Your search keyword '"Ginoux P"' showing total 43 results

1. Preliminary study of electrochemical conversion of glucose on novel modified nickel electrodes

Author

Ginoux, Erwann, Acosta, Gabriel, Cognet, Patrick, Pérès, Yolande, Latapie, Laure, Estel, Lionel, and Ledoux, Alain

Published

2024

2. A global–land snow scheme (GLASS) v1.0 for the GFDL Earth System Model: formulation and evaluation at instrumented sites

Author

E. Zorzetto, S. Malyshev, P. Ginoux, and E. Shevliakova

Subjects

Geology, QE1-996.5

Abstract

Snowpacks modulate water storage over extended land regions and at the same time play a central role in the surface albedo feedback, impacting the climate system energy balance. Despite the complexity of snow processes and their importance for both land hydrology and global climate, several state-of-the-art land surface models and Earth System Models still employ relatively simple descriptions of the snowpack dynamics. In this study we present a newly-developed snow scheme tailored to the Geophysical Fluid Dynamics Laboratory (GFDL) land model version 4.1. This new snowpack model, named GLASS (Global LAnd–Snow Scheme), includes a refined and dynamical vertical-layering snow structure that allows us to track the temporal evolution of snow grain properties in each snow layer, while at the same time limiting the model computational expense, as is necessary for a model suited to global-scale climate simulations. In GLASS, the evolution of snow grain size and shape is explicitly resolved, with implications for predicted bulk snow properties, as they directly impact snow depth, snow thermal conductivity, and optical properties. Here we describe the physical processes in GLASS and their implementation, as well as the interactions with other surface processes and the land–atmosphere coupling in the GFDL Earth System Model. The performance of GLASS is tested over 10 experimental sites, where in situ observations allow for a comprehensive model evaluation. We find that when compared to the current GFDL snow model, GLASS improves predictions of seasonal snow water equivalent, primarily as a consequence of improved snow albedo. The simulated soil temperature under the snowpack also improves by about 1.5 K on average across the sites, while a negative bias of about 1 K in snow surface temperature is observed.

Published

2024

3. A Poincar\'e formula for differential forms and applications

Author

Ginoux, Nicolas, Habib, Georges, and Raulot, Simon

Subjects

Mathematics - Differential Geometry, Mathematics - Analysis of PDEs, 53C21, 53C24, 58J32, 58J50

Abstract

We prove a new general Poincar\'e-type inequality for differential forms on compact Riemannian manifolds with nonempty boundary. When the boundary is isometrically immersed in Euclidean space, we derive a new inequality involving mean and scalar curvatures of the boundary only and characterize its limiting case in codimension one. A new Ros-type inequality for differential forms is also derived assuming the existence of a nonzero parallel form on the manifold.

Published

2023

4. On the Cauchy problem for the Fadaray tensor on globally hyperbolic manifolds with timelike boundary

Author

Drago, Nicoló, Ginoux, Nicolas, and Murro, Simone

Subjects

Mathematics - Analysis of PDEs, Mathematical Physics, Mathematics - Differential Geometry, Primary 35Q61, 35N30, Secondary 58J45, 53C50

Abstract

We study the well-posedness of the Cauchy problem for the Faraday tensor on globally hyperbolic manifolds with timelike boundary. The existence of Green operators for the operator $\mathrm{d}+\delta$ and a suitable pre-symplectic structure on the space of solutions are discussed., Comment: 19 pages -- accepted in Rendiconti Lincei Matematica e Applicazioni

Published

2023

5. Characterization of the particle size distribution, mineralogy, and Fe mode of occurrence of dust-emitting sediments from the Mojave Desert, California, USA

Author

A. González-Romero, C. González-Flórez, A. Panta, J. Yus-Díez, P. Córdoba, A. Alastuey, N. Moreno, M. Hernández-Chiriboga, K. Kandler, M. Klose, R. N. Clark, B. L. Ehlmann, R. N. Greenberger, A. M. Keebler, P. Brodrick, R. Green, P. Ginoux, X. Querol, and C. Pérez García-Pando

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Constraining dust models to understand and quantify the effect of dust upon climate and ecosystems requires comprehensive analyses of the physiochemical properties of dust-emitting sediments in arid regions. Building upon previous studies in the Moroccan Sahara and Iceland, we analyse a diverse set of crusts and aeolian ripples (n=55) from various potential dust-emitting basins within the Mojave Desert, California, USA. Our focus is on characterizing the particle size distribution (PSD), mineralogy, aggregation/cohesion state, and Fe mode of occurrence. Our results show differences in fully and minimally dispersed PSDs, with crusts exhibiting average median diameters of 92 and 37 µm, respectively, compared to aeolian ripples with 226 and 213 µm, respectively. Mineralogical analyses unveiled strong variations between crusts and ripples, with crusts being enriched in phyllosilicates (24 % vs. 7.8 %), carbonates (6.6 % vs. 1.1 %), Na salts (7.3 % vs. 1.1 %), and zeolites (1.2 % and 0.12 %) and ripples being enriched in feldspars (48 % vs. 37 %), quartz (32 % vs. 16 %), and gypsum (4.7 % vs. 3.1 %). The size fractions from crust sediments display a homogeneous mineralogy, whereas those of aeolian ripples display more heterogeneity, mostly due to different particle aggregation. Bulk Fe content analyses indicate higher concentrations in crusts (3.0 ± 1.3 wt %) compared to ripples (1.9 ± 1.1 wt %), with similar proportions in their Fe mode of occurrence: nano-sized Fe oxides and readily exchangeable Fe represent ∼1.6 %, hematite and goethite ∼15 %, magnetite/maghemite ∼2.0 %, and structural Fe in silicates ∼80 % of the total Fe. We identified segregation patterns in the PSD and mineralogy differences in Na salt content within the Mojave basins, which can be explained by sediment transportation dynamics and precipitates due to groundwater table fluctuations described in previous studies in the region. Mojave Desert crusts show similarities with previously sampled crusts in the Moroccan Sahara in terms of the PSD and readily exchangeable Fe yet exhibit substantial differences in mineralogical composition, which should significantly influence the characteristic of the emitted dust particles.

Published

2024

6. A generalised Ricci-Hessian equation on Riemannian manifolds

Author

Ginoux, Nicolas and Habib, Georges

Subjects

Mathematics - Differential Geometry

Abstract

In this paper, we prove new rigidity results related to some generalised Ricci-Hessian equation on Riemannian manifolds., Comment: arXiv admin note: text overlap with arXiv:1809.07546

Published

2023

7. Modeling impacts of dust mineralogy on fast climate response

Author

Q. Song, P. Ginoux, M. Gonçalves Ageitos, R. L. Miller, V. Obiso, and C. Pérez García-Pando

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Mineralogical composition drives dust impacts on Earth's climate systems. However, most climate models still use homogeneous dust, without accounting for the temporal and spatial variation in mineralogy. To quantify the radiative impact of resolving dust mineralogy on Earth's climate, we implement and simulate the distribution of dust minerals (i.e., illite, kaolinite, smectite, hematite, calcite, feldspar, quartz, and gypsum) from Claquin et al. (1999) (C1999) and activate their interaction with radiation in the GFDL AM4.0 model. Resolving mineralogy reduces dust absorption compared to the homogeneous dust used in the standard GFDL AM4.0 model that assumes a globally uniform hematite volume content of 2.7 % (HD27). The reduction in dust absorption results in improved agreement with observation-based single-scattering albedo (SSA), radiative fluxes from CERES (the Clouds and the Earth's Radiant Energy System), and land surface temperature from the CRU (Climatic Research Unit) compared to the baseline HD27 model version. It also results in distinct radiative impacts on Earth's climate over North Africa. Over the 19-year (from 2001 to 2019) modeled period during JJA (June–July–August), the reduction in dust absorption in AM4.0 leads to a reduction of over 50 % in net downward radiation across the Sahara and approximately 20 % over the Sahel at the top of the atmosphere (TOA) compared to the baseline HD27 model version. The reduced dust absorption weakens the atmospheric warming effect of dust aerosols and leads to an alteration in land surface temperature, resulting in a decrease of 0.66 K over the Sahara and an increase of 0.7 K over the Sahel. The less warming in the atmosphere suppresses ascent and weakens the monsoon inflow from the Gulf of Guinea. This brings less moisture to the Sahel, which combined with decreased ascent induces a reduction of precipitation. To isolate the effect of reduced absorption compared to resolving spatial and temporal mineralogy, we carry out a simulation where the hematite volume content of homogeneous dust is reduced from 2.7 % to 0.9 % (HD09). The dust absorption (e.g., single-scattering albedo) of HD09 is comparable to that of the mineralogically speciated model on a global mean scale, albeit with a lower spatial variation that arises solely from particle size. Comparison of the two models indicates that the spatial inhomogeneity in dust absorption resulting from resolving mineralogy does not have significant impacts on Earth's radiation and climate, provided there is a similar level of dust absorption on a global mean scale before and after resolving dust mineralogy. However, uncertainties related to emission and distribution of minerals may blur the advantages of resolving minerals to study their impact on radiation, cloud properties, ocean biogeochemistry, air quality, and photochemistry. On the other hand, lumping together clay minerals (i.e., illite, kaolinite, and smectite), but excluding externally mixed hematite and gypsum, appears to provide both computational efficiency and relative accuracy. Nevertheless, for specific research, it may be necessary to fully resolve mineralogy to achieve accuracy.

