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211. Model for land surface reflectance treatment: Physical derivation, application for bare soil and evaluation on airborne and satellite measurements

Author

Litvinov, Pavel, Hasekamp, Otto, Dubovik, Oleg, and Cairns, Brian

Subjects
*REFLECTANCE, *SURFACE chemistry, *ATMOSPHERIC aerosols, *ELECTROMAGNETIC wave scattering, *POLARISCOPE, *ARTIFICIAL satellites in earth sciences, *SURFACE of the earth, *EARTH (Planet)
Abstract

Abstract: For land surfaces and atmospheric aerosol characterization on the basis of satellite and airborne measurements models for surface reflection description are required. At present time for visible and infrared spectral regions semi-empirical model for surface reflection are usually used for these purposes. Due to the lack of physical basis, these models introduce a lot of uncertainties into the problem of aerosol and surface properties retrieval. In this paper we consider the possibility of using physically based models for bidirectional reflection matrix (BRM) which can be applied to the problem of simultaneous retrieval of aerosol and land surface properties. The physical model for the BRM is derived from the general solution of the electromagnetic scattering problems by random media. The equation for the reflection matrix is obtained within the far-field approximation when the ladder scattering diagrams are taken into account. To perform analytical averaging over orientation of the surface elements we assume that at different scales the surface can be considered as the Gaussian surface. We use multi-angle photopolarimetric airborne measurements of the Research Scanning Polarimeter (RSP) and satellite POLDER (Polarization and Directionality of the Earth''s Reflectances) measurements to investigate the performance of the presented BRM model. The results of the comparison are discussed. [Copyright &y& Elsevier]

Published
2012
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212. Efficient vector radiative transfer calculations in vertically inhomogeneous cloudy atmospheres

Author

van Diedenhoven, Bastiaan, Hasekamp, Otto P., and Landgraf, Jochen

Abstract

Accurate radiative transfer calculations in cloudy atmospheres are generally time consuming, limiting their practical use in satellite remote sensing applications. We present a model to efficiently calculate the radiative transfer of polarized light in atmospheres that contain homogeneous cloud layers. This model combines the Gauss-Seidel method, which is efficient for inhomogeneous cloudless atmospheres, with the doubling method, which is efficient for homogeneous cloud layers. Additionally to reduce the computational effort for radiative transfer calculations in absorption bands, the cloud reflection and transmission matrices are interpolated over the absorption and scattering optical thicknesses within the cloud layer. We demonstrate that the proposed radiative transfer model in combination with this interpolation technique is efficient for the simulation of satellite measurements for inhomogeneous atmospheres containing one homogeneous cloud layer. For example, the Scanning Imaging Absorption Spectrometer for Atmospheric Cartography (SCIAMACHY) measurements in the oxygen A band (758-773 nm) and the Hartley-Huggins ozone band (295-335 nm) with a spectral resolution of 0.4 nm can be simulated for these atmospheres within 1 min on a 2.8 GHz PC with an accuracy better than 0.1%.

Published
2006

216. Analysis of polarimetric satellite measurements suggests stronger cooling due to aerosol-cloud interactions.

Author

Hasekamp, Otto P., Gryspeerdt, Edward, and Quaas, Johannes

Subjects
POLARIMETRIC remote sensing, ATMOSPHERIC aerosols, CLOUD condensation nuclei, CLOUD droplets
Abstract

Anthropogenic aerosol emissions lead to an increase in the amount of cloud condensation nuclei and consequently an increase in cloud droplet number concentration and cloud albedo. The corresponding negative radiative forcing due to aerosol cloud interactions (RF aci ) is one of the most uncertain radiative forcing terms as reported in the 5th Assessment Report of the Intergovernmental Panel on Climate Change (IPCC). Here we show that previous observation-based studies underestimate aerosol-cloud interactions because they used measurements of aerosol optical properties that are not directly related to cloud formation and are hampered by measurement uncertainties. We have overcome this problem by the use of new polarimetric satellite retrievals of the relevant aerosol properties (aerosol number, size, shape). The resulting estimate of RF aci = −1.14 Wm -2 (range between −0.84 and −1.72 Wm -2 ) is more than a factor 2 stronger than the IPCC estimate that includes also other aerosol induced changes in cloud properties. The radiative forcing due to aerosol-cloud interactions constitutes one of the largest uncertainties of anthropogenic radiative forcing. Direct satellite measurements of the relevant aerosol properties reveal that the resulting cooling from anthropogenic aerosols is much stronger than previously thought. [ABSTRACT FROM AUTHOR]

Published
2019
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217. China's coal mine methane regulations have not curbed growing emissions.

Author

Miller, Scot M., Michalak, Anna M., Detmers, Robert G., Hasekamp, Otto P., Bruhwiler, Lori M. P., and Schwietzke, Stefan

Abstract

Anthropogenic methane emissions from China are likely greater than in any other country in the world. The largest fraction of China's anthropogenic emissions is attributable to coal mining, but these emissions may be changing; China enacted a suite of regulations for coal mine methane (CMM) drainage and utilization that came into full effect in 2010. Here, we use methane observations from the GOSAT satellite to evaluate recent trends in total anthropogenic and natural emissions from Asia with a particular focus on China. We find that emissions from China rose by 1.1 ± 0.4 Tg CH4 yr−1 from 2010 to 2015, culminating in total anthropogenic and natural emissions of 61.5 ± 2.7 Tg CH4 in 2015. The observed trend is consistent with pre-2010 trends and is largely attributable to coal mining. These results indicate that China's CMM regulations have had no discernible impact on the continued increase in Chinese methane emissions. Chinese government has implemented regulations to reduce mining-related methane emission since 2010. Here the authors estimated methane emissions in China using GOSAT satellite observation and results reveal a business-as-usual increase in methane emissions since 2010 despite those ambitious targets. [ABSTRACT FROM AUTHOR]

Published
2019
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218. Aerosol retrievals from the ACEPOL Campaign.

Author

Fu, Guangliang, Hasekamp, Otto, Noia, Antonio di, Rietjens, Jeroen, Smit, Martijn, Cairns, Brian, Wasilewski, Andrzej, Diner, David, Xu, Feng, Martins, Vanderlei, Knobelspiesse, Kirk, Burton, Sharon, Hostetler, Chris, Hair, John, and Ferrare, Richard

Subjects
*AEROSOLS, *SMOKE plumes, *POLARISCOPE
Abstract

In this study, we present aerosol level-2 retrieval results from ACEPOL (Aerosol Characterization from Polarimeter and Lidar) campaign, which was a joint initiative between NASA and SRON (NL) and took place October-November 2017 over the western part of the United States. We perform aerosol retrievals using the SRON multimode algorithm on SPEX airborne L1C data, the Research Scanning Polarimeter (RSP) L1 data, and the Airborne Multi-angle SpectroPolarimeter Imager (AirMSPI) L1B2 data. The AERONET data and the High Spectral Resolution Lidar-2 (HSRL2) data are used to validate polarimeter retrieved/diagnostics aerosol properties. The polarimeter retrievals are based on SRON 5-mode approaches. Other multimode (from 6 to 10 modes) tests show similar performances with the 5-mode approach.Validations with AERONET show that SPEX, RSP, and AirMSPI retrievals achieve similar performances on aerosol optical thickness (AOT) and they agree well with AERONET. Here, we also show that AirMSPI-AERONET based on the SRON algorithm compares well with that based on the JPL algorithm. The Angstrom Exponent is compared between SPEX-AERONET and RSP-AERONET when AOT>0.1. Validations with HSRL2 are performed on two days. One day with low aerosol (AOD in range 0.02-0.14) and one day with measurements of an inhomogeneous smoke plume with high AOD (including AOD values > 1.0). Considering the data collocations among instruments, we compare SPEX-HSRL2, RSP-HSRL2, and SPEX-RSP for these two cases. SPEX and RSP both compare well to HSRL2 for AOT, backscatter coefficients, and depolarization ratio. [ABSTRACT FROM AUTHOR]

Published
2019

219. Retrieval of aerosol and cloud properties from multi-angle photo-polarimetric measurements: Present status and future developments.

