Your search keyword '"Barret, Brice"' showing total 9 results

1. Investigation of the impact of satellite vertical sensitivity on long-term retrieved lower-tropospheric ozone trends.

Author

Pope, Richard J., O'Connor, Fiona M., Dalvi, Mohit, Kerridge, Brian J., Siddans, Richard, Latter, Barry G., Barret, Brice, Le Flochmoen, Eric, Boynard, Anne, Chipperfield, Martyn P., Feng, Wuhu, Pimlott, Matilda A., Dhomse, Sandip S., Retscher, Christian, Wespes, Catherine, and Rigby, Richard

Subjects

AIR pollutants, RADIATIVE transfer, OZONE, TIME series analysis, TROPOSPHERIC ozone, TROPOSPHERE

Abstract

Ozone is a potent air pollutant in the lower troposphere and an important short-lived climate forcer (SLCF) in the upper troposphere. Studies investigating long-term trends in the tropospheric column ozone (TCO 3) have shown large-scale spatio-temporal inconsistencies. Here, we investigate the long-term trends in lower-tropospheric column ozone (LTCO 3 , surface–450 hPa sub-column) by exploiting a synergy of satellite and ozonesonde data sets and an Earth system model (UK's Earth System Model, UKESM) over North America, Europe, and East Asia for the decade 2008–2017. Overall, we typically find small LTCO 3 linear trends with large uncertainty ranges using the Ozone Monitoring Instrument (OMI) and the Infrared Atmospheric Sounding Interferometer (IASI), while model simulations indicate a stable LTCO 3 tendency. The satellite a priori data sets show negligible trends, indicating that any year-to-year changes in the spatio-temporal sampling of these satellite data sets over the period concerned have not artificially influenced their LTCO 3 temporal evolution. The application of the satellite averaging kernels (AKs) to the UKESM simulated ozone profiles, accounting for the satellite vertical sensitivity and allowing for like-for-like comparisons, has a limited impact on the modelled LTCO 3 tendency in most cases. While, in relative terms, this is more substantial (e.g. on the order of 100 %), the absolute magnitudes of the model trends show negligible change. However, as the model has a near-zero tendency, artificial trends were imposed on the model time series (i.e. LTCO 3 values rearranged from smallest to largest) to test the influence of the AKs, but simulated LTCO 3 trends remained small. Therefore, the LTCO 3 tendencies between 2008 and 2017 in northern-hemispheric regions are likely to be small, with large uncertainties, and it is difficult to detect any small underlying linear trends due to interannual variability or other factors which require further investigation (e.g. the radiative transfer scheme (RTS) used and/or the inputs (e.g. meteorological fields) used in the RTS). [ABSTRACT FROM AUTHOR]

Published

2024

2. Investigation of satellite vertical sensitivity on long-term retrieved lower tropospheric ozone trends.

Author

Pope, Richard J., O'Connor, Fiona M., Dalvi, Mohit, Kerridge, Brian J., Siddans, Richard, Latter, Barry G., Barret, Brice, Flochmoen, Eric Le, Boynard, Anne, Chipperfield, Martyn P., Feng, Wuhu, Pimlott, Matilda A., Dhomse, Sandip S., Retscher, Christian, Wespes, Catherine, and Rigby, Richard