Published

2024

8. Biharmonic Steklov operator on differential forms

Author

Chami, Fida El, Ginoux, Nicolas, Habib, Georges, and Makhoul, Ola

Subjects

Mathematics - Differential Geometry, Mathematics - Analysis of PDEs, Mathematics - Spectral Theory, 53C21, 58J32, 58C40, 58J50

Abstract

We introduce the biharmonic Steklov problem on differential forms by considering suitable boundary conditions. We characterize its smallest eigenvalue and prove elementary properties of the spectrum. We obtain various estimates for the first eigenvalue, some of which involve eigenvalues of other problems such as the Dirichlet, Neumann, Robin and Steklov ones. Independently, new inequalities relating the eigenvalues of the latter problems are proved.

Published

2022

9. The Land Component LM4.1 of the GFDL Earth System Model ESM4.1: Model Description and Characteristics of Land Surface Climate and Carbon Cycling in the Historical Simulation

Author

E. Shevliakova, S. Malyshev, I. Martinez‐Cano, P. C. D. Milly, S. W. Pacala, P. Ginoux, K. A. Dunne, J. P. Dunne, C. Dupuis, K. L. Findell, K. Ghannam, L. W. Horowitz, T. R. Knutson, J. P. Krasting, V. Naik, P. Phillipps, N. Zadeh, Yan Yu, F. Zeng, and Y. Zeng

Subjects

Earth System Model, land surface model, dynamic vegetation model, hydrological cycle, climate change, carbon cycle, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We describe the baseline model configuration and simulation characteristics of the Geophysical Fluid Dynamics Laboratory (GFDL)'s Land Model version 4.1 (LM4.1), which builds on component and coupled model developments over 2013–2019 for the coupled carbon‐chemistry‐climate Earth System Model Version 4.1 (ESM4.1) simulation as part of the sixth phase of the Coupled Model Intercomparison Project. Analysis of ESM4.1/LM4.1 is focused on biophysical and biogeochemical processes and interactions with climate. Key features include advanced vegetation dynamics and multi‐layer canopy energy and moisture exchanges, daily fire, land use representation, and dynamic atmospheric dust coupling. We compare LM4.1 performance in the GFDL Earth System Model (ESM) configuration ESM4.1 to the previous generation component LM3.0 in the ESM2G configuration. ESM4.1/LM4.1 provides significant improvement in the treatment of ecological processes from GFDL's previous generation models. However, ESM4.1/LM4.1 likely overestimates the influence of land use and land cover change on vegetation characteristics, particularly on pasturelands, as it overestimates the competitiveness of grasses versus trees in the tropics, and as a result, underestimates present‐day biomass and carbon uptake in comparison to observations.

Published

2024

10. Selective glucose electro-oxidation catalyzed by TEMPO on graphite felt

Author

Erwann Ginoux, Thibault Rafaïdeen, Patrick Cognet, Laure Latapie, and Christophe Coutanceau

Subjects

glucose, gluconic acid, glucaric acid, optimization, TEMPO, electro-oxidation, Chemistry, QD1-999

Abstract

Long-term electrolyses of glucose in a potassium carbonate (K2CO3) aqueous electrolyte have been performed on graphite felt electrodes with TEMPO as a homogeneous catalyst. The influences of the operating conditions (initial concentrations of glucose, TEMPO, and K2CO3 along with applied anode potential) on the conversion, selectivity toward gluconate/glucarate, and faradaic efficiency were assessed first. Then, optimizations of the conversion, selectivity, and faradaic efficiency were performed using design of experiments based on the L9 (34) Taguchi table, which resulted in 84% selectivity toward gluconate with 71% faradaic efficiency for up to 79% glucose conversion. Side products such as glucaric acid were also obtained when the applied potential exceeded 1.5 V vs. reversible hydrogen electrode.

Published

2024

11. The GFDL Variable‐Resolution Global Chemistry‐Climate Model for Research at the Nexus of US Climate and Air Quality Extremes

Author

Meiyun Lin, Larry W. Horowitz, Ming Zhao, Lucas Harris, Paul Ginoux, John Dunne, Sergey Malyshev, Elena Shevliakova, Hamza Ahsan, Steve Garner, Fabien Paulot, Arman Pouyaei, Steven J. Smith, Yuanyu Xie, Niki Zadeh, and Linjiong Zhou

Subjects

drought, Earth system feedbacks, extremes, air quality‐climate interactions, precipitation, high‐resolution, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We present a variable‐resolution global chemistry‐climate model (AM4VR) developed at NOAA's Geophysical Fluid Dynamics Laboratory (GFDL) for research at the nexus of US climate and air quality extremes. AM4VR has a horizontal resolution of 13 km over the US, allowing it to resolve urban‐to‐rural chemical regimes, mesoscale convective systems, and land‐surface heterogeneity. With the resolution gradually reducing to 100 km over the Indian Ocean, we achieve multi‐decadal simulations driven by observed sea surface temperatures at 50% of the computational cost for a 25‐km uniform‐resolution grid. In contrast with GFDL's AM4.1 contributing to the sixth Coupled Model Intercomparison Project at 100 km resolution, AM4VR features much improved US climate mean patterns and variability. In particular, AM4VR shows improved representation of: precipitation seasonal‐to‐diurnal cycles and extremes, notably reducing the central US dry‐and‐warm bias; western US snowpack and summer drought, with implications for wildfires; and the North American monsoon, affecting dust storms. AM4VR exhibits excellent representation of winter precipitation, summer drought, and air pollution meteorology in California with complex terrain, enabling skillful prediction of both extreme summer ozone pollution and winter haze events in the Central Valley. AM4VR also provides vast improvements in the process‐level representations of biogenic volatile organic compound emissions, interactive dust emissions from land, and removal of air pollutants by terrestrial ecosystems. We highlight the value of increased model resolution in representing climate–air quality interactions through land‐biosphere feedbacks. AM4VR offers a novel opportunity to study global dimensions to US air quality, especially the role of Earth system feedbacks in a changing climate.

Published

2024

12. The projected future degradation in air quality is caused by more abundant natural aerosols in a warmer world

Author

Gomez, James, Allen, Robert J., Turnock, Steven T., Horowitz, Larry W., Tsigaridis, Kostas, Bauer, Susanne E., Olivié, Dirk, Thomson, Erik S., and Ginoux, Paul

Published

2023

13. Frisch’s Propagation-Impulse Model: A Comprehensive Mathematical Analysis

Author

Ginoux, Jean-Marc and Jovanovic, Franck

Published

2023

14. The Importance of Dynamic Iron Deposition in Projecting Climate Change Impacts on Pacific Ocean Biogeochemistry

Author

Elizabeth J. Drenkard, Jasmin G. John, Charles A. Stock, Hyung‐Gyu Lim, John P. Dunne, Paul Ginoux, and Jessica Y. Luo

Subjects

Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Deposition of mineral dust plays an important role in upper‐ocean biogeochemical processes, particularly by delivering iron to iron‐limited regions. Here we examine the impact of dynamically changing iron deposition on tropical Pacific Ocean biogeochemistry in fully coupled earth system model projections under several emissions scenarios. Projected end‐of‐21st‐century increases in central tropical Pacific dust and iron deposition strengthen with increasing emissions/radiative forcing, and are aligned with projected soil moisture decreases in adjacent land areas and precipitation increases over the equatorial Pacific. Increased delivery of soluble iron results in a reduction in, and eastward contraction of, equatorial Pacific phytoplankton iron limitation and shifts primary production and particulate organic carbon flux projections relative to a high emissions projection (SSP5‐8.5) wherein soluble iron deposition is prescribed as a static climatology. These results highlight modeling advances in representing coupled land‐air‐sea interactions to project basin‐scale patterns of ocean biogeochemical change.

