefkind, Pepijn, Levelt, Pieternel F., Edwards, David P., Kang, Mina, Eo, Mijin, Bak, Juseon, Baek, Kanghyun, Kwon, Hyeong-Ahn, Yang, Jiwon, Park, Junsung, Han, Kyung Man, Kim, Bo-Ram, Shin, Hee-Woo, Choi, Haklim, Lee, Ebony, Chong, Jihyo, Cha, Yesol, Koo, Ja-Ho, Irie, Hitoshi, Hayashida, Sachiko, Kasai, Yasko, Kanaya, Yugo, Liu, Cheng, Lin, Jintai, Crawford, James H., Carmichael, Gregory R., Newchurch, Michael J., Lefer, Barry L., Herman, Jay R., Swap, Robert J., Lau, Alexis K. H., Kurosu, Thomas P., Jaross, Glen, Ahlers, Berit, Dobber, Marcel, McElroy, C. Thomas, and Choi, Yunsoo

Published
2020

4. Global retrieval of stratospheric and tropospheric BrO columns from the Ozone Mapping and Profiler Suite Nadir Mapper (OMPS-NM) on board the Suomi-NPP satellite.

Author

Chong, Heesung, González Abad, Gonzalo, Nowlan, Caroline R., Chan Miller, Christopher, Saiz-Lopez, Alfonso, Fernandez, Rafael P., Kwon, Hyeong-Ahn, Ayazpour, Zolal, Wang, Huiqun, Souri, Amir H., Liu, Xiong, Chance, Kelly, O'Sullivan, Ewan, Kim, Jhoon, Koo, Ja-Ho, Simpson, William R., Hendrick, François, Querel, Richard, Jaross, Glen, and Seftor, Colin

Subjects
OZONE layer, OZONE, ULTRAVIOLET spectrometers, AIR masses, SALT lakes, BROMINE
Abstract

Quantifying the global bromine monoxide (BrO) budget is essential to understand ozone chemistry better. In particular, the tropospheric BrO budget has not been well characterized. Here, we retrieve nearly a decade (February 2012–July 2021) of stratospheric and tropospheric BrO vertical columns from the Ozone Mapping and Profiling Suite Nadir Mapper (OMPS-NM) on board the Suomi National Polar-orbiting Partnership (Suomi-NPP) satellite. In quantifying tropospheric BrO enhancements from total slant columns, the key aspects involve segregating them from stratospheric enhancements and applying appropriate air mass factors. To address this concern and improve upon the existing methods, our study proposes an approach that applies distinct BrO vertical profiles based on the presence or absence of tropospheric BrO enhancement at each pixel, identifying it dynamically using a satellite-derived stratospheric-ozone–BrO relationship. We demonstrate good agreement for both stratosphere (r = 0.81–0.83) and troposphere (r = 0.50–0.70) by comparing monthly mean BrO vertical columns from OMPS-NM with ground-based observations from three stations (Lauder, Utqiaġvik, and Harestua). Although algorithm performance is primarily assessed at high latitudes, the OMPS-NM BrO retrievals successfully capture tropospheric enhancements not only in polar regions but also in extrapolar areas, such as the Rann of Kutch and the Great Salt Lake. We also estimate random uncertainties in the retrievals pixel by pixel, which can assist in quantitative applications of the OMPS-NM BrO dataset. Our BrO retrieval algorithm is designed for cross-sensor applications and can be adapted to other space-borne ultraviolet spectrometers, contributing to the creation of continuous long-term satellite BrO observation records. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Global retrieval of stratospheric and tropospheric BrO columns from OMPS-NM onboard the Suomi-NPP satellite

Author

Chong, Heesung, González Abad, Gonzalo, Nowlan, Caroline R., Chan Miller, Christopher, Saiz-Lopez, Alfonso, Fernandez, Rafael P., Kwon, Hyeong-Ahn, Ayazpour, Zolal, Wang, Huiqun, Souri, Amir H., Liu, Xiong, Chance, Kelly, O’Sullivan, Ewan, Kim, Jhoon, Koo, Ja-Ho, Simpson, William R., Hendrick, François, Querel, Richard, Jaross, Glen, Seftor, Colin, and Suleiman, Raid M.

Abstract

Quantifying the global bromine monoxide (BrO) budget is essential to understand ozone chemistry better. In particular, the tropospheric BrO budget has not been well characterized. Here, we retrieve nearly a decade (February 2012–July 2021) of stratospheric and tropospheric BrO vertical columns from the Ozone Mapping and Profiling Suite Nadir Mapper (OMPS-NM) onboard the Suomi National Polar-orbiting Partnership (Suomi-NPP) satellite. To address the mismatch between a priori profiles and column retrievals in the stratosphere-troposphere separation, for each OMPS-NM pixel, we save two types of BrO vertical profiles and use the appropriate one based on whether a tropospheric enhancement is detected. Total ozone columns observed from OMPS-NM are used to identify tropospheric BrO enhancements. We demonstrate good agreement for both the stratosphere (r = 0.81–0.83) and the troposphere (r = 0.50–0.69) by comparing monthly mean BrO vertical columns from OMPS-NM with ground-based observations from three stations (Lauder, Utqiag ̇vik, and Harestua). The OMPS-NM BrO retrievals successfully capture tropospheric enhancements not only in the polar but also in the extrapolar regions (the Rann of Kutch and the Great Salt Lake). We also estimate random uncertainties in the retrievals pixel by pixel, which can assist in quantitative applications of the OMPS-NM BrO dataset. Our BrO retrieval algorithm is designed for cross-sensor applications and can be adapted to other space-borne ultraviolet spectrometers, contributing to the creation of continuous long-term satellite BrO observation records.