Subjects

TROPOSPHERIC ozone, AIR pollutants, OZONE, TROPOSPHERE

Abstract

Ozone is a potent air pollutant in the lower troposphere and an important short-lived climate forcer (SLCF) in the upper troposphere. Studies investigating long-term trends in tropospheric column ozone (TCO3) have shown large-scale spatiotemporal inconsistencies. Here, we investigate the long-term trends in lower tropospheric column ozone (LTCO3, surface-450 hPa sub-column) by exploiting a synergy of satellite and ozonesonde datasets and an Earth System Model (UKESM) over North America, Europe and East Asia for the decade 2008–2017. Overall, we typically find small LTCO3 linear trends with large uncertainty ranges from the Ozone Monitoring Instrument (OMI) and the Infrared Atmospheric Sounding Interferometer (IASI), while model simulations indicate a stable LTCO3 tendency. Trends in the satellite a priori datasets show negligible trends indicating year-to-year sampling is not an issue. The application of the satellite averaging kernels (AKs) to the UKESM ozone profiles, accounting for the satellite vertical sensitivity and allowing for like-for-like comparisons, has a limited impact on the modelled LTCO3 tendency in most cases. While, in relative terms, this is more substantial (e.g. in the order of 100 %), the absolute magnitudes of the model trends show negligible change. However, as the model has a near-zero tendency, artificial trends were imposed on the model time-series (i.e. LTCO3 values rearranged from smallest to largest) to test the influence of the AKs but simulated LTCO3 trends remained small. Therefore, the LTCO3 tendency between 2008 and 2017 in northern hemispheric regions are likely small, with large uncertainties, and it is difficult to detect any small underlying linear trends due to inter-annual variability or other factors which require further investigation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Quantifying the tropospheric ozone radiative effect and its temporal evolution in the satellite-era.

Author

Pope, Richard J., Rap, Alexandru, Pimlott, Matilda A., Barret, Brice, Flochmoen, Eric Le, Kerridge, Brian J., Siddans, Richard, Latter, Barry G., Ventress, Lucy J., Boynard, Anne, Retscher, Christian, Feng, Wuhu, Rigby, Richard, Dhomse, Sandip S., Wespes, Catherine, and Chipperfield, Martyn P.

Subjects

TROPOSPHERIC ozone, ATMOSPHERIC chemistry, CHEMICAL models, OZONE, METEOROLOGY, TROPOSPHERE

Abstract

Using state-of-the-art satellite ozone profile products, and chemical transport model, we provide an updated estimate of the tropospheric ozone radiative effect (TO3RE) and observational constraint on its variability over the decade 2008–2017. Previous studies have shown the short-term (i.e. a few years) globally weighted average TO3RE to be 1.17±0.03 W/m2, while our analysis suggests that the long-term (2008–2017) average TO3RE to be 1.21–1.28 W/m2. Over this decade, the modelled/observational TO3RE linear trends show negligible change (i.e. ±0.1 %/year), so the tropospheric ozone radiative contribution to climate has remained stable with time. Two model sensitivity experiments fixing emissions and meteorology to one year (i.e. start year – 2008) show that ozone precursor emissions (meteorological factors) have had limited (substantial) impacts on the long-term tendency of globally weighted average TO3RE. Here, the meteorological variability in the tropical/sub-tropical upper troposphere is dampening any tendency in TO3RE from other factors (e.g. emissions, atmospheric chemistry). [ABSTRACT FROM AUTHOR]

Published

2023

4. GLOBAL CHEMISTRY SIMULATIONS IN THE AMMA MULTIMODEL INTERCOMPARISON PROJECT

Author

Williams, Jason Edward, Scheele, Rinus, van Velthoven, Peter, Bouarar, Idir, Law, Kathy, Josse, Béatrice, Peuch, Vincent-Henri, Yang, Xin, Pyle, John, Thouret, Valérie, Barret, Brice, Liousse, Cathy, Hourdin, Frédéric, Szopa, Sophie, and Cozic, Anne

Published

2010

5. Origins and characterization of CO and O3 in the African upper troposphere

Author

Lannuque, Victor, Sauvage, Bastien, Barret, Brice, Clark, Hannah, Athier, Gilles, Petetin, Hervé, and Barcelona Supercomputing Center

Subjects

Ozone, Ozó, Capa d' -- Aspectes ambientals -- Models matemàtics, Anthropogenic CO, Troposphere, Enginyeria agroalimentària::Ciències de la terra i de la vida [Àrees temàtiques de la UPC], Africa, African intertropical troposphere, Greenhouse effect, Atmospheric, Local fires, Carbon monoxide