Published

2023

15. The projected future degradation in air quality is caused by more abundant natural aerosols in a warmer world

Author

James Gomez, Robert J. Allen, Steven T. Turnock, Larry W. Horowitz, Kostas Tsigaridis, Susanne E. Bauer, Dirk Olivié, Erik S. Thomson, and Paul Ginoux

Subjects

Geology, QE1-996.5, Environmental sciences, GE1-350

Abstract

Higher concentrations of dust and secondary organic aerosol in the atmosphere, resulting from an intensified West African monsoon and enhanced emissions of biogenic volatile organic compounds, respectively, are projected to contribute to degrading air quality in a warmer world, suggest analyses of Earth system model simulations.

Published

2023

16. Enhanced dust emission following large wildfires due to vegetation disturbance

Author

Yu, Yan and Ginoux, Paul

Published

2022

17. Using modelled relationships and satellite observations to attribute modelled aerosol biases over biomass burning regions

Author

Qirui Zhong, Nick Schutgens, Guido R. van der Werf, Twan van Noije, Susanne E. Bauer, Kostas Tsigaridis, Tero Mielonen, Ramiro Checa-Garcia, David Neubauer, Zak Kipling, Alf Kirkevåg, Dirk J. L. Olivié, Harri Kokkola, Hitoshi Matsui, Paul Ginoux, Toshihiko Takemura, Philippe Le Sager, Samuel Rémy, Huisheng Bian, and Mian Chin

Subjects

Science

Abstract

Error attribution based on modelled relationships and satellite observations suggests that errors in global models are more important and require more concerns than emission errors in creating the overall uncertainties for biomass burning aerosols.

Published

2022

18. WEST full tungsten operation with an ITER grade divertor

Author

J. Bucalossi, A. Ekedahl, and the WEST Team, J. Achard, K. Afonin, O. Agullo, T. Alarcon, L. Allegretti, F. Almuhisen, H. Ancher, G. Antar, Y. Anquetin, S. Antusch, V. Anzallo, C. Arnas, J.F. Artaud, M.H. Aumeunier, S.G. Baek, X.Y. Bai, M. Balden, C. Balorin, T. Barbui, A. Barbuti, J. Barlerin, J. Barra, V. Basiuk, T. Batal, O. Baulaigue, A. Bec, M. Becoulet, E. Benoit, E. Bernard, J.M. Bernard, M. Bernert, N. Bertelli, E. Bertrand, P. Beyer, J. Bielecki, P. Bienvenu, R. Bisson, B. Bliewert, G. Bodner, S. Bose, C. Bottereau, C. Bouchand, Y. Boumendjel, F. Bouquey, C. Bourdelle, J. Bourg, S. Brezinsek, F. Brochard, C. Brun, V. Bruno, H. Bufferand, A. Bureau, S. Burles, Y. Camenen, B. Cantone, E. Caprin, M. Carole, S. Carpentier-Chouchana, G. Caulier, F. Causa, N. Cazanave, N. Chanet, O. Chellai, Y. Chen, M. Chernyshova, P. Chmielewski, W. Choe, A. Chomiczewska, G. Ciraolo, F. Clairet, J. Coenen, L. Colas, G. Colledani, J. Colnel, P. Coquillat, E. Corbel, Y. Corre, X. Courtois, T. Czarski, A. Da Ros, R. Daniel, J. Daumas, M. De Combarieu, P. De Vries, C. Dechelle, F. Deguara, R. Dejarnac, J.M. Delaplanche, L.F. Delgado-Aparicio, E. Delmas, L. Delpech, C. Desgranges, P. Devynck, J. Denis, S. Di Genova, R. Diab, A. Diallo, M. Diez, G. Dif-Pradalier, M. Dimitrova, R. Ding, T. Dittmar, L. Doceul, M. Domenes, D. Donovan, D. Douai, L. Dubus, N. Dumas, R. Dumont, F. Durand, A. Durif, F. Durodié, D. Elbeze, S. Ertmer, A. Escarguel, F. Escourbiac, B. Esposito, K. Ezato, F. Faisse, J.L. Farjon, N. Faure, N. Fedorczak, P. Fejoz, F. Felici, C. Fenzi-Bonizec, F. Ferlay, L. Ferrand, L. Fevre, M. Firdaouss, L. Fleury, D. Flouquet, T. Fonghetti, A. Gallo, X. Garbet, J. Garcia, J.L. Gardarein, L. Gargiulo, P. Garibaldi, S. Garitta, J. Gaspar, E. Gauthier, S. Gazzotti, F. Gely, J. Gerardin, G. Gervasini, E. Geulin, M. Geynet, P. Ghendrih, I. Giacalone, C. Gil, S. Ginoux, S. Girard, E. Giroux, G. Giruzzi, M. Goniche, V. Gorse, T. Gray, E. Grelier, C. Grisolia, A. Grosjean, A. Grosman, O. Grover, D. Guibert, D. Guilhem, C. Guillemaut, B. Guillermin, R. Guirlet, J.P. Gunn, Y. Gunsu, T. Gyergyek, S. Hacquin, A. Hakola, J. Harris, J.C. Hatchressian, W. Helou, P. Hennequin, C. Hernandez, L. Hijazi, J. Hillairet, T. Hirai, G.T. Hoang, C. Honoré, M. Houry, A. Huart, G. Huijsmans, P. Huynh, M. Iafrati, F. Imbeaux, N. Imbert, I. Ivanova-Stanik, P. Ivanova, R. Jalageas, A. Jamann, C. Jammes, A. Jardin, L. Jaubert, G. Jiolat, E. Joffrin, C. Johnson, A. Jonas, A. Kirschner, C.C. Klepper, M. Komm, M. Koubiti, S. Kosslow, J. Kovacic, M. Kozeiha, K. Krieger, K. Krol, I. Kudashev, B. Lacroix, L. Laguardia, V. Lamaison, V. Lapleigne, H. Laqua, C. Lau, Y. Lausenaz, R. Lé, M. Le Bohec, N. Lefevre, N. Lemoine, E. Lerche, Y. Lesourd, L. Letellier, M. Lewerentz, Y. Li, A. Liang, P. Linczuk, C. Linsmeier, M. Lipa, X. Litaudon, X. Liu, J. Llorens, T. Loarer, A. Loarte, T. Loewenhoff, G. Lombard, J. Lore, P. Lorenzetto, B. Lu, A. Lumsdaine, R. Lunsford, T. Lunt, G. Luo, P. Magaud, P. Maget, J.F. Mahieu, P. Maini, P. Malard, K. Malinowski, P. Manas, L. Manenc, V. Maquet, Y. Marandet, C. Martin, E.J. Martin, P. Martino, M. Mayer, D. Mazon, S. Mazzi, P. Messina, L. Meunier, D. Midou, G. Miglionico, Y. Mineo, M. Missirlian, R. Mitteau, B. Mitu, D. Moiraf, P. Mollard, G. Momparler, V. Moncada, T. Mondiere, C. Monti, J. Morales, M. Moreau, Ph. Moreau, Y. Moudden, G. Moureau, D. Mouyon, M. Muraglia, T. Nakano, E. Nardon, A. Neff, F. Nespoli, J. Nichols, L. Nicolas, S. Nicollet, R. Nouailletas, M. Ono, V. Ostuni, O. Paillat, C. Parish, H. Park, H. Parrat, J.Y. Pascal, B. Pegourie, F.P. Pellissier, Y. Peneliau, M. Peret, E. Pignoly, G. Pintsuk, R. Pitts, C. Pocheau, A. Podolnik, C. Portafaix, M. Poulos, P. Prochet, A. Puig Sitjes, R. Ragona, M. Rasinski, S. Ratynskaia, G. Raup, X. Regal-Mezin, C. Reux, J. Rice, M. Richou, F. Rigollet, N. Rivals, H. Roche, S. Rodrigues, J. Romazanov, G. Ronchi, C. Ruset, R. Sabot, A. Saille, R. Sakamoto, B. Salamon, F. Samaille, A. Santagiustina, B. Santraine, Y. Sarazin, O. Sauter, Y. Savoie-Peysson, L. Schiesko, M. Scholz, J.L. Schwob, E. Serre, H. Shin, S. Shiraiwa, Ja. Signoret, O. Skalli-Fettachi, P. Sogorb, Y. Song, A. Spring, P. Spuig, S. Sridhar, B. Stratton, C. Talatizi, P. Tamain, R. Tatali, Q. Tichit, A. Torre, L. Toulouse, W. Treutterer, E. Tsitrone, E.A. Unterberg, G. Urbanczyk, G. Van Rooij, N. Varadarajan, S. Vartanian, E. Velly, J.M. Verger, L. Vermare, D. Vezinet, N. Vignal, B. Vincent, S. Vives, D. Volpe, G. Wallace, E. Wang, L. Wang, Y. Wang, Y.S. Wang, T. Wauters, D. Weldon, B. Wirth, M. Wirtz, A. Wojenski, M. Xu, Q.X. Yang, H. Yang, B. Zago, R. Zagorski, B. Zhang, X.J. Zhang, X.L. Zou, and the EUROfusion Tokamak Exploitation Team