Published
2023

6. Global Formaldehyde Products From the Ozone Mapping and Profiler Suite (OMPS) Nadir Mappers on Suomi NPP and NOAA‐20

Author

Nowlan, Caroline R., primary, González Abad, Gonzalo, additional, Kwon, Hyeong‐Ahn, additional, Ayazpour, Zolal, additional, Chan Miller, Christopher, additional, Chance, Kelly, additional, Chong, Heesung, additional, Liu, Xiong, additional, O’Sullivan, Ewan, additional, Wang, Huiqun, additional, Zhu, Lei, additional, De Smedt, Isabelle, additional, Jaross, Glen, additional, Seftor, Colin, additional, and Sun, Kang, additional

Published
2023
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8. Trends in Global Tropospheric Ozone Inferred from a Composite Record of TOMS/OMI/MLS/OMPS Satellite Measurements and the MERRA-2 GMI Simulation

Author

Ziemke, Jerald R, Oman, Luke D, Strode, Sarah A, Douglass, Anne R, Olsen, Mark A, McPeters, Richard D, Bhartia, Pawan K, Froidevaux, Lucien, Labow, Gordon J, Witte, Jacquie C, Thompson, Anne M, Haffner, David P, Kramarova, Natalya A, Frith, Stacey M, Huang, Liang-Kang, Jaross, Glen R, Seftor, Colin J, Deland, Mathew T, and Taylor, Steven L

Subjects
Earth Resources And Remote Sensing, Geophysics
Abstract

Past studies have suggested that ozone in the troposphere has increased globally throughout much of the 20th century due to increases in anthropogenic emissions and transport. We show, by combining satellite measurements with a chemical transport model, that during the last four decades tropospheric ozone does indeed indicate increases that are global in nature, yet still highly regional. Satellite ozone measurements from Nimbus-7 and Earth Probe Total Ozone Mapping Spectrometer (TOMS) are merged with ozone measurements from the Aura Ozone Monitoring Instrument/Microwave Limb Sounder (OMI/MLS) to determine trends in tropospheric ozone for 1979–2016. Both TOMS (1979–2005) and OMI/MLS (2005–2016) depict large increases in tropospheric ozone from the Near East to India and East Asia and further eastward over the Pacific Ocean. The 38-year merged satellite record shows total net change over this region of about +6 to +7 Dobson units (DU) (i.e., ∼15 %–20 % of average background ozone), with the largest increase (∼4 DU) occurring during the 2005–2016 Aura period. The Global Modeling Initiative (GMI) chemical transport model with time-varying emissions is used to aid in the interpretation of tropospheric ozone trends for 1980–2016. The GMI simulation for the combined record also depicts the greatest increases of +6 to +7 DU over India and East Asia, very similar to the satellite measurements. In regions of significant increases in tropospheric column ozone (TCO) the trends are a factor of 2–2.5 larger for the Aura record when compared to the earlier TOMS record; for India and East Asia the trends in TCO for both GMI and satellite measurements are ∼+3 DU decade(exp −1) or greater during 2005–2016 compared to about +1.2 to +1.4 DU decade(exp −1) for 1979–2005. The GMI simulation and satellite data also reveal a tropospheric ozone increases in ∼+4 to +5 DU for the 38-year record over central Africa and the tropical Atlantic Ocean. Both the GMI simulation and satellite-measured tropospheric ozone during the latter Aura time period show increases of ∼+3 DU decade−1 over the N Atlantic and NE Pacific.

Published
2019
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9. Global Formaldehyde Products from the Ozone Mapping and Profiler Suite (OMPS) Nadir Mappers on Suomi NPP and NOAA-20

Author

Nowlan, Caroline R., primary, González Abad, Gonzalo, additional, Kwon, Hyeong-Ahn, additional, Ayazpour, Zolal, additional, Chan Miller, Christopher, additional, Chance, Kelly, additional, Chong, Heesung, additional, Liu, Xiong, additional, O'Sullivan, Ewan, additional, Wang, Huiqun, additional, Zhu, Lei, additional, De Smedt, Isabelle, additional, Jaross, Glen, additional, Seftor, Colin, additional, and Sun, Kang, additional

Published
2022
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10. Validation of Ozone Profile Retrievals Derived from the OMPS LP Version 2.5 Algorithm Against Correlative Satellite Measurements

Author

Kramarova, Natalya A, Bhartia, Pawan K, Jaross, Glen, Moy, Leslie, Xu, Philippe, Chen, Zhong, DeLand, Matthew, Froidevaux, Lucien, Livesey, Nathaniel, Degenstein, Douglas, Bourassa, Adam, Walker, Kaley A, and Sheese, Patrick