Author

Hasekamp, Otto, Fu, Guangliang, Noia, Antonio Di, Wu, Lianghai, Martin, Will, Landgraf, Jochen, van Amerongen, Aaldert, Smit, Martijn, and Rietjens, Jeroen

Subjects
*AEROSOLS, *OCEAN color, *AIR quality, *RADIOISOTOPES, *REMOTE sensing, *CARBONACEOUS aerosols
Abstract

There is growing consensus in the aerosol remote sensing community that Multi-Angle Photo-polarimetric (MAP) measurements are essential to unambiguously determine all aerosol properties relevant to quantify and understand the impact of aerosols on climate and air quality. This presentation will discuss the advanced algorithm development for aerosol and cloud retrieval from MAP instruments. This includes aerosol and cloud retrieval from the PARASOL mission (2004-2013) and its validation, estimation the Direct Radiative Effect of Aerosols (DREA) using PARASOL and other A-Train sensors, use of Neural Network techniques for cloud retrievals, and aerosol retrieval from airborne MAP instruments. Further, we will discuss the development of the SPEXone instrument for the NASA PACE mission (launch 2022) and its aerosol retrieval capabilities. SPEXone is a high accuracy MAP with 5 viewing angles with hyperspectral capability, that is expected to provide aerosol properties with unprecedented detail and accuracy. On the PACE mission SPEXone will be used in synergy with the Hyper-Angular Rainbow Polarimeter-2 (HARP-2) and the Ocean Color Instrument (OCI). [ABSTRACT FROM AUTHOR]

Published
2019

224. Geophysical validation of Sentinel-5P Methane and Carbon Monoxide using ground-based total column data from all stations of the TCCON and NDACC-IRWG networks (TCCON4S5P).

Author

Sha, Mahesh Kumar, Langerock, Bavo, De Mazière, Martine, Hermans, Christian, Kumps, Nicolas, Feist, Dietrich, Sussmann, Ralf, Roehl, Coleen, Kiel, Matthäus, Notholt, Justus, Wennberg, Paul, Wunch, Debra, Velazco, Voltaire, Deutscher, Nicholas, Landgraf, Jochen, Borsdorff, Tobias, Hu, Haili, Lorente, Alba, and Hasekamp, Otto

Published
2019

225. Ensemble-based satellite-derived carbon dioxide and methane column-averaged dry-air mole fraction data sets (2003-2018) for carbon and climate applications

Author

Reuter, Maximilian, Buchwitz, Michael, Schneising, Oliver, Noël, Stefan, Bovensmann, Heinrich, Burrows, John P., Boesch, Hartmut, Di Noia, Antonio, Anand, Jasdeep, Parker, Robert J., Somkuti, Peter, Wu, Lianghai, Hasekamp, Otto P., Aben, Ilse, Kuze, Akihiko, Suto, Hiroshi, Shiomi, Kei, Yoshida, Yukio, Morino, Isamu, Crisp, David, O&Apos;Dell, Christopher W., Notholt, Justus, Petri, Christof, Warneke, Thorsten, Velazco, Voltaire A., Deutscher, Nicholas M., Griffith, David W. T., Kivi, Rigel, Pollard, David F., Hase, Frank, Sussmann, Ralf, Té, Yao V., Strong, Kimberly, Roche, Sébastien, Sha, Mahesh K., De Mazière, Martine, Feist, Dietrich G., Iraci, Laura T., Roehl, Coleen M., Retscher, Christian, and Schepers, Dinand

Subjects
13. Climate action
Abstract

Satellite retrievals of column-averaged dry-air mole fractions of carbon dioxide (CO$_{2}$) and methane (CH$_{4}$), denoted XCO$_{2}$ and XCH$_{4}$, respectively, have been used in recent years to obtain information on natural and anthropogenic sources and sinks and for other applications such as comparisons with climate models. Here we present new data sets based on merging several individual satellite data products in order to generate consistent long-term climate data records (CDRs) of these two Essential Climate Variables (ECVs). These ECV CDRs, which cover the time period 2003–2018, have been generated using an ensemble of data products from the satellite sensors SCIAMACHY/ENVISAT and TANSO-FTS/GOSAT and (for XCO$_{2}$) for the first time also including data from the Orbiting Carbon Observatory 2 (OCO-2) satellite. Two types of products have been generated: (i) Level 2 (L2) products generated with the latest version of the ensemble median algorithm (EMMA) and (ii) Level 3 (L3) products obtained by gridding the corresponding L2 EMMA products to obtain a monthly 5°x5°data product in Obs4MIPs (Observations for Model Intercomparisons Project) format. The L2 products consist of daily NetCDF (Network Common Data Form) files, which contain in addition to the main parameters, i.e., XCO$_{2}$ or XCH$_{4}$, corresponding uncertainty estimates for random and potential systematic uncertainties and the averaging kernel for each single (quality-filtered) satellite observation. We describe the algorithms used to generate these data products and present quality assessment results based on comparisons with Total Carbon Column Observing Network (TCCON) ground-based retrievals. We found that the XCO$_{2}$ Level 2 data set at the TCCON validation sites can be characterized by the following figures of merit (the corresponding values for the Level 3 product are listed in brackets) – single-observation random error (1$^{σ}$): 1.29 ppm (monthly: 1.18 ppm); global bias: 0.20 ppm (0.18 ppm); and spatiotemporal bias or relative accuracy (1$^{σ}$): 0.66 ppm (0.70 ppm). The corresponding values for the XCH$_{4}$ products are singleobservation random error (1$^{σ}$): 17.4 ppb (monthly: 8.7 ppb); global bias: -2.0 ppb (-2.9 ppb); and spatiotemporal bias (1$^{σ}$): 5.0 ppb (4.9 ppb). It has also been found that the data products exhibit very good long-term stability as no significant long-term bias trend has been identified. The new data sets have also been used to derive annual XCO$_{2}$ and XCH$_{4}$ growth rates, which are in reasonable to good agreement with growth rates from the National Oceanic and Atmospheric Administration (NOAA) based on marine surface observations.

226. Cloud detection from multi-angular polarimetric satellite measurements using a neural network ensemble approach.

Author

Yuan, Zihao, Fu, Guangliang, van Diedenhoven, Bastiaan, Lin, Hai Xiang, Erisman, Jan Willem, and Hasekamp, Otto P.