Subjects

nuclear fusion, magnetic confinement, tokamak, divertor, WEST, ITER, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The mission of WEST (tungsten-W Environment in Steady-state Tokamak) is to explore long pulse operation in a full tungsten (W) environment for preparing next-step fusion devices (ITER and DEMO) with a focus on testing the ITER actively cooled W divertor in tokamak conditions. Following the successful completion of phase 1 (2016-2021), phase 2 started in December 2022 with the lower divertor made entirely of actively cooled ITER-grade tungsten mono-blocks. A boronization prior the first plasma attempt allowed for a smooth startup with the new divertor. Despite the reduced operating window due to tungsten, rapid progress has been made in long pulse operation, resulting in discharges with a pulse length of 100 s and an injected energy of around 300 MJ per discharge. Plasma startup studies were carried out with equatorial boron nitride limiters to compare them with tungsten limiters, while Ion Cyclotron Resonance Heating assisted startup was attempted. High fluence operation in attached regime, which was the main thrust of the first campaigns, already showed the progressive build up of deposits and appearance of dust, impacting the plasma operation as the plasma fluence increased. In total, the cumulated injected energy during the first campaigns reached 43 GJ and the cumulated plasma time exceeded 5 h. Demonstration of controlled X-Point Radiator regime is also reported, opening a promising route for investigating plasma exhaust and plasma-wall interaction issues in more detached regime. This paper summarises the lessons learned from the manufacturing and the first operation of the ITER-grade divertor, describing the progress achieved in optimising operation in a full W environment with a focus on long pulse operation and plasma wall interaction.

Published

2024

19. Albert Einstein and the Doubling of the Deflection of Light

Author

Ginoux, Jean-Marc

Published

2022

20. Black carbon and dust alter the response of mountain snow cover under climate change

Author

Marion Réveillet, Marie Dumont, Simon Gascoin, Matthieu Lafaysse, Pierre Nabat, Aurélien Ribes, Rafife Nheili, Francois Tuzet, Martin Ménégoz, Samuel Morin, Ghislain Picard, and Paul Ginoux

Subjects

Science

Abstract

Black carbon and dust deposition advanced the end of the snow season by 17 days on average over the last 40 years in the French Alps and the Pyrenees. The warming-induced snow cover decline was partly offset by decreases in black carbon deposition observed since the 1980s.

Published

2022

21. Satellite-based evaluation of AeroCom model bias in biomass burning regions

Author

Q. Zhong, N. Schutgens, G. van der Werf, T. van Noije, K. Tsigaridis, S. E. Bauer, T. Mielonen, A. Kirkevåg, Ø. Seland, H. Kokkola, R. Checa-Garcia, D. Neubauer, Z. Kipling, H. Matsui, P. Ginoux, T. Takemura, P. Le Sager, S. Rémy, H. Bian, M. Chin, K. Zhang, J. Zhu, S. G. Tsyro, G. Curci, A. Protonotariou, B. Johnson, J. E. Penner, N. Bellouin, R. B. Skeie, and G. Myhre

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Global models are widely used to simulate biomass burning aerosol (BBA). Exhaustive evaluations on model representation of aerosol distributions and properties are fundamental to assess health and climate impacts of BBA. Here we conducted a comprehensive comparison of Aerosol Comparisons between Observations and Models (AeroCom) project model simulations with satellite observations. A total of 59 runs by 18 models from three AeroCom Phase-III experiments (i.e., biomass burning emissions, CTRL16, and CTRL19) and 14 satellite products of aerosols were used in the study. Aerosol optical depth (AOD) at 550 nm was investigated during the fire season over three key fire regions reflecting different fire dynamics (i.e., deforestation-dominated Amazon, Southern Hemisphere Africa where savannas are the key source of emissions, and boreal forest burning in boreal North America). The 14 satellite products were first evaluated against AErosol RObotic NETwork (AERONET) observations, with large uncertainties found. But these uncertainties had small impacts on the model evaluation that was dominated by modeling bias. Through a comparison with Polarization and Directionality of the Earth’s Reflectances measurements with the Generalized Retrieval of Aerosol and Surface Properties algorithm (POLDER-GRASP), we found that the modeled AOD values were biased by −93 % to 152 %, with most models showing significant underestimations even for the state-of-the-art aerosol modeling techniques (i.e., CTRL19). By scaling up BBA emissions, the negative biases in modeled AOD were significantly mitigated, although it yielded only negligible improvements in the correlation between models and observations, and the spatial and temporal variations in AOD biases did not change much. For models in CTRL16 and CTRL19, the large diversity in modeled AOD was in almost equal measures caused by diversity in emissions, lifetime, and the mass extinction coefficient (MEC). We found that in the AeroCom ensemble, BBA lifetime correlated significantly with particle deposition (as expected) and in turn correlated strongly with precipitation. Additional analysis based on Cloud-Aerosol LIdar with Orthogonal Polarization (CALIOP) aerosol profiles suggested that the altitude of the aerosol layer in the current models was generally too low, which also contributed to the bias in modeled lifetime. Modeled MECs exhibited significant correlations with the Ångström exponent (AE, an indicator of particle size). Comparisons with the POLDER-GRASP-observed AE suggested that the models tended to overestimate the AE (underestimated particle size), indicating a possible underestimation of MECs in models. The hygroscopic growth in most models generally agreed with observations and might not explain the overall underestimation of modeled AOD. Our results imply that current global models contain biases in important aerosol processes for BBA (e.g., emissions, removal, and optical properties) that remain to be addressed in future research.

Published

2022

22. Correction to Frisch’s Propagation-Impulse Model: A Comprehensive Mathematical Analysis

Author

Ginoux, Jean-Marc and Jovanovic, Franck

Published

2022

23. Volcanic Drivers of Stratospheric Sulfur in GFDL ESM4

Author

Chloe Yuchao Gao, Vaishali Naik, Larry W. Horowitz, Paul Ginoux, Fabien Paulot, John Dunne, Michael Mills, Valentina Aquila, and Peter Colarco

Subjects

aerosol modeling, sulfate aerosols, stratospheric aerosols, model development, climate modeling, earth system modeling, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Stratospheric injections of sulfur dioxide from major volcanic eruptions perturb the Earth's global radiative balance and dominate variability in stratospheric sulfur loading. The atmospheric component of the GFDL Earth System Model (ESM4.1) uses a bulk aerosol scheme and previously prescribed the distribution of aerosol optical properties in the stratosphere. To quantify volcanic contributions to the stratospheric sulfur cycle and the resulting climate impact, we modified ESM4.1 to simulate stratospheric sulfate aerosols prognostically. Driven by explicit volcanic emissions of aerosol precursors and non‐volcanic sources, we conduct ESM4.1 simulations from 1989 to 2014, with a focus on the Mt. Pinatubo eruption. We evaluate our interactive representation of the stratospheric sulfur cycle against data from Moderate Resolution Imaging Spectroradiometer, Multi‐angle Imaging SpectroRadiometer, Advanced Very High Resolution Radiometer, High Resolution Infrared Radiation Sounder, and Stratospheric Aerosol and Gas Experiment II. To assess the key processes associated with volcanic aerosols, we performed a sensitivity analysis of sulfate burden from the Mt. Pinatubo eruption by varying injection heights, emission amount, and stratospheric sulfate's dry effective radius. We find that the simulated stratospheric sulfate mass burden and aerosol optical depth in the model are sensitive to these parameters, especially volcanic SO2 injection height, and the optimal combination of parameters depends on the metric we evaluate.