Subjects
Geosciences (General)
Abstract

The Limb Profiler (LP) is a part of the Ozone Mapping and Profiler Suite launched on board of the Suomi NPP satellite in October 2011. The LP measures solar radiation scattered from the atmospheric limb in ultraviolet and visible spectral ranges between the surface and 80 km. These measurements of scattered solar radiances allow for the retrieval of ozone profiles from cloud tops up to 55 km. The LP started operational observations in April 2012. In this study we evaluate more than 5.5 years of ozone profile measurements from the OMPS LP processed with the new NASA GSFC version 2.5 retrieval algorithm. We provide a brief description of the key changes that had been implemented in this new algorithm, including a pointing correction, new cloud height detection, explicit aerosol correction and a reduction of the number of wavelengths used in the retrievals. The OMPS LP ozone retrievals have been compared with independent satellite profile measurements obtained from the Aura Microwave Limb Sounder (MLS), Atmospheric Chemistry Experiment Fourier Transform Spectrometer (ACE-FTS) and Odin Optical Spectrograph and InfraRed Imaging System (OSIRIS). We document observed biases and seasonal differences and evaluate the stability of the version 2.5 ozone record over 5.5 years. Our analysis indicates that the mean differences between LP and correlative measurements are well within required +/- 10% between 18 and 42 km. In the upper stratosphere and lower mesosphere (>43 km) LP tends to have a negative bias. We find larger biases in the lower stratosphere and upper troposphere, but LP ozone retrievals have significantly improved in version 2.5 compared to version 2 due to the implemented aerosol correction. In the northern high latitudes we observe larger biases between 20 and 32 km due to the remaining thermal sensitivity issue. Our analysis shows that LP ozone retrievals agree well with the correlative satellite observations in characterizing vertical, spatial and temporal ozone distribution associated with natural processes, like the seasonal cycle and quasi-biennial oscillations. We found a small positive drift approx. 0.5%/yr in the LP ozone record against MLS and OSIRIS that is more pronounced at altitudes above 35 km. This pattern in the relative drift is consistent with a possible 100m drift in the LP sensor pointing detected by one of our altitude-resolving methods.

Published
2018
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11. Ozone Monitoring Instrument (OMI) collection 4: establishing a 17-year-long series of detrended level-1b data

Author

Kleipool, Quintus, primary, Rozemeijer, Nico, additional, van Hoek, Mirna, additional, Leloux, Jonatan, additional, Loots, Erwin, additional, Ludewig, Antje, additional, van der Plas, Emiel, additional, Adrichem, Daley, additional, Harel, Raoul, additional, Spronk, Simon, additional, ter Linden, Mark, additional, Jaross, Glen, additional, Haffner, David, additional, Veefkind, Pepijn, additional, and Levelt, Pieternel F., additional

Published
2022
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12. Ozone Monitoring Instrument (OMI) collection 4: Establishing a 17-year-long series of detrended level-1b data

Author

Kleipool, Quintus (author), Rozemeijer, Nico (author), Leloux, Jonatan (author), Loots, Erwin (author), Ludewig, Antje (author), Adrichem, Daley (author), Ter Linden, Mark (author), Jaross, Glen (author), Levelt, Pieternel Felicitas (author), Kleipool, Quintus (author), Rozemeijer, Nico (author), Leloux, Jonatan (author), Loots, Erwin (author), Ludewig, Antje (author), Adrichem, Daley (author), Ter Linden, Mark (author), Jaross, Glen (author), and Levelt, Pieternel Felicitas (author)

Abstract

The Ozone Monitoring Instrument (OMI) was launched on 15 July 2004, with an expected mission lifetime of 5 years. After more than 17 years in orbit the instrument is still functioning satisfactorily and in principle can continue doing so until the expected decommissioning of its platform Aura in 2025. In order to continue the datasets acquired by OMI and the Microwave Limb Sounder, the mission was extended up to at least 2023. Actions have been taken to ensure the proper functioning of the OMI operations, the data processing, and the calibration monitoring system until the eventual end of the mission. For the data processing a new level-0 (L0) to level-1b (L1b) data processor was built based on the recent developments for the TROPOspheric Monitoring Instrument (TROPOMI). With corrections for the degradation of the instrument now included, it is feasible to generate a new data collection to supersede the current collection-3 data products and reprocess the data of the entire mission up to now. This paper describes the differences between the collection-3 and collection-4 data. It will be shown that the collection-4 L1b data comprise a clear improvement with respect to the previous collections. By correcting for the gentle optical and electronic aging that has occurred over the past 17 years, OMI's ability to make trend-quality ozone measurements has further improved., Atmospheric Remote Sensing

Published
2022
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15. In-Flight Performance of the Ozone Monitoring Instrument

Author

Schenkeveld, V.M. Erik, Jaross, Glen, Marchenko, Sergey, Haffner, David, Kleipool, Quintus L, Rozemeijer, Nico C, Veefkind, J. Pepijn, and Levelt, Pieternel F

Subjects
Instrumentation And Photography, Statistics And Probability, Earth Resources And Remote Sensing
Abstract

The Dutch-Finnish Ozone Monitoring Instrument (OMI) is an imaging spectrograph flying on NASA's EOS Aura satellite since 15 July 2004. OMI is primarily used to map trace-gas concentrations in the Earth's atmosphere, obtaining mid-resolution (0.4-0.6 nm) ultraviolet-visible (UV- VIS; 264-504 nm) spectra at multiple (30-60) simultaneous fields of view. Assessed via various approaches that include monitoring of radiances from selected ocean, land ice and cloud areas, as well as measurements of line profiles in the solar spectra, the instrument shows low optical degradation and high wavelength stability over the mission lifetime. In the regions relatively free from the slowly unraveling "row anomaly" (RA) the OMI irradiances have degraded by 3- 8 %, while radiances have changed by 1-2 %. The long-term wavelength calibration of the instrument remains stable to 0.005-0.020 nm.