Subjects
*MODIS (Spectroradiometer), *RADARSAT satellites, *GEOSTATIONARY satellites, *ATMOSPHERIC sciences
Abstract

This paper describes a neural network cloud masking scheme from PARASOL (Polarization and Anisotropy of Reflectances for Atmospheric Science coupled with Observations from a Lidar) multi-angle polarimetric measurements. The algorithm has been trained on synthetic measurements and has been applied to the processing of 1 year of PARASOL data. Comparisons of the retrieved cloud fraction with MODIS (Moderate Resolution Imaging Spectroradiometer) products show overall agreement in spatial and temporal patterns, but the PARASOL neural network (PARASOL-NN) retrieves lower cloud fractions. Comparisons with a goodness-of-fit mask from aerosol retrievals suggest that the NN cloud mask flags fewer clear pixels as cloudy than MODIS (∼ 3 % of the clear pixels versus ∼ 15 % by MODIS). On the other hand the NN classifies more pixels incorrectly as clear than MODIS (∼ 20 % by NN, versus ∼ 15 % by MODIS). Additionally, the NN and MODIS cloud mask have been applied to the aerosol retrievals from PARASOL using the Remote Sensing of Trace Gas and Aerosol Products (RemoTAP) algorithm. Validation with AERONET shows that the NN cloud mask performs comparably with MODIS in screening residual cloud contamination in retrieved aerosol properties. Our study demonstrates that cloud masking from multi-angle polarimeter (MAP) aerosol retrievals can be performed based on the MAP measurements themselves, making the retrievals independent of the availability of a cloud imager. [ABSTRACT FROM AUTHOR]

Published
2024
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229. Frontiers in Satellite‐Based Estimates of Cloud‐Mediated Aerosol Forcing.

Author

Rosenfeld, Daniel, Kokhanovsky, Alexander, Goren, Tom, Gryspeerdt, Edward, Hasekamp, Otto, Jia, Hailing, Lopatin, Anton, Quaas, Johannes, Pan, Zengxin, and Sourdeval, Odran

Subjects
*CLIMATE change models, *GENERAL circulation model, *CLOUD condensation nuclei, *ATMOSPHERIC aerosols, *AEROSOLS, *ICE clouds, *ENERGY budget (Geophysics)
Abstract

Atmospheric aerosols affect the Earth's climate in many ways, including acting as the seeds on which cloud droplets form. Since a large fraction of these particles is anthropogenic, the clouds' microphysical and radiative characteristics are influenced by human activity on a global scale leading to important climatic effects. The respective change in the energy budget at the top of the atmosphere is defined as the effective radiative forcing due to aerosol‐cloud interaction (ERFaci). It is estimated that the ERFaci offsets presently nearly 1/4 of the greenhouse‐induced warming, but the uncertainty is within a factor of two. A common method to calculate the ERFaci is by the multiplication of the susceptibility of the cloud radiative effect to changes in aerosols by the anthropogenic change of the aerosol concentration. This has to be done by integrating it over all cloud regimes. Here we review the various methods of the ERFaci estimation. Global measurements require satellites' global coverage. The challenge of quantifying aerosol amounts in cloudy atmospheres are met with the rapid development of novel methodologies reviewed here. The aerosol characteristics can be retrieved from space based on their optical properties, including polarization. The concentrations of the aerosols that serve as cloud drop condensation nuclei can be also estimated from their impact on the satellite‐retrieved cloud drop number concentrations. These observations are critical for reducing the uncertainty in the ERFaci calculated from global climate models (GCMs), but further development is required to allow GCMs to properly simulate and benefit these novel observables. Plain Language Summary: Aerosols affect the climate in many ways, including serving as the basis for the formation of cloud droplets. Therefore, aerosols have profound impacts on clouds and through that on the Earth's energy budget. Increasing aerosols leads to additional cloud droplets, changing cloud properties such that they reflect more solar radiation back to space and offset nearly 1/4 of the warming induced by greenhouse gases, but with a large uncertainty within a factor of two. Here we review the ways by which aerosols and their radiative effects are retrieved from space. A major challenge is to reduce the uncertainty by better retrieval methods of atmospheric aerosol and cloud properties. This challenge is met by rapid satellite retrieval methodological developments and numerous new satellite missions, which are described here. These new methodologies have to be matched with parallel development in the global circulation models for the improved estimation of the actual climatic impacts. Key Points: Calculating the susceptibility of clouds to aerosols has to include the cleanest conditions where measuring the aerosols is challengingThe definition and use of regimes to group clouds with similar responses to aerosol is vital for future observation‐based effective radiative forcing due to aerosol‐cloud interaction (ERFaci) estimatesNew observational tools are vital for reducing ERFaci uncertainty but require further global climate model development to simulate these novel observables [ABSTRACT FROM AUTHOR]

Published
2023
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230. Simultaneous retrieval of aerosol and ocean properties from PACE HARP2 with uncertainty assessment using cascading neural network radiative transfer models.

Author

Gao, Meng, Franz, Bryan A., Zhai, Peng-Wang, Knobelspiesse, Kirk, Sayer, Andrew M., Xu, Xiaoguang, Martins, J. Vanderlei, Cairns, Brian, Castellanos, Patricia, Fu, Guangliang, Hannadige, Neranga, Hasekamp, Otto, Hu, Yongxiang, Ibrahim, Amir, Patt, Frederick, Puthukkudy, Anin, and Werdell, P. Jeremy

Subjects
*CASCADE connections, *RADIATIVE transfer, *AEROSOLS, *MONTE Carlo method, *OCEAN color, *WIND speed, *OCEAN
Abstract

The University of Maryland, Baltimore County (UMBC) Hyper-Angular Rainbow Polarimeter (HARP2) will be on board NASA's Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) mission, scheduled for launch in January 2024. In this study we systematically evaluate the retrievability and uncertainty of aerosol and ocean parameters from HARP2 multi-angle polarimeter (MAP) measurements. To reduce the computational demand of MAP-based retrievals and maximize data processing throughput, we developed improved neural network (NN) forward models for spaceborne HARP2 measurements over a coupled atmosphere and ocean system within the FastMAPOL retrieval algorithm. To this end, a cascading retrieval scheme is implemented in FastMAPOL, which leverages a series of NN models of varying size, speed, and accuracy to optimize performance. Two sets of NN models are used for reflectance and polarization, respectively. A full day of global synthetic HARP2 data was generated and used to test various retrieval parameters including aerosol microphysical and optical properties, aerosol layer height, ocean surface wind speed, and ocean chlorophyll a concentration. To assess retrieval quality, pixel-wise retrieval uncertainties were derived from error propagation and evaluated against the difference between the retrieval parameters and truth based on a Monte Carlo method. We found that the fine-mode aerosol properties can be retrieved well from the HARP2 data, though the coarse-mode aerosol properties are more uncertain. Larger uncertainties are associated with a reduced number of available viewing angles, which typically occur near the scan edge of the HARP2 instrument. Results of the performance assessment demonstrate that the algorithm is a viable approach for operational application to HARP2 data after the PACE launch. [ABSTRACT FROM AUTHOR]

Published
2023
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231. Enhanced methane emissions from tropical wetlands during the 2011 La Niña.