Abstract

Between December 2005 and 2013, the In-service Aircraft for a Global Observing System (IAGOS) program produced almost daily in situ measurements of CO and O3 between Europe and southern Africa. IAGOS data combined with measurements from the Infrared Atmospheric Sounding Interferometer (IASI) instrument aboard the Metop-A satellite (2008–2013) are used to characterize meridional distributions and seasonality of CO and O3 in the African upper troposphere (UT). The FLEXPART particle dispersion model and the SOFT-IO model which combines the FLEXPART model with CO emission inventories are used to explore the sources and origins of the observed transects of CO and O3. We focus our analysis on two main seasons: December to March (DJFM) and June to October (JJASO). These seasons have been defined according to the position of Intertropical Convergence Zone (ITCZ), determined using in situ measurements from IAGOS. During both seasons, the UT CO meridional transects are characterized by maximum mixing ratios located 10∘ from the position of the ITCZ above the dry regions inside the hemisphere of the strongest Hadley cell (132 to 165 ppb at 0–5∘ N in DJFM and 128 to 149 ppb at 3–7∘ S in JJASO) and decreasing values southward and northward. The O3 meridional transects are characterized by mixing ratio minima of ∼42–54 ppb at the ITCZ (10–16∘ S in DJFM and 5–8∘ N in JJASO) framed by local maxima (∼53–71 ppb) coincident with the wind shear zones north and south of the ITCZ. O3 gradients are strongest in the hemisphere of the strongest Hadley cell. IASI UT O3 distributions in DJFM have revealed that the maxima are a part of a crescent-shaped O3 plume above the Atlantic Ocean around the Gulf of Guinea. CO emitted at the surface is transported towards the ITCZ by the trade winds and then convectively uplifted. Once in the upper troposphere, CO-enriched air masses are transported away from the ITCZ by the upper branches of the Hadley cells and accumulate within the zonal wind shear zones where the maximum CO mixing ratios are found. Anthropogenic and fires both contribute, by the same order of magnitude, to the CO budget of the African upper troposphere. Local fires have the highest contribution and drive the location of the observed UT CO maxima. Anthropogenic CO contribution is mostly from Africa during the entire year, with a low seasonal variability. There is also a large contribution from Asia in JJASO related to the fast convective uplift of polluted air masses in the Asian monsoon region which are further westward transported by the tropical easterly jet (TEJ) and the Asian monsoon anticyclone (AMA). O3 minima correspond to air masses that were recently uplifted from the surface where mixing ratios are low at the ITCZ. The O3 maxima correspond to old high-altitude air masses uplifted from either local or long-distance area of high O3 precursor emissions (Africa and South America during all the year, South Asia mainly in JJASO) and must be created during transport by photochemistry. This research has been supported by the European Union's Horizon 2020 research and innovation program under Marie Skłodowska-Curie grant agreement H2020-MSCA-COFUND-2016-754433. Peer Reviewed "Article signat per 17 autors/es: Victor Lannuque, Bastien Sauvage, Brice Barret, Hannah Clark, Gilles Athier, Damien Boulanger, Jean-Pierre Cammas, Jean-Marc Cousin, Alain Fontaine, Eric Le Flochmoën, Philippe Nédélec, Hervé Petetin, Isabelle Pfaffenzeller, Susanne Rohs, Herman G. J. Smit, Pawel Wolff, and Valérie Thouret"

Published

2021

6. The effects of the COVID-19 lockdowns on the composition of the troposphere as seen by In-service Aircraft for a Global Observing System (IAGOS) at Frankfurt.

Author

Clark, Hannah, Bennouna, Yasmine, Tsivlidou, Maria, Wolff, Pawel, Sauvage, Bastien, Barret, Brice, Le Flochmoën, Eric, Blot, Romain, Boulanger, Damien, Cousin, Jean-Marc, Nédélec, Philippe, Petzold, Andreas, and Thouret, Valérie

Subjects

STAY-at-home orders, TROPOSPHERE, COVID-19 pandemic, CARBON monoxide, ATMOSPHERIC composition, QUASI-biennial oscillation (Meteorology), DIAMOND wheels