Published
2017
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16. Altitude Registration of Limb-Scattered Radiation

Author

Moy, Leslie, Bhartia, Pawan K, Jaross, Glen, Loughman, Robert, Kramarova, Natalya, Chen, Zhong, Taha, Ghassan, Chen, Grace, and Xu, Philippe

Subjects
Earth Resources And Remote Sensing
Abstract

One of the largest constraints to the retrieval of accurate ozone profiles from UV backscatter limb sounding sensors is altitude registration. Two methods, the Rayleigh scattering attitude sensing (RSAS) and absolute radiance residual method (ARRM), are able to determine altitude registration to the accuracy necessary for long-term ozone monitoring. The methods compare model calculations of radiances to measured radiances and are independent of onboard tracking devices. RSAS determines absolute altitude errors, but, because the method is susceptible to aerosol interference, it is limited to latitudes and time periods with minimal aerosol contamination. ARRM, a new technique introduced in this paper, can be applied across all seasons and altitudes. However, it is only appropriate for relative altitude error estimates. The application of RSAS to Limb Profiler (LP) measurements from the Ozone Mapping and Profiler Suite (OMPS) on board the Suomi NPP (SNPP) satellite indicates tangent height (TH) errors greater than 1 km with an absolute accuracy of +/-200 m. Results using ARRM indicate a approx. 300 to 400m intra-orbital TH change varying seasonally +/-100 m, likely due to either errors in the spacecraft pointing or in the geopotential height (GPH) data that we use in our analysis. ARRM shows a change of approx. 200m over 5 years with a relative accuracy (a long-term accuracy) of 100m outside the polar regions.

Published
2017
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19. Supplementary material to "OMI Collection 4: establishing a 17-year long series of detrended L1b data"

Author

Kleipool, Quintus, primary, Rozemeijer, Nico, additional, van Hoek, Mirna, additional, Leloux, Jonatan, additional, Loots, Erwin, additional, Ludewig, Antje, additional, van der Plas, Emiel, additional, Adrichem, Daley, additional, Harel, Raoul, additional, Spronk, Simon, additional, ter Linden, Mark, additional, Jaross, Glen, additional, Haffner, David, additional, Veefkind, Pepijn, additional, and Levelt, Pieternel, additional

Published
2022
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20. OMI Collection 4: establishing a 17-year long series of detrended L1b data

Author

Kleipool, Quintus, primary, Rozemeijer, Nico, additional, van Hoek, Mirna, additional, Leloux, Jonatan, additional, Loots, Erwin, additional, Ludewig, Antje, additional, van der Plas, Emiel, additional, Adrichem, Daley, additional, Harel, Raoul, additional, Spronk, Simon, additional, ter Linden, Mark, additional, Jaross, Glen, additional, Haffner, David, additional, Veefkind, Pepijn, additional, and Levelt, Pieternel, additional

Published
2022
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22. Release 2 data products from the Ozone Mapping and Profiler Suite (OMPS) Limb Profiler

Author

Xu, Q. Philippe, Bhartia, Pawan K, Jaross, Glen R, Deland, Matthew T, Larsen, Jack C, Fleig, Albert, Kahn, Daniel, Zhu, Tong, Chen, Zhong, Gorkavyi, Nick, Warner, Jeremy, Linda, Mike, Chen, Hong, Kowitt, Mark, Haken, Michael, and Hall, Peter

Subjects
Earth Resources And Remote Sensing
Abstract

The OMPS Limb Profiler (LP) was launched on board the NASA Suomi National Polar-orbiting Partnership (SNPP) satellite in October 2011. OMPS-LP is a limb-scattering hyperspectral sensor that provides ozone profiling capability at 1.5 km vertical resolution from cloud top to 60 km altitude. The use of three parallel slits allows global coverage in approximately four days. We have recently completed a full reprocessing of all LP data products, designated as Release 2, that improves the accuracy and quality of these products. Level 1 gridded radiance (L1G) changes include intra-orbit and seasonal correction of variations in wavelength registration, revised static and intra-orbit tangent height adjustments, and simplified pixel selection from multiple images. Ozone profile retrieval changes include removal of the explicit aerosol correction, exclusion of channels contaminated by stratospheric OH emission, a revised instrument noise characterization, improved synthetic solar spectrum, improved pressure and temperature ancillary data, and a revised ozone climatology. Release 2 data products also include aerosol extinction coefficient profiles derived with the prelaunch retrieval algorithm. Our evaluation of OMPS LP Release 2 data quality is good. Zonal average ozone profile comparisons with Aura MLS data typically show good agreement, within 5-10% over the altitude range 20-50 km between 60 deg S and 60 deg N. The aerosol profiles agree well with concurrent satellite measurements such as CALIPSO and OSIRIS, and clearly detect exceptional events such as volcanic eruptions and the Chelyabinsk bolide in February 2013.

Published
2014

23. Evaluation of the Sensor Data Record from the Nadir Instruments of the Ozone Mapping Profiler Suite (OMPS)

Author

Wu, Xiangqian, Liu, Quanhua, Zeng, Jian, Grotenhuis, Michael, Qian, Haifeng, Caponi, Maria, Flynn, Larry, Jaross, Glen, Sen, Bhaswar, Buss, Richard H., Jr, Johnsen, William, Janz, Scott, Pan, Chunhui, Niu, Jianguo, Beck, Trevor, Beach, Eric, Yu, Wei, Raja, M. K. Rama Varma, Stuhmer, Derek, Cumpton, Daniel, Owen, Cristina, and Li, Wen-Hao

Subjects
Earth Resources And Remote Sensing
Abstract

This paper evaluates the first 15 months of the Ozone Mapping and Profiler Suite (OMPS) Sensor Data Record (SDR) acquired by the nadir sensors and processed by the National Oceanic and Atmospheric Administration Interface Data Processing Segment. The evaluation consists of an inter-comparison with a similar satellite instrument, an analysis using a radiative transfer model, and an assessment of product stability. This is in addition to the evaluation of sensor calibration and the Environment Data Record product that are also reported in this Special Issue. All these are parts of synergetic effort to provide comprehensive assessment at every level of the products to ensure its quality. It is found that the OMPS nadir SDR quality is satisfactory for the current Provisional maturity. Methods used in the evaluation are being further refined, developed, and expanded, in collaboration with international community through the Global Space-based Inter-Calibration System, to support the upcoming long-term monitoring.