Published

2023

24. The MONARCH high-resolution reanalysis of desert dust aerosol over Northern Africa, the Middle East and Europe (2007–2016)

Author

E. Di Tomaso, J. Escribano, S. Basart, P. Ginoux, F. Macchia, F. Barnaba, F. Benincasa, P.-A. Bretonnière, A. Buñuel, M. Castrillo, E. Cuevas, P. Formenti, M. Gonçalves, O. Jorba, M. Klose, L. Mona, G. Montané Pinto, M. Mytilinaios, V. Obiso, M. Olid, N. Schutgens, A. Votsis, E. Werner, and C. Pérez García-Pando

Subjects

Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

One of the challenges in studying desert dust aerosol along with its numerous interactions and impacts is the paucity of direct in situ measurements, particularly in the areas most affected by dust storms. Satellites typically provide column-integrated aerosol measurements, but observationally constrained continuous 3D dust fields are needed to assess dust variability, climate effects and impacts upon a variety of socio-economic sectors. Here, we present a high-resolution regional reanalysis data set of desert dust aerosols that covers Northern Africa, the Middle East and Europe along with the Mediterranean Sea and parts of central Asia and the Atlantic and Indian oceans between 2007 and 2016. The horizontal resolution is 0.1∘ latitude × 0.1∘ longitude in a rotated grid, and the temporal resolution is 3 h. The reanalysis was produced using local ensemble transform Kalman filter (LETKF) data assimilation in the Multiscale Online Nonhydrostatic AtmospheRe CHemistry model (MONARCH) developed at the Barcelona Supercomputing Center (BSC). The assimilated data are coarse-mode dust optical depth retrieved from the Moderate Resolution Imaging Spectroradiometer (MODIS) Deep Blue Level 2 products. The reanalysis data set consists of upper-air variables (dust mass concentrations and the extinction coefficient), surface variables (dust deposition and solar irradiance fields among them) and total column variables (e.g. dust optical depth and load). Some dust variables, such as concentrations and wet and dry deposition, are expressed for a binned size distribution that ranges from 0.2 to 20 µm in particle diameter. Both analysis and first-guess (analysis-initialized simulation) fields are available for the variables that are diagnosed from the state vector. A set of ensemble statistics is archived for each output variable, namely the ensemble mean, standard deviation, maximum and median. The spatial and temporal distribution of the dust fields follows well-known dust cycle features controlled by seasonal changes in meteorology and vegetation cover. The analysis is statistically closer to the assimilated retrievals than the first guess, which proves the consistency of the data assimilation method. Independent evaluation using Aerosol Robotic Network (AERONET) dust-filtered optical depth retrievals indicates that the reanalysis data set is highly accurate (mean bias = −0.05, RMSE = 0.12 and r = 0.81 when compared to retrievals from the spectral de-convolution algorithm on a 3-hourly basis). Verification statistics are broadly homogeneous in space and time with regional differences that can be partly attributed to model limitations (e.g. poor representation of small-scale emission processes), the presence of aerosols other than dust in the observations used in the evaluation and differences in the number of observations among seasons. Such a reliable high-resolution historical record of atmospheric desert dust will allow a better quantification of dust impacts upon key sectors of society and economy, including health, solar energy production and transportation. The reanalysis data set (Di Tomaso et al., 2021) is distributed via Thematic Real-time Environmental Distributed Data Services (THREDDS) at BSC and is freely available at http://hdl.handle.net/21.12146/c6d4a608-5de3-47f6-a004-67cb1d498d98 (last access: 10 June 2022).

Published

2022

25. Inferring iron-oxide species content in atmospheric mineral dust from DSCOVR EPIC observations

Author

S. Go, A. Lyapustin, G. L. Schuster, M. Choi, P. Ginoux, M. Chin, O. Kalashnikova, O. Dubovik, J. Kim, A. da Silva, B. Holben, and J. S. Reid

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The iron-oxide content of dust in the atmosphere and most notably its apportionment between hematite (α-Fe2O3) and goethite (α-FeOOH) are key determinants in quantifying dust's light absorption, its top of atmosphere ultraviolet (UV) radiances used for dust monitoring, and ultimately shortwave dust direct radiative effects (DREs). Hematite and goethite column mass concentrations and iron-oxide mass fractions of total dust mass concentration were retrieved from the Deep Space Climate Observatory (DSCOVR) Earth Polychromatic Imaging Camera (EPIC) measurements in the ultraviolet–visible (UV–Vis) channels. The retrievals were performed for dust-identified aerosol plumes over land using aerosol optical depth (AOD) and the spectral imaginary refractive index provided by the Multi-Angle Implementation of Atmospheric Correction (MAIAC) algorithm over six continental regions (North America, North Africa, West Asia, Central Asia, East Asia, and Australia). The dust particles are represented as an internal mixture of non-absorbing host and absorbing hematite and goethite. We use the Maxwell Garnett effective medium approximation with carefully selected complex refractive indices of hematite and goethite that produce mass fractions of iron-oxide species consistent with in situ values found in the literature to derive the hematite and goethite volumetric/mass concentrations from MAIAC EPIC products. We compared the retrieved hematite and goethite concentrations with in situ dust aerosol mineralogical content measurements, as well as with published data. Our data display variations within the published range of hematite, goethite, and iron-oxide mass fractions for pure-mineral-dust cases. A specific analysis is presented for 15 sites over the main dust-source regions. Sites in the central Sahara, Sahel, and Middle East exhibit a greater temporal variability of iron oxides relative to other sites. The Niger site (13.52∘ N, 2.63∘ E) is dominated by goethite over the Harmattan season with a median of ∼ 2 weight percentage (wt %) of iron oxide. The Saudi Arabia site (27.49∘ N, 41.98∘ E) over the Middle East also exhibited a surge of goethite content with the beginning of the shamal season. The Sahel dust is richer in iron oxide than Saharan and northern China dust except in summer. The Bodélé Depression area shows a distinctively lower iron-oxide concentration (∼ 1 wt %) throughout the year. Finally, we show that EPIC data allow the constraining of the hematite refractive index. Specifically, we select 5 out of 13 different hematite refractive indices that are widely variable in published laboratory studies by constraining the iron-oxide mass ratio to the known measured values. The provided climatology of hematite and goethite mass fractions across the main dust regions of Earth will be useful for dust shortwave DRE studies and climate modeling.

Published

2022

26. Granger causality analysis for calcium transients in neuronal networks, challenges and improvements

Author

Xiaowen Chen, Faustine Ginoux, Martin Carbo-Tano, Thierry Mora, Aleksandra M Walczak, and Claire Wyart

Subjects

causality, information flow, neural networks, locomotion, calcium imaging, statistical analysis, Medicine, Science, Biology (General), QH301-705.5

Abstract

One challenge in neuroscience is to understand how information flows between neurons in vivo to trigger specific behaviors. Granger causality (GC) has been proposed as a simple and effective measure for identifying dynamical interactions. At single-cell resolution however, GC analysis is rarely used compared to directionless correlation analysis. Here, we study the applicability of GC analysis for calcium imaging data in diverse contexts. We first show that despite underlying linearity assumptions, GC analysis successfully retrieves non-linear interactions in a synthetic network simulating intracellular calcium fluctuations of spiking neurons. We highlight the potential pitfalls of applying GC analysis on real in vivo calcium signals, and offer solutions regarding the choice of GC analysis parameters. We took advantage of calcium imaging datasets from motoneurons in embryonic zebrafish to show how the improved GC can retrieve true underlying information flow. Applied to the network of brainstem neurons of larval zebrafish, our pipeline reveals strong driver neurons in the locus of the mesencephalic locomotor region (MLR), driving target neurons matching expectations from anatomical and physiological studies. Altogether, this practical toolbox can be applied on in vivo population calcium signals to increase the selectivity of GC to infer flow of information across neurons.

Published

2023

27. Black carbon and dust alter the response of mountain snow cover under climate change

Author

Réveillet, Marion, Dumont, Marie, Gascoin, Simon, Lafaysse, Matthieu, Nabat, Pierre, Ribes, Aurélien, Nheili, Rafife, Tuzet, Francois, Ménégoz, Martin, Morin, Samuel, Picard, Ghislain, and Ginoux, Paul

Published

2022

28. Using modelled relationships and satellite observations to attribute modelled aerosol biases over biomass burning regions

Author

Zhong, Qirui, Schutgens, Nick, van der Werf, Guido R., van Noije, Twan, Bauer, Susanne E., Tsigaridis, Kostas, Mielonen, Tero, Checa-Garcia, Ramiro, Neubauer, David, Kipling, Zak, Kirkevåg, Alf, Olivié, Dirk J. L., Kokkola, Harri, Matsui, Hitoshi, Ginoux, Paul, Takemura, Toshihiko, Le Sager, Philippe, Rémy, Samuel, Bian, Huisheng, and Chin, Mian

Published

2022

29. Local Innate Markers and Vaginal Microbiota Composition Are Influenced by Hormonal Cycle Phases

Author

Cindy Adapen, Louis Réot, Natalia Nunez, Claude Cannou, Romain Marlin, Julien Lemaître, Léo d’Agata, Emmanuel Gilson, Eric Ginoux, Roger Le Grand, Marie-Thérèse Nugeyre, and Elisabeth Menu

Subjects

inflammation, menstrual cycle, female reproductive tract (FRT), cytokines, blood compartment, neutrophils, Immunologic diseases. Allergy, RC581-607