Author

Pandey, Sudhanshu, Houweling, Sander, Krol, Maarten, Aben, Ilse, Monteil, Guillaume, Nechita-Banda, Narcisa, Dlugokencky, Edward J., Detmers, Rob, Hasekamp, Otto, Xu, Xiyan, Riley, William J., Poulter, Benjamin, Zhang, Zhen, McDonald, Kyle C., White, James W. C., Bousquet, Philippe, and Röckmann, Thomas

Abstract

Year-to-year variations in the atmospheric methane (CH4) growth rate show significant correlation with climatic drivers. The second half of 2010 and the first half of 2011 experienced the strongest La Niña since the early 1980s, when global surface networks started monitoring atmospheric CH4 mole fractions. We use these surface measurements, retrievals of column-averaged CH4 mole fractions from GOSAT, new wetland inundation estimates, and atmospheric δ13C-CH4 measurements to estimate the impact of this strong La Niña on the global atmospheric CH4 budget. By performing atmospheric inversions, we find evidence of an increase in tropical CH4 emissions of ∼6-9 TgCH4 yr−1 during this event. Stable isotope data suggest that biogenic sources are the cause of this emission increase. We find a simultaneous expansion of wetland area, driven by the excess precipitation over the Tropical continents during the La Niña. Two process-based wetland models predict increases in wetland area consistent with observationally-constrained values, but substantially smaller per-area CH4 emissions, highlighting the need for improvements in such models. Overall, tropical wetland emissions during the strong La Niña were at least by 5% larger than the long-term mean. [ABSTRACT FROM AUTHOR]

Published
2017
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232. Cloud Detection from Multi-Angular Polarimetric Satellite Measurements using a Neural Network Ensemble Approach.

Author

Zihao Yuan, Guangliang Fu, van Diedenhoven, Bastiaan, Hai Xiang Lin, Erisman, Jan Willem, and Hasekamp, Otto P.

Subjects
*MODIS (Spectroradiometer), *ATMOSPHERIC sciences
Abstract

This paper describes a neural network cloud masking scheme from PARASOL (Polarisation and Anisotropy of Reflectances for Atmospheric Science coupled with Observations from a Lidar) Multi-Angle Polarimetric measurements. The algorithm has been trained on synthetic measurements and has been applied to the processing of one year of PARASOL data. Comparisons of the retrieved cloud fraction with MODIS (Moderate Resolution Imaging Spectroradiometer) products show overall agreement in spatial and temporal patterns but the PARASOL-NN retrieves lower cloud fractions. Comparisons with a goodness-of-fit mask from aerosol retrievals suggest that the NN cloud mask flags less clear pixels as cloudy than MODIS (∼ 3% of the clear pixels, versus ∼ 15% by MODIS). On the other hand the NN classifies more pixels incorrectly as clear than MODIS (∼ 19% by NN, versus ∼ 15% by MODIS). Additionally, the NN and MODIS cloud mask have been applied to the aerosol retrievals from PARASOL using the Remote Sensing of Trace Gas and Aerosol Products (RemoTAP) algorithm. Validation with AERONET shows that the NN cloud mask performs comparably with MODIS in screening residual cloud contamination in retrieved aerosol properties. Our study demonstrates that cloud masking from MAP aerosol retrievals can be performed based on the MAP measurements themselves, making the retrievals independent of the availability of a cloud imager. [ABSTRACT FROM AUTHOR]

Published
2023
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233. Evaluation of the methane full-physics retrieval applied to TROPOMI ocean sun glint measurements.

Author

Lorente, Alba, Borsdorff, Tobias, Martinez-Velarte, Mari C., Butz, Andre, Hasekamp, Otto P., Wu, Lianghai, and Landgraf, Jochen

Subjects
*ATMOSPHERIC methane, *OCEAN, *OCEAN color, *ATMOSPHERIC oxygen, *METHANE, *TROPOSPHERIC aerosols, *COLUMNS, *GREENHOUSE gases
Abstract

The TROPOspheric Monitoring Instrument (TROPOMI), due to its wide swath, performs observations over the ocean in every orbit, enhancing the monitoring capabilities of methane from space. In the short-wave–infrared (SWIR) spectral band ocean surfaces are dark except for the specific sun glint geometry, for which the specular reflectance detected by the satellite provides a signal that is high enough to retrieve methane with high accuracy and precision. In this study, we build upon the RemoTeC full-physics retrieval algorithm for land measurements, and we retrieve 4 years of methane concentrations over the ocean from TROPOMI. We fully assess the quality of the dataset by performing a validation using ground-based measurements of the Total Carbon Column Observing Network (TCCON) from near-ocean sites. The validation results in an agreement of -0.5±0.3 % (-8.4±6.3 ppb) for the mean bias and station-to-station variability, which show that glint measurements comply with the mission requirement of precision and accuracy below 1 %. Comparison to ocean measurements from the Greenhouse gases Observing SATellite (GOSAT) results in a bias of -0.2±0.9 % (-4.4±15.7 ppb), equivalent to the comparison of measurements over land. The full-physics algorithm simultaneously retrieves the amount of atmospheric methane and the physical scattering properties of the atmosphere from measurements in the near-infrared (NIR) and SWIR spectral bands. Based on the scattering properties of the atmosphere and ocean surface reflection we further validate retrievals over the ocean. Using the "upper-edge" method, we identify a set of ocean glint observations where scattering by aerosols and clouds can be ignored in the measurement simulation to investigate other possible error sources such as instrumental errors, radiometric inaccuracies or uncertainties related to spectroscopic absorption cross-sections. With this ensemble we evaluate the RemoTeC forward model via the validation of the total atmospheric oxygen (O 2) column retrieved from the O 2 A-band, as well as the consistency of XCH4 retrievals using sub-bands from the SWIR band, which show a consistency within 1 %. We discard any instrumental and radiometric errors by a calibration of the O 2 absorption line strengths as suggested in the literature. [ABSTRACT FROM AUTHOR]

Published
2022
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234. Effective uncertainty quantification for multi-angle polarimetric aerosol remote sensing over ocean.

Author

Gao, Meng, Knobelspiesse, Kirk, Franz, Bryan A., Zhai, Peng-Wang, Sayer, Andrew M., Ibrahim, Amir, Cairns, Brian, Hasekamp, Otto, Hu, Yongxiang, Martins, Vanderlei, Werdell, P. Jeremy, and Xu, Xiaoguang

Subjects
*POLARIMETRIC remote sensing, *ARTIFICIAL neural networks, *AUTOMATIC differentiation, *OCEAN color, *OCEAN, *OPTICAL properties
Abstract

Multi-angle polarimetric (MAP) measurements can enable detailed characterization of aerosol microphysical and optical properties and improve atmospheric correction in ocean color remote sensing. Advanced retrieval algorithms have been developed to obtain multiple geophysical parameters in the atmosphere–ocean system. Theoretical pixel-wise retrieval uncertainties based on error propagation have been used to quantify retrieval performance and determine the quality of data products. However, standard error propagation techniques in high-dimensional retrievals may not always represent true retrieval errors well due to issues such as local minima and the nonlinear dependence of the forward model on the retrieved parameters near the solution. In this work, we analyze these theoretical uncertainty estimates and validate them using a flexible Monte Carlo approach. The Fast Multi-Angular Polarimetric Ocean coLor (FastMAPOL) retrieval algorithm, based on efficient neural network forward models, is used to conduct the retrievals and uncertainty quantification on both synthetic HARP2 (Hyper-Angular Rainbow Polarimeter 2) and AirHARP (airborne version of HARP2) datasets. In addition, for practical application of the uncertainty evaluation technique in operational data processing, we use the automatic differentiation method to calculate derivatives analytically based on the neural network models. Both the speed and accuracy associated with uncertainty quantification for MAP retrievals are addressed in this study. Pixel-wise retrieval uncertainties are further evaluated for the real AirHARP field campaign data. The uncertainty quantification methods and results can be used to evaluate the quality of data products, as well as guide MAP algorithm development for current and future satellite systems such as NASA's Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) mission. [ABSTRACT FROM AUTHOR]

Published
2022
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235. The Space Carbon Observatory (SCARBO) concept: assessment of XCO2 and XCH4 retrieval performance.