Published
2014
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24. OMPS Limb Profiler Instrument Performance Assessment

Author

Jaross, Glen R, Bhartia, Pawan K, Chen, Grace, Kowitt, Mark, Haken, Michael, Chen, Zhong, Xu, Philippe, Warner, Jeremy, and Kelly, Thomas

Subjects
Geophysics
Abstract

Following the successful launch of the Ozone Mapping and Profiler Suite (OMPS) aboard the Suomi National Polar-orbiting Partnership (SNPP) spacecraft, the NASA OMPS Limb team began an evaluation of instrument and data product performance. The focus of this paper is the instrument performance in relation to the original design criteria. Performance that is closer to expectations increases the likelihood that limb scatter measurements by SNPP OMPS and successor instruments can form the basis for accurate long-term monitoring of ozone vertical profiles. The team finds that the Limb instrument operates mostly as designed and basic performance meets or exceeds the original design criteria. Internally scattered stray light and sensor pointing knowledge are two design challenges with the potential to seriously degrade performance. A thorough prelaunch characterization of stray light supports software corrections that are accurate to within 1% in radiances up to 60 km for the wavelengths used in deriving ozone. Residual stray light errors at 1000nm, which is useful in retrievals of stratospheric aerosols, currently exceed 10%. Height registration errors in the range of 1 km to 2 km have been observed that cannot be fully explained by known error sources. An unexpected thermal sensitivity of the sensor also causes wavelengths and pointing to shift each orbit in the northern hemisphere. Spectral shifts of as much as 0.5nm in the ultraviolet and 5 nm in the visible, and up to 0.3 km shifts in registered height, must be corrected in ground processing.

Published
2014
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25. Ozone Monitoring Instrument calibration

Author

Dobber, Marcel R., Dirksen, Ruud J., Levelt, Pieternel F., van den Oord, G.H.J., Voors, Robert H.M., Kleipool, Quintus, Jaross, Glen, Kowalewski, Matthew, Hilsenrath, Ernest, Leppelmeier, Gilbert W., de Vries, Johan Dierssen, Werner, and Rozemeijer, Nico C.

Subjects
Charge coupled devices -- Usage, Calibration -- Analysis, Remote sensing -- Analysis, Ultraviolet spectroscopy -- Properties, Business, Earth sciences, Electronics and electrical industries
Abstract

The Ozone Monitoring Instrument (OMI) was launched on July 15, 2004 on the National Aeronautics and Space Administration's Earth Observing System Aura satellite. The OMI instrument is an ultraviolet-visible imaging spectrograph that uses two-dimensional charge-coupled device detectors to register both the spectrum and the swath perpendicular to the flight direction with a 115[degrees] wide swath, which enables global daily ground coverage with high spatial resolution. This paper presents the OMI design and discusses the main performance and calibration features and results. Index Terms--Calibration, charge coupled device (CCD), remote sensing, ultraviolet spectroscopy.

Published
2006

31. TOMS/ADEOS instrument characterization

Author

Krueger, Arlin J. and Jaross, Glen

Subjects
Advanced Earth Observing Satellite (Artificial satellite) -- Research, Scientific satellites -- Equipment and supplies, Atmospheric ozone -- Measurement, Artificial satellites in remote sensing -- Research, Spectrometer -- Calibration, Business, Earth sciences, Electronics and electrical industries
Abstract

Data sets from the total ozone mapping spectrometer (TOMS) on the ADEOS I spacecraft have been processed using initial and time-dependent instrument characterizations. Initial characterizations, performed on the ground, focused on wavelength registration of the six near-UV TOMS channels and on the instrument albedo calibration. Few calibration adjustments were required in the postlaunch phase. Instrument performance, including bandpass wavelengths, were stable throughout the life of the instrument. Indirect evidence exists for small changes in the reflectance of the primary solar diffuser. Characterizations used in data processing assume no change. No ozone retrieval errors are expected due to this assumption. All totaled, estimated calibration uncertainties represent less than 1% in total column ozone uncertainty. A comparison between two TOMS instruments is marginally consistent with these estimates. However, a comparison with ground measurements resulted in differences exceeding 1%. Index Terms - Atmospheric measurements, ozone, remote sensing, UV calibration, wavelength calibration.

Published
1999

32. OMI Collection 4: establishing a 17-year long series of detrended L1b data.

Author

Kleipool, Quintus, Rozemeijer, Nico, Hoek, Mirna van, Leloux, Jonatan, Loots, Erwin, Ludewig, Antje, Plas, Emiel van der, Adrichem, Daley, Harel, Raoul, Spronk, Simon, Linden, Mark ter, Jaross, Glen, Haffner, David, Veefkind, Pepijn, and Levelt, Pieternel

Subjects
COLLECTIONS, ACQUISITION of data, ELECTRONIC data processing, OZONE
Abstract

The Ozone Monitoring Instrument (OMI) was launched on July 15, 2004, with an expected mission lifetime of 5 years. After more than 17 years in orbit the instrument is still functioning satisfactorily, and in principle can continue doing so for many years more. In order to continue the datasets acquired by OMI and the Microwave Limb Sounder the mission was extended up to at least 2023. Actions have been taken to ensure the proper functioning of the OMI instrument operations, the data processing, and the calibration monitoring system until the eventual end of the mission. For the data processing a new level 0 to level 1b data processor was built based on the recent developments for Tropospheric Monitoring Instrument (TROPOMI). With corrections for the degradation of the instrument now included, it is feasible to generate a new data collection to supersede the current collection 3 data products. This paper describes the differences between the collection 3 and collection 4 data. It will be shown that the collection 4 L1b data is a clear improvement with respect to the previous collections. By correcting for the gentle optical and electronic aging that has occurred over the past 17 years, OMI's ability to make trend-quality ozone measurements has further improved. [ABSTRACT FROM AUTHOR]