Abstract

The European research infrastructure IAGOS (In-service Aircraft for a Global Observing System) equips commercial aircraft with a system for measuring atmospheric composition. A range of essential climate variables and air quality parameters are measured throughout the flight, from take-off to landing, giving high-resolution information in the vertical in the vicinity of international airports and in the upper troposphere–lower stratosphere during the cruise phase of the flight. Six airlines are currently involved in the programme, achieving a quasi-global coverage under normal circumstances. During the COVID-19 crisis, many airlines were forced to ground their fleets due to a fall in passenger numbers and imposed travel restrictions. Deutsche Lufthansa, a partner in IAGOS since 1994 was able to operate an IAGOS-equipped aircraft during the COVID-19 lockdown, providing regular measurements of ozone and carbon monoxide at Frankfurt Airport. The data form a snapshot of an unprecedented time in the 27-year time series. In May 2020, we see a 32 % increase in ozone near the surface with respect to a recent reference period, a magnitude similar to that of the 2003 heatwave. The anomaly in May is driven by an increase in ozone at nighttime which might be linked to the reduction in NO during the COVID-19 lockdowns. The anomaly diminishes with altitude becoming a slightly negative anomaly in the free troposphere. The ozone precursor carbon monoxide shows an 11 % reduction in MAM (March–April–May) near the surface. There is only a small reduction in CO in the free troposphere due to the impact of long-range transport on the CO from emissions in regions outside Europe. This is confirmed by data from the Infrared Atmospheric Sounding Interferometer (IASI) using retrievals performed by SOftware for a Fast Retrieval of IASI Data (SOFRID), which display a clear drop of CO at 800 hPa over Europe in March but otherwise show little change to the abundance of CO in the free troposphere. [ABSTRACT FROM AUTHOR]

Published

2021

7. Multi-year assimilation of IASI and MLS ozone retrievals: variability of tropospheric ozone over the tropics in response to ENSO.

Author

Peiro, Hélène, Emili, Emanuele, Cariolle, Daniel, Barret, Brice, and Le Flochmoën, Eric

Subjects

TROPOSPHERE, ATMOSPHERIC ozone, ATMOSPHERE, TROPOSPHERIC ozone, OZONE layer

Abstract

The Infrared Atmospheric Sounder Instrument (IASI) allows global coverage with very high spatial resolution and its measurements are promising for long-term ozone monitoring. In this study, Microwave Limb Sounder (MLS) O3 profiles and IASI O3 partial columns (1013.25–345 hPa) are assimilated in a chemistry transport model to produce 6-hourly analyses of tropospheric ozone for 6 years (2008–2013). We have compared and evaluated the IASI-MLS analysis and the MLS analysis to assess the added value of IASI measurements. The global chemical transport model MOCAGE (MOdèle de Chimie Atmosphérique à Grande Echelle) has been used with a linear ozone chemistry scheme and meteorological forcing fields from ERA-Interim (ECMWF global reanalysis) with a horizontal resolution of 2°  ×  2° and 60 vertical levels. The MLS and IASI O3 retrievals have been assimilated with a 4-D variational algorithm to constrain stratospheric and tropospheric ozone respectively. The ozone analyses are validated against ozone soundings and tropospheric column ozone (TCO) from the OMI-MLS residual method. In addition, an Ozone ENSO Index (OEI) is computed from the analysis to validate the TCO variability during the ENSO events. We show that the assimilation of IASI reproduces the variability of tropospheric ozone well during the period under study. The variability deduced from the IASI-MLS analysis and the OMI-MLS measurements are similar for the period of study. The IASI-MLS analysis can reproduce the extreme oscillation of tropospheric ozone caused by ENSO events over the tropical Pacific Ocean, although a correction is required to reduce a constant bias present in the IASI-MLS analysis. [ABSTRACT FROM AUTHOR]