Author

Dogniaux, Matthieu, Crevoisier, Cyril, Gousset, Silvère, Le Coarer, Étienne, Ferrec, Yann, Croizé, Laurence, Wu, Lianghai, Hasekamp, Otto, Sic, Bojan, and Brooker, Laure

Subjects
*OBSERVATORIES, *GREENHOUSE gases, *CARBON dioxide, *MICROSPACECRAFT, *SPATIAL resolution, *GREENHOUSE gas analysis, *SPACE-based radar
Abstract

Several single-platform satellite missions have been designed during the past decades in order to retrieve the atmospheric concentrations of anthropogenic greenhouse gases (GHG), initiating worldwide efforts towards better monitoring of their sources and sinks. To set up a future operational system for anthropogenic GHG emission monitoring, both revisit frequency and spatial resolution need to be improved. The Space Carbon Observatory (SCARBO) project aims at significantly increasing the revisit frequency of spaceborne GHG measurements, while reaching state-of-the-art precision requirements, by implementing a concept of small satellite constellation. It would accommodate a miniaturised GHG sensor named NanoCarb coupled with an aerosol instrument, the multi-angle polarimeter SPEXone. More specifically, the NanoCarb sensor is a static Fabry–Pérot imaging interferometer with a 2.3×2.3 km 2 spatial resolution and 200 km swath. It samples a truncated interferogram at optical path differences (OPDs) optimally sensitive to all the geophysical parameters necessary to retrieve column-averaged dry-air mole fractions of CO 2 and CH 4 (hereafter XCO2 and XCH4). In this work, we present the Level 2 performance assessment of the concept proposed in the SCARBO project. We perform inverse radiative transfer to retrieve XCO2 and XCH4 directly from synthetic NanoCarb truncated interferograms and provide their systematic and random errors, column vertical sensitivities, and degrees of freedom as a function of five scattering-error-critical atmospheric and observational parameters. We show that NanoCarb XCO2 and XCH4 systematic retrieval errors can be greatly reduced with SPEXone posterior outputs used as improved prior aerosol constraints. For two-thirds of the soundings, located at the centre of the 200 km NanoCarb swath, XCO2 and XCH4 random errors span 0.5–1 ppm and 4–6 ppb, respectively, compliant with their respective 1 ppm and 6 ppb precision objectives. Finally, these Level 2 performance results are parameterised as a function of the explored scattering-error-critical atmospheric and observational parameters in order to time-efficiently compute extensive L2 error maps for future CO 2 and CH 4 flux estimation performance studies. [ABSTRACT FROM AUTHOR]

Published
2022
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236. Estimating aerosol emission from SPEXone on the NASA PACE mission using an ensemble Kalman smoother: observing system simulation experiments (OSSEs).

Author

Tsikerdekis, Athanasios, Schutgens, Nick A. J., Fu, Guangliang, and Hasekamp, Otto P.

Subjects
*AEROSOLS, *DIMETHYL sulfide, *SIMULATION methods & models, *PLANETARY exploration, *SOOT, *GAUSSIAN distribution, *SEA salt
Abstract

We present a top-down approach for aerosol emission estimation from Spectropolarimeter for Planetary Exploration (SPEXone) polarimetric retrievals related to the aerosol amount, size, and absorption using a fixed-lag ensemble Kalman smoother (LETKS) in combination with the ECHAM-HAM model. We assess the system by performing observing system simulation experiments (OSSEs) in order to evaluate the ability of the future multi-angle polarimeter instrument, SPEXone, as well as a satellite with near-perfect global coverage. In our OSSEs, the nature run (NAT) is a simulation by the global climate aerosol model ECHAM-HAM with altered aerosol emissions. The control (CTL) and the data assimilation (DAS) experiments are composed of an ensemble of ECHAM-HAM simulations, where the default aerosol emissions are perturbed with factors taken from a Gaussian distribution. Synthetic observations, specifically aerosol optical depth at 550 nm (AOD 550), Ångström exponent from 550 to 865 nm (AE 550–865), and single-scattering albedo at 550 nm (SSA 550) are assimilated in order to estimate the aerosol emission fluxes of desert dust (DU), sea salt (SS), organic carbon (OC), black carbon (BC), and sulfate (SO 4), along with the emission fluxes of two SO 4 precursor gases (SO 2 , DMS). The prior emission global relative mean absolute error (MAE) before the assimilation ranges from 33 % to 117 %. Depending on the species, the assimilated observations sampled using the satellite with near-perfect global coverage reduce this error to equal to or lower than 5 %. Despite its limited coverage, the SPEXone sampling shows similar results, with somewhat larger errors for DU and SS (both having a MAE equal to 11 %). Further, experiments show that doubling the measurement error increases the global relative MAE up to 22 % for DU and SS. In addition, our results reveal that when the wind of DAS uses a different reanalysis dataset (ERA5 instead of ERA-Interim) to the NAT, the estimated SS emissions are negatively affected the most, while other aerosol species are negatively affected to a smaller extent. If the DAS uses dust or sea salt emission parametrizations that are very different from the NAT, posterior emissions can still be successfully estimated, but this experiment revealed that the source location is important for the estimation of dust emissions. This work suggests that the upcoming SPEXone sensor will provide observations related to aerosol amount, size, and absorption with sufficient coverage and accuracy in order to estimate aerosol emissions. [ABSTRACT FROM AUTHOR]

Published
2022
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237. Retrieval of aerosol microphysical properties from atmospheric lidar sounding: an investigation using synthetic measurements and data from the ACEPOL campaign.

Author

McLean, William G. K., Fu, Guangliang, Burton, Sharon P., and Hasekamp, Otto P.

Subjects
*LIDAR, *AEROSOLS, *DEPTH sounding, *REFRACTIVE index, *SMOKE plumes, *CLOUD physics, *CARBONACEOUS aerosols
Abstract