Abstract

BackgroundThe female reproductive tract (FRT) mucosa is the first line of defense against sexually transmitted infection (STI). FRT environmental factors, including immune-cell composition and the vaginal microbiota, interact with each other to modulate susceptibility to STIs. Moreover, the menstrual cycle induces important modifications within the FRT mucosa. Cynomolgus macaques are used as a model for the pathogenesis and prophylaxis of STIs. In addition, their menstrual cycle and FRT morphology are similar to women. The cynomolgus macaque vaginal microbiota is highly diverse and similar to dysbiotic vaginal microbiota observed in women. However, the impact of the menstrual cycle on immune markers and the vaginal microbiota in female cynomolgus macaques is unknown. We conducted a longitudinal study covering three menstrual cycles in cynomolgus macaques. The evolution of the composition of the vaginal microbiota and inflammation (cytokine/chemokine profile and neutrophil phenotype) in the FRT and blood was determined throughout the menstrual cycle.ResultsCervicovaginal cytokine/chemokine concentrations were affected by the menstrual cycle, with a peak of production during menstruation. We observed three main cervicovaginal neutrophil subpopulations: CD11bhigh CD101+ CD10+ CD32a+, CD11bhigh CD101+ CD10- CD32a+, and CD11blow CD101low CD10- CD32a-, of which the proportion varied during the menstrual cycle. During menstruation, there was an increase in the CD11bhigh CD101+ CD10+ CD32a+ subset of neutrophils, which expressed higher levels of CD62L. Various bacterial taxa in the vaginal microbiota showed differential abundance depending on the phase of the menstrual cycle. Compilation of the factors that vary according to hormonal phase showed the clustering of samples collected during menstruation, characterized by a high concentration of cytokines and an elevated abundance of the CD11bhigh CD101+ CD10+ CD32a+ CD62L+ neutrophil subpopulation.ConclusionsWe show a significant impact of menstruation on the local environment (cytokine production, neutrophil phenotype, and vaginal microbiota composition) in female cynomolgus macaques. Menstruation triggers increased production of cytokines, shift of the vaginal microbiota composition and the recruitment of mature/activated neutrophils from the blood to the FRT. These results support the need to monitor the menstrual cycle and a longitudinal sampling schedule for further studies in female animals and/or women focusing on the mucosal FRT environment.

Published

2022

30. Corrigendum: Individual, Sociodemographic, and Environmental Factors Related to Physical Activity During the Spring 2020 COVID-19 Lockdown

Author

Claudia Teran-Escobar, Cyril Forestier, Clément Ginoux, Sandrine Isoard-Gautheur, Philippe Sarrazin, Anna Clavel, and Aïna Chalabaev

Subjects

physical activity, COVID-19 pandemic, psychology, context, exercise, Psychology, BF1-990

Published

2021

31. COVA1-18 neutralizing antibody protects against SARS-CoV-2 in three preclinical models

Author

Maisonnasse, Pauline, Aldon, Yoann, Marc, Aurélien, Marlin, Romain, Dereuddre-Bosquet, Nathalie, Kuzmina, Natalia A., Freyn, Alec W., Snitselaar, Jonne L., Gonçalves, Antonio, Caniels, Tom G., Burger, Judith A., Poniman, Meliawati, Bontjer, Ilja, Chesnais, Virginie, Diry, Ségolène, Iershov, Anton, Ronk, Adam J., Jangra, Sonia, Rathnasinghe, Raveen, Brouwer, Philip J. M., Bijl, Tom P. L., van Schooten, Jelle, Brinkkemper, Mitch, Liu, Hejun, Yuan, Meng, Mire, Chad E., van Breemen, Mariëlle J., Contreras, Vanessa, Naninck, Thibaut, Lemaître, Julien, Kahlaoui, Nidhal, Relouzat, Francis, Chapon, Catherine, Ho Tsong Fang, Raphaël, McDanal, Charlene, Osei-Twum, Mary, St-Amant, Natalie, Gagnon, Luc, Montefiori, David C., Wilson, Ian A., Ginoux, Eric, de Bree, Godelieve J., García-Sastre, Adolfo, Schotsaert, Michael, Coughlan, Lynda, Bukreyev, Alexander, van der Werf, Sylvie, Guedj, Jérémie, Sanders, Rogier W., van Gils, Marit J., and Le Grand, Roger

Published

2021

32. The Land Component LM4.1 of the GFDL Earth System Model ESM4.1: Model Description and Characteristics of Land Surface Climate and Carbon Cycling in the Historical Simulation.

Author

Shevliakova, E., Malyshev, S., Martinez‐Cano, I., Milly, P. C. D., Pacala, S. W., Ginoux, P., Dunne, K. A., Dunne, J. P., Dupuis, C., Findell, K. L., Ghannam, K., Horowitz, L. W., Knutson, T. R., Krasting, J. P., Naik, V., Phillipps, P., Zadeh, N., Yu, Yan, Zeng, F., and Zeng, Y.

Subjects

GEOPHYSICAL fluid dynamics, DUST, VEGETATION dynamics, EARTH (Planet), LAND cover, CARBON cycle, THEMATIC mapper satellite

Abstract

We describe the baseline model configuration and simulation characteristics of the Geophysical Fluid Dynamics Laboratory (GFDL)'s Land Model version 4.1 (LM4.1), which builds on component and coupled model developments over 2013–2019 for the coupled carbon‐chemistry‐climate Earth System Model Version 4.1 (ESM4.1) simulation as part of the sixth phase of the Coupled Model Intercomparison Project. Analysis of ESM4.1/LM4.1 is focused on biophysical and biogeochemical processes and interactions with climate. Key features include advanced vegetation dynamics and multi‐layer canopy energy and moisture exchanges, daily fire, land use representation, and dynamic atmospheric dust coupling. We compare LM4.1 performance in the GFDL Earth System Model (ESM) configuration ESM4.1 to the previous generation component LM3.0 in the ESM2G configuration. ESM4.1/LM4.1 provides significant improvement in the treatment of ecological processes from GFDL's previous generation models. However, ESM4.1/LM4.1 likely overestimates the influence of land use and land cover change on vegetation characteristics, particularly on pasturelands, as it overestimates the competitiveness of grasses versus trees in the tropics, and as a result, underestimates present‐day biomass and carbon uptake in comparison to observations. Plain Language Summary: The Geophysical Fluid Dynamics Laboratory (GFDL) has developed a new Land Model (LM4.1) as part of its 4th generation coupled model development. This model includes advances from the previous generation and introduces a new vegetation demography model, multi‐layer canopy, plant hydraulics, fire, and land use representation as well as dynamic atmospheric dust coupling. Coupled within an Earth System Model (ESM4.1), LM4.1 features an improved representation of many ecological processes from the previous generation of GFDL ESMs. Key Points: A new land model LM4.1 is developed at the Geophysical Fluid Dynamics Laboratory (GFDL) for the next‐generation Earth System Model (ESM) ESM4.1LM4.1 integrates age‐height structured vegetation dynamics, multi‐layer canopy‐soil‐snow energy exchanges, and prognostic fires and mineral dustESM4.1/LM4.1 improves patterns of land surface climate and carbon cycle compared to the previous generation GFDL model ESM2G/LM3.0 [ABSTRACT FROM AUTHOR]

Published

2024

33. LETTER TO THE EDITORS: SOLVING VINCENT CARRET’S PUZZLE: A REBUTTAL OF CARRET’S FALLACIES AND ERRORS

Author

Ginoux, Jean-Marc and Jovanovic, Franck

Abstract

In his article published in JHET in 2022, Vincent Carret (2022a) criticizes our work. In footnote 19, pages 630–631, he claims that our result “is based on a mistaken interpretation of the paragraph at the bottom of p. 191 of Frisch (1933).” He then states that we “take to mean that the coefficient of each cycle in the general sum of solutions is arbitrary, while … these coefficients [depended] on initial conditions and the parameters of the system.” The present rejoinder aims at rebutting Carret’s allegation of mistaken interpretation in our work. We demonstrate that his statements are based on a misunderstanding of Frisch’s econometric model and approach. Then, we show that Carret’s results are not supported by the demonstration he claims to have made, and that he misrepresents our arguments.

Published

2023

34. Development of a Graphene-Oxide-Deposited Carbon Electrode for the Rapid and Low-Level Detection of Fentanyl and Derivatives.