Published

2018

8. Upper-tropospheric CO and O3 budget during the Asian summer monsoon.

Author

Barret, Brice, Sauvage, Bastien, Bennouna, Yasmine, and Le Flochmoen, Eric

Subjects

MONSOONS, TROPOSPHERE, CARBON monoxide, ANTICYCLONES

Abstract

During the Asian summer monsoon, the circulation in the upper troposphere/lower stratosphere (UTLS) is dominated by the Asian monsoon anticyclone (AMA). Pollutants convectively uplifted to the upper troposphere are trapped within this anticyclonic circulation that extends from the Pacific Ocean to the Eastern Mediterranean basin. Among the uplifted pollutants are ozone (O3) and its precursors, such as carbon monoxide (CO) and nitrogen oxides (NOx). Many studies based on global modeling and satellite data have documented the source regions and transport pathways of primary pollutants (CO, HCN) into the AMA. Here, we aim to quantify the O3 budget by taking into consideration anthropogenic and natural sources. We first use CO and O3 data from the MetOp-A/IASI sensor to document their tropospheric distributions over Asia, taking advantage of the useful information they provide on the vertical dimension. These satellite data are used together with MOZAIC tropospheric profiles recorded in India to validate the distributions simulated by the global GEOS-Chem chemistry transport model. Over the Asian region, UTLS monthly CO and O3 distributions from IASI and GEOS-Chem display the same large-scale features. UTLS CO columns from GEOS-Chem are in agreement with IASI, with a low bias of 11±9% and a correlation coefficient of 0.70. For O3, the model underestimates IASI UTLS columns over Asia by 14±26% but the correlation between both is high (0.94). GEOS-Chem is further used to quantify the CO and O3 budget through sensitivity simulations. For CO, these simulations confirm that South Asian anthropogenic emissions have a more important impact on enhanced concentrations within the AMA (~25 ppbv) than East Asian emissions (~10 ppbv). The correlation between enhanced emissions over the Indo-Gangetic Plain and monsoon deep convection is responsible for this larger impact. Consistently, South Asian anthropogenic NOx emissions also play a larger role in producing O3 within the AMA (~8 ppbv) than East Asian emissions (~5 ppbv), but Asian lightning-produced NOx is responsible for the largest O3 production (10-14 ppbv). Stratosphere-to-troposphere exchanges are also important in transporting O3 in the upper part of the AMA. [ABSTRACT FROM AUTHOR]

Published

2016

9. Retrieval of Metop-A/IASI N 2 O Profiles and Validation with NDACC FTIR Data.

Author

Barret, Brice, Gouzenes, Yvan, Le Flochmoen, Eric, Ferrant, Sylvain, Havemann, Stephan, and Garcia-Comas, Maya

Subjects

*ATMOSPHERIC composition, *INFORMATION retrieval, *STATISTICAL correlation, *TROPOSPHERE, *REMOTE sensing, *TREND analysis

Abstract

This paper reports atmospheric profiles of N 2 O retrieved from Metop/IASI with the Software for the Retrieval of IASI Data (SOFRID) for the 2008–2018 period and their validation with FTIR data from 12 stations of the Network for the Detection of Atmospheric Composition Changes (NDACC). SOFRID retrievals performed in the 2160–2218 cm − 1 spectral window provide 3 independent pieces of information about the vertical profile of N 2 O. The FTIR versus SOFRID comparisons display a better agreement in the mid-troposphere (MT, 700–350 hPa) than in the lower (LT, Surface–700 hPa) and upper (UT, 350–110 hPa) troposphere with correlation coefficients (R) in the 0.49–0.83 range and comparable variabilities (3–5 ppbv). The agreement for oceanic and coastal stations (R > 0.77) is better than for continental ones (R < 0.72). The SOFRID MT N 2 O mixing ratios are significantly biased high (up to 16.8 ppbv) relative to FTIR at continental stations while the biases remain below 4.2 ppbv and mostly unsignificant when oceanic data are considered. The average MT decadal trends derived from SOFRID at the 8 NDACC stations with continuous observations during the 2008–2018 period (1.05 ± 0.1 ppbv·yr − 1 ) is in good agreement with the corresponding FTIR trends (1.08 ± 0.1 ppbv·yr − 1 ) and the NOAA-ESRL trends from surface in-situ measurements (0.95 ± 0.02 ppbv·yr − 1 ). In the Northern Hemisphere where they are clearly detected, the N 2 O MT seasonal variations from SOFRID and FTIR are phased (summer minima) and have similar amplitudes. SOFRID also detects the UT summer maxima indicating independent MT and UT information. The global MT N 2 O oceanic distributions from SOFRID display low geographical variability and are mainly characterized by enhanced tropical mixing ratios relative to mid and high latitudes. [ABSTRACT FROM AUTHOR]

Published

2021