This study presents an investigation of aerosol microphysical retrievals from high spectral resolution lidar (HSRL) measurements. Firstly, retrievals are presented for synthetically generated lidar measurements, followed by an application of the retrieval algorithm to real lidar measurements. Here, we perform the investigation for an aerosol state vector that is typically used in multi-angle polarimeter (MAP) retrievals, so that the results can be interpreted in relation to a potential combination of lidar and MAP measurements. These state vectors correspond to a bimodal size distribution, where column number, effective radius, and effective variance of both modes are treated as fit parameters, alongside the complex refractive index and particle shape. The focus is primarily on a lidar configuration based on that of the High Spectral Resolution Lidar-2 (HSRL-2), which participated in the ACEPOL (Aerosol Characterization from Polarimeter and Lidar) campaign, a combined project between NASA and SRON (Netherlands Institute for Space Research). The measurement campaign took place between October and November 2017, over the western region of the USA. Six different instruments were mounted on the aeroplane: four MAPs and two lidar instruments, HSRL-2 and the Cloud Physics Lidar (CPL). Most of the flights were carried out over land, passing over scenes with a low aerosol load. One of the flights passed over a prescribed forest fire in Arizona on 9 November, with a relatively higher aerosol optical depth (AOD), and it is the data from this flight that are focussed on in this study. A retrieval of the aerosol microphysical properties of the smoke plume mixture was attempted with the data from HSRL-2 and compared with a retrieval from the MAPs carried out in previous work pertaining to the ACEPOL data. The synthetic HSRL-2 retrievals resulted for the fine mode in a mean absolute error (MAE) of 0.038 (0.025) µm for the effective radius (with a mean truth value of 0.195 µm), 0.052 (0.037) for the real refractive index, 0.010 (7.20×10-3) for the imaginary part of the refractive index, 0.109 (0.071) for the spherical fraction, and 0.054 (0.039) for the AOD at 532 nm, where the retrievals inside brackets indicate the MAE for noise-free retrievals. For the coarse mode, we find the MAE is 0.459 (0.254) µm for the effective radius (with a mean truth value of 1.970 µm), 0.085 (0.075) for the real refractive index, 2.06×10-4 (1.90×10-4) for the imaginary component, 0.120 (0.090) for the spherical fraction, and 0.051 (0.039) for the AOD. A study of the sensitivity of retrievals to the choice of prior and first guess showed that, on average, the retrieval errors increase when the prior deviates too much from the truth value. These experiments revealed that the measurements primarily contain information on the size and shape of the aerosol, along with the column number. Some information on the real component of the refractive index is also present, with the measurements providing little on absorption or on the effective variance of the aerosol distribution, as both of these were shown to depend heavily on the choice of prior. Retrievals using the HSRL-2 smoke-plume data yielded, for the fine mode, an effective radius of 0.107 µm , a real refractive index of 1.561, an imaginary component of refractive index of 0.010, a spherical fraction of 0.719, and an AOD at 532 nm of 0.505. Additionally, the single-scattering albedo (SSA) from the HSRL-2 retrievals was 0.940. Overall, these results are in good agreement with those from the Spectropolarimeter for Planetary Exploration (SPEX) and Research Scanning Polarimeter (RSP) retrievals. [ABSTRACT FROM AUTHOR]

Published
2021
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238. Efficient multi-angle polarimetric inversion of aerosols and ocean color powered by a deep neural network forward model.

Author

Gao, Meng, Franz, Bryan A., Knobelspiesse, Kirk, Zhai, Peng-Wang, Martins, Vanderlei, Burton, Sharon, Cairns, Brian, Ferrare, Richard, Gales, Joel, Hasekamp, Otto, Hu, Yongxiang, Ibrahim, Amir, McBride, Brent, Puthukkudy, Anin, Werdell, P. Jeremy, and Xu, Xiaoguang

Subjects
*OCEAN color, *ARTIFICIAL neural networks, *OCEAN energy resources, *AEROSOLS, *PLANETARY exploration, *PHYSIOLOGICAL effects of acceleration, *CHROMOSOME inversions, *OCEAN
Abstract

NASA's Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) mission, scheduled for launch in the timeframe of 2023, will carry a hyperspectral scanning radiometer named the Ocean Color Instrument (OCI) and two multi-angle polarimeters (MAPs): the UMBC Hyper-Angular Rainbow Polarimeter (HARP2) and the SRON Spectro-Polarimeter for Planetary EXploration one (SPEXone). The MAP measurements contain rich information on the microphysical properties of aerosols and hydrosols and therefore can be used to retrieve accurate aerosol properties for complex atmosphere and ocean systems. Most polarimetric aerosol retrieval algorithms utilize vector radiative transfer models iteratively in an optimization approach, which leads to high computational costs that limit their usage in the operational processing of large data volumes acquired by the MAP imagers. In this work, we propose a deep neural network (NN) forward model to represent the radiative transfer simulation of coupled atmosphere and ocean systems for applications to the HARP2 instrument and its predecessors. Through the evaluation of synthetic datasets for AirHARP (airborne version of HARP2), the NN model achieves a numerical accuracy smaller than the instrument uncertainties, with a running time of 0.01 s in a single CPU core or 1 ms in a GPU. Using the NN as a forward model, we built an efficient joint aerosol and ocean color retrieval algorithm called FastMAPOL, evolved from the well-validated Multi-Angular Polarimetric Ocean coLor (MAPOL) algorithm. Retrievals of aerosol properties and water-leaving signals were conducted on both the synthetic data and the AirHARP field measurements from the Aerosol Characterization from Polarimeter and Lidar (ACEPOL) campaign in 2017. From the validation with the synthetic data and the collocated High Spectral Resolution Lidar (HSRL) aerosol products, we demonstrated that the aerosol microphysical properties and water-leaving signals can be retrieved efficiently and within acceptable error. Comparing to the retrieval speed using a conventional radiative transfer forward model, the computational acceleration is 103 times faster with CPU or 104 times with GPU processors. The FastMAPOL algorithm can be used to operationally process the large volume of polarimetric data acquired by PACE and other future Earth-observing satellite missions with similar capabilities. [ABSTRACT FROM AUTHOR]

Published
2021
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239. Ensemble-based satellite-derived carbon dioxide and methane column-averaged dry-air mole fraction data sets (2003–2018) for carbon and climate applications.

Author

Reuter, Maximilian, Buchwitz, Michael, Schneising, Oliver, Noël, Stefan, Bovensmann, Heinrich, Burrows, John P., Boesch, Hartmut, Di Noia, Antonio, Anand, Jasdeep, Parker, Robert J., Somkuti, Peter, Wu, Lianghai, Hasekamp, Otto P., Aben, Ilse, Kuze, Akihiko, Suto, Hiroshi, Shiomi, Kei, Yoshida, Yukio, Morino, Isamu, and Crisp, David

Subjects
*MOLE fraction, *CARBON dioxide, *MARINE natural products, *METHANE, *PRODUCT quality, *CLIMATOLOGY, *CARBON cycle
Abstract