Published
2022
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33. Development of Long-term Datasets from Satellite BUV Instruments: The 'Soft' Calibration Approach

Author

Bhartia, Pawan K, Taylor, Steven, and Jaross, Glen

Subjects
Spacecraft Instrumentation And Astrionics
Abstract

The first BUV instrument was launched in April 1970 on NASA's Nimbus4 satellite. More than a dozen instruments, broadly based on the same principle, but using very different technologies, have been launched in the last 35 years on NASA, NOAA, Japanese and European satellites. In this paper we describe the basic principles of the "soft" calibration approach that we have successfully applied to the data from many of these instruments to produce a consistent long-term record of total ozone, ozone profile and aerosols. This approach is based on using accurate radiative transfer models and assumed/known properties of the atmosphere in ultraviolet to derive calibration parameters. Although the accuracy of the results inevitably depends upon how well the assumed atmospheric properties are known, the technique has several built-in cross- checks that improve the robustness of the method. To develop further confidence in the data the soft calibration technique can be combined with data collected from few well- calibrated ground-based instruments. We will use examples from past and present BUV instruments to show how the method works.

Published
2005

34. Reflectance-Based Sensor Validation Over Ice Surfaces

Author

Jaross, Glen and Dodge, James C

Subjects
Earth Resources And Remote Sensing
Abstract

During this period work was performed in the following areas. These areas are defined in the Work Schedule presented in the original proposal: BRDF development, Data acquisition and processing, THR Table generation and Presentations and Publications. BRDF development involves creating and/or modifying a reflectance model of the Antarctic surface. This model must, for a temporal and spatial average, be representative of the East Antarctic plateau and be expressed in terms of the three standard surface angles: solar zenith angle (SolZA), view zenith angle (SatZA), and relative azimuth angle (RelAZ). We successfully acquired a limited amount of NOAA-9 AVHRR data for radiance validation. The data were obtained from the Laboratory for Terrestrial Physics at Goddard Space Flight Center. We developed our own reading and unpacking software, which we used to select Channel 1 data (visible). We then applied geographic subsetting criteria (same as used for TOMS), and wrote only the relevant data to packed binary files. We proceeded with analysis of these data, which is not yet complete.

Published
2003

36. Supplementary material to "Trends in Global Tropospheric Ozone Inferred from a Composite Record of TOMS/OMI/MLS/OMPS Satellite Measurements and the MERRA-2 GMI Simulation"

Author

Ziemke, Jerry R., primary, Oman, Luke D., additional, Strode, Sarah A., additional, Douglass, Anne R., additional, Olsen, Mark A., additional, McPeters, Richard D., additional, Bhartia, Pawan K., additional, Froidevaux, Lucien, additional, Labow, Gordon J., additional, Witte, Jacquie C., additional, Thompson, Anne M., additional, Haffner, David P., additional, Kramarova, Natalya A., additional, Frith, Stacey M., additional, Huang, Liang-Kang, additional, Jaross, Glen R., additional, Seftor, Colin J., additional, Deland, Mathew T., additional, and Taylor, Steven L., additional

Published
2018
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37. Trends in Global Tropospheric Ozone Inferred from a Composite Record of TOMS/OMI/MLS/OMPS Satellite Measurements and the MERRA-2 GMI Simulation

Author

Ziemke, Jerry R., primary, Oman, Luke D., additional, Strode, Sarah A., additional, Douglass, Anne R., additional, Olsen, Mark A., additional, McPeters, Richard D., additional, Bhartia, Pawan K., additional, Froidevaux, Lucien, additional, Labow, Gordon J., additional, Witte, Jacquie C., additional, Thompson, Anne M., additional, Haffner, David P., additional, Kramarova, Natalya A., additional, Frith, Stacey M., additional, Huang, Liang-Kang, additional, Jaross, Glen R., additional, Seftor, Colin J., additional, Deland, Mathew T., additional, and Taylor, Steven L., additional

Published
2018
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38. Nimbus-7 Total Ozone Mapping Spectrometer (TOMS) Data Products User's Guide

Author

McPeters, Richard D, Bhartia, P. K, Krueger, Arlin J, Herman, Jay R, Schlesinger, Barry M, Wellemeyer, Charles G, Seftor, Colin J, Jaross, Glen, Taylor, Steven L, Swissler, Tom, Torres, Omar, Labow, Gordon, Byerly, William, and Cebula, Richard P

Subjects
Geophysics
Abstract

Two data products from the Total Ozone Mapping Spectrometer (TOMS) onboard Nimbus-7 have been archived at the Distributed Active Archive Center, in the form of Hierarchical Data Format files. The instrument measures backscattered Earth radiance and incoming solar irradiance; their ratio is used in ozone retrievals. Changes in the instrument sensitivity are monitored by a spectral discrimination technique using measurements of the intrinsically stable wavelength dependence of derived surface reflectivity. The algorithm to retrieve total column ozone compares measured Earth radiances at sets of three wavelengths with radiances calculated for different total ozone values, solar zenith angles, and optical paths. The initial error in the absolute scale for TOMS total ozone is 3 percent, the one standard deviation random error is 2 percent, and drift is less than 1.0 percent per decade. The Level-2 product contains the measured radiances, the derived total ozone amount, and reflectivity information for each scan position. The Level-3 product contains daily total ozone amount and reflectivity in a I - degree latitude by 1.25 degrees longitude grid. The Level-3 product also is available on CD-ROM. Detailed descriptions of both HDF data files and the CD-ROM product are provided.