Author

Jun, Daniel, Sammis, Glenn, Rezazadeh-Azar, Pouya, Ginoux, Erwann, and Bizzotto, Dan

Published

2022

35. Where Dust Comes From: Global Assessment of Dust Source Attributions With AeroCom Models

Author

Kim, Dongchul, Chin, Mian, Schuster, Greg, Yu, Hongbin, Takemura, Toshihiko, Tuccella, Paolo, Ginoux, Paul, Liu, Xiaohong, Shi, Yang, Matsui, Hitoshi, Tsigaridis, Kostas, Bauer, Susanne E., Kok, Jasper F., and Schulz, Michael

Abstract

The source of dust in the global atmosphere is an important factor to better understand the role of dust aerosols in the climate system. However, it is a difficult task to attribute the airborne dust over the remote land and ocean regions to their origins since dust from various sources are mixed during long‐range transport. Recently, a multi‐model experiment, namely the AeroCom‐III Dust Source Attribution (DUSA), has been conducted to estimate the relative contribution of dust in various locations from different sources with tagged simulations from seven participating global models. The BASE run and a series of runs with nine tagged regions were made to estimate the contribution of dust emitted in East‐ and West‐Africa, Middle East, Central‐ and East‐Asia, North America, the Southern Hemisphere, and the prominent dust hot spots of the Bodélé and Taklimakan Deserts. The models generally agree in large scale mean dust distributions, however models show large diversity in dust source attribution. The inter‐model differences are significant with the global model dust diversity in 30%–50%, but the differences in regional and seasonal scales are even larger. The multi‐model analysis estimates that North Africa contributes 60% of global atmospheric dust loading, followed by Middle East and Central Asia sources (24%). Southern hemispheric sources account for 10% of global dust loading, however it contributes more than 70% of dust over the Southern Hemisphere. The study provides quantitative estimates of the impact of dust emitted from different source regions on the globe and various receptor regions including remote land, ocean, and the polar regions synthesized from the seven models. As the most abundant aerosol type in the Earth's atmosphere, mineral dust plays an important role in global climate by interacting with incoming and outgoing radiation, providing liquid and ice cloud nuclei, and affecting atmospheric stability. The global dust sources are relatively well characterized by the remote sensing and modeling studies as the majority of dust is emitted from the so‐called dust belt which expands from North Africa to East Asia. However, it is challenging to attribute dust sources over the remote land and ocean regions, since dust is mixed during long‐range transport, where it experiences complex atmospheric processes, including horizontal and vertical‐advection, wet deposition, and dry deposition. Using the multi‐model simulations in the Aerocom/Dust Source Attribution experiment, the present study (a) examines the model diversity in dust source attribution and (b) estimates the contribution of dust sources to various receptor regions, including remote land/ocean and the polar regions in different altitudes, from the multi‐model statistics. Beyond dust sources, many remote land, ocean, and polar regions are affected by a mixture of dust from various sources around the globe. Contributions of various dust sources are quantitatively estimated in a multi‐model experimentContributions of various sources have different horizontal and vertical distributions and seasonalityDust near source regions are dominated by dust emitted in the upwind source regions; however many remote land, ocean, and polar regions are affected by a mixture of dust from various sources around the globe Contributions of various dust sources are quantitatively estimated in a multi‐model experiment Contributions of various sources have different horizontal and vertical distributions and seasonality Dust near source regions are dominated by dust emitted in the upwind source regions; however many remote land, ocean, and polar regions are affected by a mixture of dust from various sources around the globe

Published

2024

36. The Importance of Dynamic Iron Deposition in Projecting Climate Change Impacts on Pacific Ocean Biogeochemistry

Author

Drenkard, Elizabeth J., John, Jasmin G., Stock, Charles A., Lim, Hyung‐Gyu, Dunne, John P., Ginoux, Paul, and Luo, Jessica Y.

Abstract

Deposition of mineral dust plays an important role in upper‐ocean biogeochemical processes, particularly by delivering iron to iron‐limited regions. Here we examine the impact of dynamically changing iron deposition on tropical Pacific Ocean biogeochemistry in fully coupled earth system model projections under several emissions scenarios. Projected end‐of‐21st‐century increases in central tropical Pacific dust and iron deposition strengthen with increasing emissions/radiative forcing, and are aligned with projected soil moisture decreases in adjacent land areas and precipitation increases over the equatorial Pacific. Increased delivery of soluble iron results in a reduction in, and eastward contraction of, equatorial Pacific phytoplankton iron limitation and shifts primary production and particulate organic carbon flux projections relative to a high emissions projection (SSP5‐8.5) wherein soluble iron deposition is prescribed as a static climatology. These results highlight modeling advances in representing coupled land‐air‐sea interactions to project basin‐scale patterns of ocean biogeochemical change. We use an Earth System Model (ESM) to explore climate‐driven changes in the deposition of dust and iron from the atmosphere to the ocean under a range of climate change scenarios. These simulations use a “dynamic” approach for iron deposition which means iron deposition is affected by changing atmospheric dust loads and factoring in wind and precipitation which affect dust and iron transfer from the atmosphere to the ocean. Under increasing climate change scenarios, GFDL's ESM4.1 projects drier soil conditions, as well as more dust in the atmosphere and precipitation over the Pacific Ocean toward the end of the 21st century. Elevated levels of future iron delivery to the ocean reduce iron limitation of phytoplankton growth in the central Pacific. As a result, we find higher levels of phytoplankton production in the central, equatorial Pacific but lower levels downstream in the western and off‐equatorial Pacific because other nutrients necessary for growth are depleted by reduced upwelling and enhanced production in the eastern Pacific. This geographic pattern also appears in the change in carbon sinking from the surface ocean to depth. Overall, these results highlight how ESM advances can improve our understanding of climate change impacts on marine ecosystems. Dynamically modeled atmosphere‐to‐ocean soluble iron deposition permits deposition driver variability to affect upper ocean biogeochemistryTropical Pacific iron deposition increases with radiative forcing, affecting phytoplankton nutrient limitation, production, and POC fluxDeposition increases align with soil moisture decreases in adjacent land areas, and precipitation increases over the equatorial Pacific Dynamically modeled atmosphere‐to‐ocean soluble iron deposition permits deposition driver variability to affect upper ocean biogeochemistry Tropical Pacific iron deposition increases with radiative forcing, affecting phytoplankton nutrient limitation, production, and POC flux Deposition increases align with soil moisture decreases in adjacent land areas, and precipitation increases over the equatorial Pacific

Published

2023

37. Influence of printing irregularities on the elastic behavior and mesostructural stress concentrations in material extrusion additive manufacturing—A numerical approach based on X-ray tomography

Author

Paux, Joseph, Ginoux, Geoffrey, Pulickan, Shyam, and Allaoui, Samir

Abstract

Materials manufactured by additive manufacturing processes based on extrusion of polymer are recent and difficult to model due to their complex and irregular mesostructure. In the case of printed material with parallel extruded rasters, the existing models, based on 2D Representative Volume Elements (RVEs), neglect the influence of the variation of the cavity shape along the printing direction due to printing irregularities such as ghosting or rippling. In this paper, the mesostructure of the printed material is investigated based on X-ray tomography, and a new approach to extract a 3D RVE is proposed. The new method provides typical mesostructural features of interest, and, in particular, the defects induced by printing irregularities. This method is used to define RVEs for different mesostructures associated with different printing conditions. A numerical homogenization of the printed material based on these RVEs is performed using the Fast-Fourier Transform (FFT) method to determine its macroscopic properties. Both macroscopic elastic properties of the printed material and stress concentrations in the mesostructure are studied and compared to estimate the influence of the different typical mesostructures on the mechanical behavior of the printed material. The results establish a significant influence of the variation of the mesostructure induced by the printing conditions on the rigidity of the printed material, showing the efficiency of the method to better predict the structure–properties relationships of material extrusion additive manufacturing (MEAM) based material. Furthermore, the method links the mesostructural defects to the induced stress concentrations in the mesostructure, thus to their criticality to the resistance of the material.

Published

2023

38. New preparation method of microstructurally and mechanically standardized PETG specimens by material extrusion additive manufacturing and machining

Author

Ginoux, Geoffrey, Paux, Joseph, and Allaoui, Samir

Abstract

Additive manufacturing processes are recent and lack standardized methods to characterize the mechanical properties of the printed material. Sample preparations in the literature consist in the direct printing of specimens, which induces uncontrolled interactions between printing conditions of the specimens and material properties. This study aims to develop a method for the specimen preparation to characterize the behavior of materials manufactured by material extrusion additive manufacturing. The proposed method consists in preparing printed plates from polyethylene terephthalate glycol-modified filament into a unique design before machining out specimens at different orientation angles. A comparison to directly printed specimens at the same orientation angles is performed to confront the proposed method to a commonly used one in the literature, and to understand the cause of discrepancies and the lack of predictiveness in additive manufacturing. The prepared specimens are characterized by X-ray tomography and tensile tests to assess process-structure-property relationships. The analysis highlights the structure heterogeneity of the as-printed specimen compared to the machined one, which influences the mechanical properties of the specimen. The new hybrid additive-subtractive preparation method for the specimen limits the superimposed thermo-kinetic effects caused by changes in deposition strategy, including coalescence and flow instability, and allows to measure effective mechanical properties based on a homogenized multiscale structure that is more representative of large parts. In addition, machining smooths the surface without thermal alterations, which leads to more accurate mechanical testing regarding cross-sectional area measurement, crack initiation and fracture mode. The proposed method is thought to standardize the preparation of additively manufactured materials based on extrusion to ease comparison between studies, to help the qualification of technical and industrial parts, and to measure intrinsic material’s properties based on a controlled microstructure for understanding of the process-related behavior and properties of material.