Satellite retrievals of column-averaged dry-air mole fractions of carbon dioxide (CO2) and methane (CH4), denoted XCO2 and XCH4 , respectively, have been used in recent years to obtain information on natural and anthropogenic sources and sinks and for other applications such as comparisons with climate models. Here we present new data sets based on merging several individual satellite data products in order to generate consistent long-term climate data records (CDRs) of these two Essential Climate Variables (ECVs). These ECV CDRs, which cover the time period 2003–2018, have been generated using an ensemble of data products from the satellite sensors SCIAMACHY/ENVISAT and TANSO-FTS/GOSAT and (for XCO2) for the first time also including data from the Orbiting Carbon Observatory 2 (OCO-2) satellite. Two types of products have been generated: (i) Level 2 (L2) products generated with the latest version of the ensemble median algorithm (EMMA) and (ii) Level 3 (L3) products obtained by gridding the corresponding L2 EMMA products to obtain a monthly 5∘×5∘ data product in Obs4MIPs (Observations for Model Intercomparisons Project) format. The L2 products consist of daily NetCDF (Network Common Data Form) files, which contain in addition to the main parameters, i.e., XCO2 or XCH4 , corresponding uncertainty estimates for random and potential systematic uncertainties and the averaging kernel for each single (quality-filtered) satellite observation. We describe the algorithms used to generate these data products and present quality assessment results based on comparisons with Total Carbon Column Observing Network (TCCON) ground-based retrievals. We found that the XCO2 Level 2 data set at the TCCON validation sites can be characterized by the following figures of merit (the corresponding values for the Level 3 product are listed in brackets) – single-observation random error (1σ): 1.29 ppm (monthly: 1.18 ppm); global bias: 0.20 ppm (0.18 ppm); and spatiotemporal bias or relative accuracy (1σ): 0.66 ppm (0.70 ppm). The corresponding values for the XCH4 products are single-observation random error (1σ): 17.4 ppb (monthly: 8.7 ppb); global bias: -2.0 ppb (-2.9 ppb); and spatiotemporal bias (1σ): 5.0 ppb (4.9 ppb). It has also been found that the data products exhibit very good long-term stability as no significant long-term bias trend has been identified. The new data sets have also been used to derive annual XCO2 and XCH4 growth rates, which are in reasonable to good agreement with growth rates from the National Oceanic and Atmospheric Administration (NOAA) based on marine surface observations. The presented ECV data sets are available (from early 2020 onwards) via the Climate Data Store (CDS, https://cds.climate.copernicus.eu/ , last access: 10 January 2020) of the Copernicus Climate Change Service (C3S, https://climate.copernicus.eu/ , last access: 10 January 2020). [ABSTRACT FROM AUTHOR]

Published
2020
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240. Satellite observations reveal extreme methane leakage from a natural gas well blowout.

Author

Pandey, Sudhanshu, Gautam, Ritesh, Houweling, Sander, van der Gon, Hugo Denier, Sadavarte, Pankaj, Borsdorff, Tobias, Hasekamp, Otto, Landgraf, Jochen, Tol, Paul, van Kempen, Tim, Hoogeveen, Ruud, van Hees, Richard, Hamburg, Steven P., Maasakkers, Joannes D., and Aben, Ilse

Subjects
*GAS wells, *METHANE, *NATURAL gas, *GAS industry, *EMISSION inventories
Abstract

Methane emissions due to accidents in the oil and natural gas sector are very challenging tomonitor, and hence are seldomconsidered in emission inventories and reporting. One of the main reasons is the lack of measurements during such events. Here we report the detection of large methane emissions from a gas well blowout in Ohio during February to March 2018 in the total column methane measurements from the spaceborne Tropospheric Monitoring Instrument (TROPOMI). From these data, we derive a methane emission rate of 120 ± 32 metric tons per hour. This hourly emission rate is twice that of the widely reported Aliso Canyon event in California in 2015. Assuming the detected emission represents the average rate for the 20-d blowout period, we find the total methane emission from the well blowout is comparable to one-quarter of the entire state of Ohio's reported annual oil and natural gas methane emission, or, alternatively, a substantial fraction of the annual anthropogenic methane emissions from several European countries. Our work demonstrates the strength and effectiveness of routine satellite measurements in detecting and quantifying greenhouse gas emission from unpredictable events. In this specific case, the magnitude of a relatively unknown yet extremely large accidental leakage was revealed using measurements of TROPOMI in its routine global survey, providing quantitative assessment of associated methane emissions. [ABSTRACT FROM AUTHOR]

Published
2019
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241. The Plankton, Aerosol, Cloud, Ocean Ecosystem Mission: Status, Science, Advances.

Author

Werdell, P. Jeremy, Behrenfeld, Michael J., Bontempi, Paula S., Boss, Emmanuel, Cairns, Brian, Davis, Gary T., Franz, Bryan A., Gliese, Ulrik B., Gorman, Eric T., Hasekamp, Otto, Knobelspiesse, Kirk D., Mannino, Antonio, Martins, J. Vanderlei, McClain, Charles R., Meister, Gerhard, and Remer, Lorraine A.

Subjects
*OCEAN color, *AEROSOLS, *WATER quality, *OCEAN, *RADIATIVE forcing, *CARBON cycle, *FISHERY management
Abstract

The Plankton, Aerosol, Cloud, Ocean Ecosystem (PACE) mission represents the National Aeronautics and Space Administration's (NASA) next investment in satellite ocean color and the study of Earth's ocean–atmosphere system, enabling new insights into oceanographic and atmospheric responses to Earth's changing climate. PACE objectives include extending systematic cloud, aerosol, and ocean biological and biogeochemical data records, making essential ocean color measurements to further understand marine carbon cycles, food-web processes, and ecosystem responses to a changing climate, and improving knowledge of how aerosols influence ocean ecosystems and, conversely, how ocean ecosystems and photochemical processes affect the atmosphere. PACE objectives also encompass management of fisheries, large freshwater bodies, and air and water quality and reducing uncertainties in climate and radiative forcing models of the Earth system. PACE observations will provide information on radiative properties of land surfaces and characterization of the vegetation and soils that dominate their reflectance. The primary PACE instrument is a spectrometer that spans the ultraviolet to shortwave-infrared wavelengths, with a ground sample distance of 1 km at nadir. This payload is complemented by two multiangle polarimeters with spectral ranges that span the visible to near-infrared region. Scheduled for launch in late 2022 to early 2023, the PACE observatory will enable significant advances in the study of Earth's biogeochemistry, carbon cycle, clouds, hydrosols, and aerosols in the ocean–atmosphere–land system. Here, we present an overview of the PACE mission, including its developmental history, science objectives, instrument payload, observatory characteristics, and data products. [ABSTRACT FROM AUTHOR]

Published
2019
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242. Polarimetric remote sensing of atmospheric aerosols: Instruments, methodologies, results, and perspectives.

Author

Dubovik, Oleg, Li, Zhengqiang, Mishchenko, Michael I., Tanré, Didier, Karol, Yana, Bojkov, Bojan, Cairns, Brian, Diner, David J., Espinosa, W. Reed, Goloub, Philippe, Gu, Xingfa, Hasekamp, Otto, Hong, Jin, Hou, Weizhen, Knobelspiesse, Kirk D., Landgraf, Jochen, Li, Li, Litvinov, Pavel, Liu, Yi, and Lopatin, Anton

Subjects
*POLARIMETRIC remote sensing, *ATMOSPHERIC aerosols, *POLARIMETRY, *POLARIZATION (Electricity), *OPTICAL polarization
Abstract