Published
1996

39. Global ozone data from the meteor-3/TOMS ultraviolet spectrometer

Author

Herman, J. R, Krueger, Arlin, Cote, C, Ahmad, Zia, Forman, M, Wellemeyer, C, Byerly, W, Pan, L, Jaross, Glen, and Hudson, R

Subjects
Geophysics
Abstract

A new TOMS instrument (Total Ozone Mapping Spectrometer) was launched from the Plesetsk Cosomodrome, Russia on August 15, 1991. The purpose of the joint project between the U.S. and Russia was to continue the long-term record of ozone measurements from Nimbus-7/TOMS (launched in October 1978). Ozone data from the two satellites compare very closely. When the orbital positions were nearly the same, the comparison over the entire globe showed an offset of 2 percent with a standard deviation of 5 percent. Comparisons were made with several ground based M124 and Dobson stations showing good agreement in absolute value and with the day-to-day variations seen by the ground stations.

Published
1994

40. Post launch performance of the Meteor-3/TOMS instrument

Author

Jaross, Glen, Ahmad, Zia, Cebula, Richard P, and Krueger, Arlin J

Subjects
Spacecraft Instrumentation
Abstract

The Meteor-3/TOMS instrument is the second in a series of Total Ozone Mapping Spectrometers (TOMS) following the 1978 launch of Nimbus-7/TOMS. TOMS instruments are designed to measure total ozone amounts over the entire earth on a daily basis, and have been the cornerstone of ozone trend monitoring. Consequently, calibration is a critical issue, and is receiving much attention on both instruments. Performance and calibration data obtained by monitoring systems aboard the Meteor-3 instrument have been analyzed through the first full year of operation, and indicate that the instrument is performing quite well. A new system for monitoring instrument sensitivity employing multiple diffusers has been used successfully and is providing encouraging results. The 3-diffuser system has monitored changes in instrument sensitivity of a few percent despite decreases in diffuser reflectivity approaching 50 percent since launch.

Published
1994

41. Validation of ozone profile retrievals derived from the OMPS LP version 2.5 algorithm against correlative satellite measurements

Author

Kramarova, Natalya A., primary, Bhartia, Pawan K., additional, Jaross, Glen, additional, Moy, Leslie, additional, Xu, Philippe, additional, Chen, Zhong, additional, DeLand, Matthew, additional, Froidevaux, Lucien, additional, Livesey, Nathaniel, additional, Degenstein, Douglas, additional, Bourassa, Adam, additional, Walker, Kaley A., additional, and Sheese, Patrick, additional

Published
2017
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42. Supplementary material to "Validation of ozone profile retrievals derived from the OMPS LP version 2.5 algorithm against correlative satellite measurements"

Author

Kramarova, Natalya A., primary, Bhartia, Pawan K., additional, Jaross, Glen, additional, Moy, Leslie, additional, Xu, Philippe, additional, Chen, Zhong, additional, DeLand, Matthew, additional, Froidevaux, Lucien, additional, Livesey, Nathaniel, additional, Degenstein, Douglas, additional, Bourassa, Adam, additional, Walker, Kaley A., additional, and Sheese, Patrick, additional

Published
2017
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43. In-flight performance of the Ozone Monitoring Instrument

Author

Schenkeveld, V. M.Erik (author), Jaross, Glen (author), Marchenko, Sergey (author), Haffner, David (author), Kleipool, Quintus L. (author), Rozemeijer, Nico C. (author), Veefkind, j. Pepijn (author), Levelt, Pieternel Felicitas (author), Schenkeveld, V. M.Erik (author), Jaross, Glen (author), Marchenko, Sergey (author), Haffner, David (author), Kleipool, Quintus L. (author), Rozemeijer, Nico C. (author), Veefkind, j. Pepijn (author), and Levelt, Pieternel Felicitas (author)

Abstract

The Dutch-Finnish Ozone Monitoring Instrument (OMI) is an imaging spectrograph flying on NASA's EOS Aura satellite since 15 July 2004. OMI is primarily used to map trace-gas concentrations in the Earth's atmosphere, obtaining mid-resolution (0.4-0.6 nm) ultraviolet-visible (UV-VIS; 264-504 nm) spectra at multiple (30-60) simultaneous fields of view. Assessed via various approaches that include monitoring of radiances from selected ocean, land ice and cloud areas, as well as measurements of line profiles in the solar spectra, the instrument shows low optical degradation and high wavelength stability over the mission lifetime. In the regions relatively free from the slowly unraveling "row anomaly" (RA) the OMI irradiances have degraded by 3-8 %, while radiances have changed by 1-2 %. The long-term wavelength calibration of the instrument remains stable to 0.005-0.020 nm., Atmospheric Remote Sensing

Published
2017
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46. In-flight performance of the Ozone Monitoring Instrument

Author

Schenkeveld, V. M. Erik, primary, Jaross, Glen, additional, Marchenko, Sergey, additional, Haffner, David, additional, Kleipool, Quintus L., additional, Rozemeijer, Nico C., additional, Veefkind, J. Pepijn, additional, and Levelt, Pieternel F., additional

Published
2017
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47. OMPS Limb Sensor II: Novel Operations to Fix Data Artifacts

Author

Soo, Dan, Brownsberger, Ken, Leitch, Jim, Draper, David, Huang, Pei, Knewtson, Rebecca, Lipscy, Sarah, Rusling, Dave, Stutheit, Cameron, Bennett, Steve, and Jaross, Glen

Abstract

The OMPS Limb sensor flying on the Suomi-NPP mission measures vertically-resolved Earth limb spectral radiance profiles to derive a high vertical resolution ozone profile using both UV and visible light dispersed by a prism and imaged onto a single CCD. The measurement challenges include a wide dynamic range in both spectral and spatial directions and demanding stray light requirements, especially for the UV wavelengths. The proposed operational change from Suomi NPP to JPSS2 eliminates a multiple image approach and reduces stray light levels through use of different images for different wavelength channels. Through use of a stepped integration time scheme and on-board image consolidation, the spectral radiance measurements are improved and more pixels are available for downlink within the allotted data rate. We present the operational concept, results of ground testing using the Limb sensor engineering unit and estimates of expected on-orbit performance.