Published

2023

39. L’exercice physique pour la santé mentale : mécanismes, recommandations, recherches futures

Author

Legrand, Fabien D., Chaouloff, Francis, Ginoux, Clément, Ninot, Gregory, Polidori, Guillaume, Beaumont, Fabien, Murer, Sébastien, Jeandet, Philippe, and Pelissolo, Antoine

Abstract

L’idée d’utiliser diverses formes d’exercice physique pour améliorer la santé est largement répandue. Bien que cette idée remonte à l’antiquité, il était peu conventionnel jusqu’à ces dernières années d’envisager l’utilisation de l’exercice physique en tant que thérapie (principale ou adjuvante) dans la prise en charge des psychopathologies. Ces deux dernières décennies, cependant, nous assistons à une explosion de l’intérêt scientifique pour cette forme d’intervention non médicamenteuse. L’objectif de cette revue de littérature narrative est de fournir un aperçu complet et mis à jour des connaissances scientifiques dans ce domaine. Dans un premier temps, nous présentons un résumé des recherches contemporaines évaluant les effets à court et à long terme de l’exercice physique sur la santé mentale. Puis nous évoquons dans la partie principale de cet article une liste de mécanismes explicatifs et de leurs soubassements neurobiologiques actuellement proposés pour rendre compte des effets favorables de l’exercice physique. Enfin nous proposons des orientations pour les recherches futures ainsi qu’une série de recommandations concrètes pour les cliniciens qui souhaitent intégrer la prescription d’activité physique dans leur pratique clinique.

Published

2023

40. Oceanic and Atmospheric Drivers of Post‐El‐Niño Chlorophyll Rebound in the Equatorial Pacific

Author

Lim, Hyung‐Gyu, Dunne, John P., Stock, Charles A., Ginoux, Paul, John, Jasmin G., and Krasting, John

Abstract

The El Niño‐Southern Oscillation (ENSO) strongly influences phytoplankton in the tropical Pacific, with El Niño conditions suppressing productivity in the equatorial Pacific (EP) and placing nutritional stresses on marine ecosystems. The Geophysical Fluid Dynamics Laboratory's (GFDL) Earth System Model version 4.1 (ESM4.1) captures observed ENSO‐chlorophyll patterns (r= 0.57) much better than GFDL's previous ESM2M (r= 0.23). Most notably, the observed post‐El Niño “chlorophyll rebound” is substantially improved in ESM4.1 (r= 0.52). We find that an anomalous increase in iron propagation from western Pacific (WP) subsurface to the cold tongue via the equatorial undercurrent (EUC) and subsequent post‐El Niño surfacing, unresolved in ESM2M, is the primary driver of chlorophyll rebound. We also find that this chlorophyll rebound is augmented by high post‐El Niño dust‐iron deposition anomalies in the eastern EP. This post‐El Niño chlorophyll rebound provides a previously unrecognized source of marine ecosystem resilience independent from the La Niña that sometimes follows. In the tropical Pacific, year‐to‐year changes in chlorophyll, a proxy for the phytoplankton base of ocean food webs, is dominated by the El Niño–Southern Oscillation. El Niño, triggered by westerly wind anomalies and subsequent redistributions of upper ocean heat content, can sharply reduce the regional supply of nutrients limiting phytoplankton growth. A new Earth System Model captures not only the onset and extent of chlorophyll anomalies during El Niño events, but also a pronounced post‐El Niño “chlorophyll rebound” that produces positive equatorial Pacific chlorophyll anomalies in the summer following El Niño events. This post‐El Niño chlorophyll rebound is primarily driven by positive iron anomalies propagated from the subsurface western Pacific to the surface eastern Pacific cold tongue via the Equatorial Undercurrent. High post‐El Niño dust deposition anomalies arising from dry land conditions in Central and South America augment the post‐El Niño chlorophyll rebound. This post‐El Niño chlorophyll rebound provides a key source of resilience to marine ecosystems in the equatorial Pacific. The observed post‐El Niño chlorophyll anomaly, “chlorophyll rebound,” in the equatorial Pacific is successfully simulated in GFDL‐ESM4.1This rebound is primarily driven by surfacing high iron anomalies propagated from western Pacific via Equatorial UndercurrentHigh dust‐iron deposition anomalies arising from dry land conditions augment the post‐El Niño chlorophyll rebound The observed post‐El Niño chlorophyll anomaly, “chlorophyll rebound,” in the equatorial Pacific is successfully simulated in GFDL‐ESM4.1 This rebound is primarily driven by surfacing high iron anomalies propagated from western Pacific via Equatorial Undercurrent High dust‐iron deposition anomalies arising from dry land conditions augment the post‐El Niño chlorophyll rebound

Published

2022

41. Letter to the Editor regarding Chappell et al., 2023, "Satellites reveal Earth's seasonally shifting dust emission sources".

Author

Mahowald N, Ginoux P, Okin GS, Kok J, Albani S, Balkanski Y, Chin M, Bergametti G, Eck TF, Pérez García-Pando C, Gkikas A, Gonçalves Ageitos M, Kim D, Klose M, LeGrand S, Li L, Marticorena B, Miller R, Ryder C, Zender C, and Yu Y

Abstract

Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Published

2024

42. Decreased dust particles amplify the cloud cooling effect by regulating cloud ice formation over the Tibetan Plateau.

Author

Chen J, Xu J, Wu Z, Meng X, Yu Y, Ginoux P, DeMott PJ, Xu R, Zhai L, Yan Y, Zhao C, Li SM, Zhu T, and Hu M

Abstract

Ice-nucleating particles (INPs) can initiate cloud ice formation, influencing cloud radiative effects (CRE) and climate. However, the knowledge of INP sources, concentrations, and their impact on CRE over the Tibetan Plateau (TP)-a highly climate-sensitive region-remains largely hypothetical. Here, we integrated data from multisource satellite observations and snowpack samples collected from five glaciers to demonstrate that dust particles constitute primary INP sources over the TP. The springtime dust influxes lead to seasonally elevated ice concentrations in mixed-phase clouds. Furthermore, the decadal reduction in dustiness from 2007 to 2019 results in decreased springtime dust INPs, thereby amplifying the cooling effect of clouds over the TP, with a 1.98 ± 0.39-watt per square meter reduction in surface net CRE corresponding to a 0.01 decrease in dust optical depth. Our findings elucidate previously unidentified pathways of climate feedback from an atmospheric INP perspective, especially highlighting the crucial role of dust in aerosol-cloud interactions.

Published

2024

43. Threefold reduction of modeled uncertainty in direct radiative effects over biomass burning regions by constraining absorbing aerosols.

Author

Zhong Q, Schutgens N, van der Werf GR, Takemura T, van Noije T, Mielonen T, Checa-Garcia R, Lohmann U, Kirkevåg A, Olivié DJL, Kokkola H, Matsui H, Kipling Z, Ginoux P, Le Sager P, Rémy S, Bian H, Chin M, Zhang K, Bauer SE, and Tsigaridis K

Abstract

Absorbing aerosols emitted from biomass burning (BB) greatly affect the radiation balance, cloudiness, and circulation over tropical regions. Assessments of these impacts rely heavily on the modeled aerosol absorption from poorly constrained global models and thus exhibit large uncertainties. By combining the AeroCom model ensemble with satellite and in situ observations, we provide constraints on the aerosol absorption optical depth (AAOD) over the Amazon and Africa. Our approach enables identification of error contributions from emission, lifetime, and MAC (mass absorption coefficient) per model, with MAC and emission dominating the AAOD errors over Amazon and Africa, respectively. In addition to primary emissions, our analysis suggests substantial formation of secondary organic aerosols over the Amazon but not over Africa. Furthermore, we find that differences in direct aerosol radiative effects between models decrease by threefold over the BB source and outflow regions after correcting the identified errors. This highlights the potential to greatly reduce the uncertainty in the most uncertain radiative forcing agent.

Published

2023