Highlights • This article overviews polarimetric observations, their history and expected developments, and resulting aerosol products. • The paper was conceived during the workshop APOLO-2017 held in Hefei, China, in October 2017. Abstract Polarimetry is one of the most promising types of remote sensing for improved characterization of atmospheric aerosol. Indeed, aerosol particles constitute a highly variable atmospheric component characterized by a large number of parameters describing particle sizes, morphologies (including shape and internal structure), absorption and scattering properties, amounts, horizontal and vertical distribution, etc. Reliable monitoring of all these parameters is very challenging, and therefore the aerosol effects on climate and environment are considered to be among the most uncertain factors in climate and environmental research. In this regard, observations that provide both the angular distribution of the scattered atmospheric radiation as well as its polarization state at multiple wavelengths covering the UV–SWIR spectral range carry substantial implicit information on the atmospheric composition. Therefore, high expectations in improving aerosol characterization are associated with detailed passive photopolarimetric observations. The critical need to use space-borne polarimetry for global accurate monitoring of detailed aerosol properties was first articulated in the late 1980s and early 1990s. By now, several orbital instruments have already provided polarization observations from space, and a number of advanced missions are scheduled for launch in the coming years by international and national space agencies. The first and most extensive record of polarimetric imagery was provided by POLDER-I, POLDER-II, and POLDER/PARASOL multi-angle multi-spectral polarization sensors. Polarimetric observations with the POLDER-like design intended for collecting extensive multi-angular multi-spectral measurements will be provided by several instruments, such as the MAI/TG-2, CAPI/TanSat, and DPC/GF-5 sensors recently launched by the Chinese Space Agency. Instruments such as the 3MI/MetOp-SG, MAIA, SpexOne and HARP2 on PACE, POSP, SMAC, PCF, DPC–Lidar, ScanPol and MSIP/Aerosol-UA, MAP/Copernicus CO2 Monitoring, etc. are planned to be launched by different space agencies in the coming decade. The concepts of these future instruments, their technical designs, and the accompanying algorithm development have been tested intensively and analyzed using diverse airborne prototypes. Certain polarimetric capabilities have also been implemented in such satellite sensors as GOME-2/MetOp and SGLI/GCOM-C. A number of aerosol retrieval products have been developed based on the available measurements and successfully used for different scientific applications. However, the completeness and accuracy of aerosol data operationally derived from polarimetry do not yet appear to have reached the accuracy levels implied by theoretical sensitivity studies that analyzed the potential information content of satellite polarimetry. As a result, the dataset provided by MODIS is still most frequently used by the scientific community, yet this sensor has neither polarimetric nor multi-angular capabilities. Admittedly polarimetric multi-angular observations are highly complex and have extra sensitivities to aerosol particle morphology, vertical variability of aerosol properties, polarization of surface reflectance, etc. As such, they necessitate state-of-the-art forward modeling based on first-principles physics which remains rare, and conventional retrieval approaches based on look-up tables turn out to be unsuitable to fully exploit the information implicit in the measurements. Several new-generation retrieval approaches have recently been proposed to address these challenges. These methods use improved forward modeling of atmospheric (polarized) radiances and implement a search in the continuous space of solutions using rigorous statistically optimized inversions. Such techniques provide more accurate retrievals of the main aerosol parameters such as aerosol optical thickness and yield additional parameters such as aerosol absorption. However, the operational implementation of advanced retrieval approaches generally requires a significant extra effort, and the forward-modeling part of such retrievals still needs to be substantially improved. Ground-based passive polarimetric measurements have also been evolving over the past decade. Although polarimetry helps improve aerosol characterization, especially of the fine aerosol mode, the operators of major observational networks such as AERONET remain reluctant to include polarimetric measurements as part of routine retrievals owing to their high complexity and notable increase in effort required to acquire and interpret polarization data. In addition to remote-sensing observations, polarimetric characteristics of aerosol scattering have been measured in situ as well as in the laboratory using polar nephelometers. Such measurements constitute direct observations of single scattering with no contributions from multiple scattering effects and therefore provide unique data for the validation of aerosol optical models and retrieval concepts. This article overviews the above-mentioned polarimetric observations, their history and expected developments, and the state of resulting aerosol products. It also discusses the main achievements and challenges in the exploitation of polarimetry for the improved characterization of atmospheric aerosols. [ABSTRACT FROM AUTHOR]

Published
2019
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243. The polarization crossfire (PCF) sensor suite focusing on satellite remote sensing of fine particulate matter PM2.5 from space.

Author

Li, Zhengqiang, Hou, Weizhen, Hong, Jin, Fan, Cheng, Wei, Yuanyuan, Liu, Zhenhai, Lei, Xuefeng, Qiao, Yanli, Hasekamp, Otto P., Fu, Guangliang, Wang, Jun, Dubovik, Oleg, Qie, LiLi, Zhang, Ying, Xu, Hua, Xie, Yisong, Song, Maoxin, Zou, Peng, Luo, Donggen, and Wang, Yi

Subjects
*REMOTE sensing, *PARTICULATE matter, *POLARIMETRY, *DETECTORS, *REFRACTIVE index, *AEROSOLS, *TELECOMMUNICATION satellites
Abstract

• PCF suite is the first dedicated satellite sensor for PM 2.5 remote sensing. • The principle of PCF composed by DPC and POSP are described. • Retrievals of aerosols and PM 2.5 by PMRS model are investigated. • The errors propagation from aerosols to PM 2.5 retrievals are discussed. Focusing on satellite remote sensing of fine particulate matter PM 2.5 from space, the polarization crossfire (PCF) strategy has been developed, which includes the PCF satellite suite and the particulate matter remote sensing (PMRS) model. Expected to be the first dedicated satellite sensor for PM 2.5 remote sensing globally, the PCF suite is composed by the Particulate Observing Scanning Polarimeter (POSP) and the Directional Polarimetric Camera (DPC) together, and will be launched on board the Chinese GaoFen-5(02) satellite in 2021. Since the cross-track polarimetric measurements of POSP fully cover the multi-viewing swath of DPC, the sophisticated joint measurements could be obtained from the PCF suite in the range of 380–2250 nm including intensity and polarization, by the means of pixel matching and the cross calibration from POSP to DPC. Based on the optimal estimation inversion framework and synthetic data of PCF, the retrieval performances of key aerosol parameters are systematically investigated and assessed for the PM 2.5 estimation by the PMRS model. For the design of inversion strategy for PCF, we firstly test the retrievals of aerosol optical depth (AOD), fine mode fraction (FMF), aerosol layer height (H) and the fine-mode real part of complex refractive index (m r f) simultaneously with surface parameters from the synthetic PCF data, and then the columnar volume-to-extinction ratio of fine particulates (VE f), the aerosol effective density (ρ f) and the hygroscopic growth factor of fine-mode particles (f (RH)) are further obtained by the corresponding empirical relationship. The propagation errors from aerosol parameters to PM 2.5 retrieval are investigated with the key procedures of PMRS model. In addition, the influences of improving calibration accuracy of PCF on PM 2.5 retrievals are discussed, as well as the retrieval feasibility of PM 10 by PCF strategy. [ABSTRACT FROM AUTHOR]

Published
2022
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244. Passive remote sensing of aerosol layer height using near-UV multi-angle polarization measurements.

Author

Wu L, Hasekamp O, van Diedenhoven B, Cairns B, Yorks JE, and Chowdhary J

Abstract

We demonstrate that multi-angle polarization measurements in the near-UV and blue part of the spectrum are very well suited for passive remote sensing of aerosol layer height. For this purpose we use simulated measurements with different set-ups (different wavelength ranges, with and without polarization, different polarimetric accuracies) as well as airborne measurements from the Research Scanning Polarimeter (RSP) obtained over the continental USA. We find good agreement of the retrieved aerosol layer height from RSP with measurements from the Cloud Physics Lidar (CPL) showing a mean absolute difference of less than 1 km. Furthermore, we found that the information on aerosol layer height is provided for large part by the multi-angle polarization measurements with high accuracy rather than the multi-angle intensity measurements. The information on aerosol layer height is significantly decreased when the shortest RSP wavelength (410 nm) is excluded from the retrieval and is virtually absent when 550 nm is used as shortest wavelength.

Published
2016
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