Published
2015

49. Evaluation of OMPS/LP Stratospheric Aerosol Extinction Product Using SAGE III/ISS Observations.

Author

Zhong Chen, Bhartia, Pawan K., Torres, Omar, Jaross, Glen, Loughman, Robert, DeLand, Matthew, Colarco, Peter, Damadeo, Robert, and Taha, Ghassan

Subjects
STRATOSPHERIC aerosols, OZONE layer, MIE scattering, BIOLOGICAL extinction, OZONIZATION, PEARSON correlation (Statistics), VOLCANIC eruptions
Abstract

The Ozone Mapping and Profiler Suite Limb Profiler (OMPS/LP) has been flying on the Suomi NPP satellite since October 2011. It is designed to produce ozone and aerosol vertical profiles at 1.6 km vertical resolution over the entire sunlit globe. The Version 1.5 (V1.5) aerosol extinction retrieval algorithm provides aerosol extinction profiles using observed radiances at 675 nm. The algorithm assumes Mie theory and a gamma function aerosol size distribution for the stratospheric aerosol that is derived from Community Aerosol and Radiation Model for Atmospheres (CARMA) calculated results and observations in April 2012. In this paper, we compare V1.5 LP aerosol profiles with SAGE III/ISS solar occultation observations for the period June 2017 - May 2019, when both measurements were available. Overall, LP extinction profiles agree with SAGE data to within ±25% for the main aerosol layer between 19 and 27 km, even during periods perturbed by volcanic eruptions or intense forest fires. The slope parameter of linear fitting of LP extinctions with respect to SAGE measurements are close to 1.0, with Pearson's correlation coefficients of r ≥ 0.95, indicating that the LP aerosol data are reliable in that altitude range. Comparisons of extinction time series show a high degree of correlation between LP and SAGE, indicating that the LP retrieved extinction variability in time is robust. On the other hand, we find that LP retrieved extinction is systematically higher than SAGE observations at altitudes above 28 km and systematically lower below 19 km in the tropics. This is likely due in part to the fact that the actual aerosol size distribution is altitude dependent, while the assumed size distribution in the V1.5 retrieval is assumed to be altitude independent and so it may be less accurate for altitudes above 28 km and below 19 km where the size distribution is more variable. There are other reasons related to cloud contamination, wavelength limitations and the accuracy of both instruments at low aerosol loading. [ABSTRACT FROM AUTHOR]

Published
2019
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50. Trends in Global Tropospheric Ozone Inferred from a Composite Record of TOMS/OMI/MLS/OMPS Satellite Measurements and the MERRA-2 GMI Simulation.

Author

Ziemke, Jerry R., Oman, Luke D., Strode, Sarah A., Douglass, Anne R., Olsen, Mark A., McPeters, Richard D., Bhartia, Pawan K., Froidevaux, Lucien, Labow, Gordon J., Witte, Jacquie C., Thompson, Anne M., Haffner, David P., Kramarova, Natalya A., Frith, Stacey M., Liang-Kang Huang, Jaross, Glen R., Seftor, Colin J., Deland, Mathew T., and Taylor, Steven L.

Abstract

Past studies have suggested that ozone in the troposphere has increased globally throughout much of the 20th century due to increases in anthropogenic emissions and transport. We show by combining satellite measurements with a chemical transport model that during the last four decades tropospheric ozone does indeed indicate increases that are global in nature, yet still highly regional. Satellite ozone measurements from Nimbus-7 and Earth Probe Total Ozone Mapping Spectrometer (TOMS) are merged with ozone measurements from Aura Ozone Monitoring Instrument/Microwave Limb Sounder (OMI/MLS) to determine trends in tropospheric ozone for 1979-2016. Both TOMS (1979-2005) and OMI/MLS (2005-2016) depict large increases in tropospheric ozone from the Near East to India/East Asia and further eastward over the Pacific Ocean. The 38-year merged satellite record shows total net change over this region of about +6 to +7 Dobson Units (DU) (i.e., ~ 15-20% of average background ozone), with the largest increase (~ 4 DU) occurring during the 2005-2016 Aura period. The Global Modeling Initiative (GMI) chemical transport model with time-varying emissions is included to evaluate tropospheric ozone trends for 1980-2016. The GMI simulation for the combined record also depicts greatest increases of +6 to +7 DU over India/east Asia, identical to the satellite measurements. In regions of significant increases in TCO the trends are a factor of 2-2.5 larger for the Aura record when compared to the earlier TOMS record; for India/east Asia the trends in TCO for both GMI and satellite measurements are ~ +3 DU-decade-1 or greater during 2005-2016 compared to about +1.2 to +1.4 DU-decade-1 for 1979-2016. The GMI simulation and satellite data also reveal a tropospheric ozone increase of ~ +4 to +5 DU for the 38-year record over central Africa and the tropical Atlantic Ocean. Both the GMI simulation and satellite-measured tropospheric ozone during the latter Aura time period show increases of ~ +3 DU-decade-1 over the NH Atlantic and NE Pacific. [ABSTRACT FROM AUTHOR]

Published
2018
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