+44 1613068532

Dr. Xiaohong Liu is a Professor and the Reta Haynes Chair in Geosciences at Texas A&M University. His research focuses on cloud-aerosol-precipitation-radiation interactions and effects on climate change; multi-scale modeling of clouds and aerosols and their interactions in the climate system; and developments of cloud and aerosol parameterizations for Earth System Models.

Dr. Xiaohong Liu is a Professor and the Reta Haynes Chair in Geosciences at Texas A&M University. His research focuses on cloud-aerosol-precipitation-radiation interactions and effects on climate change; multi-scale modeling of clouds and aerosols and their interactions in the climate system; and developments of cloud and aerosol parameterizations for Earth System Models.

9798455566

Employed at Inst. Energy Clim. Res. (IEK-7), Forschungszentrum Jülich Lead author, author, contributer and reviewer WMO ozone assessments (1998-2018) Lead author, IPCC special report on safeguarding the ozone layer and the global climate system (2004-2005) Reviewer IPCC reports AR4 to AR6 (2006-2020) Regular lectures on a variety of topics at the University of Wuppertal. Reviewer for various scientific journals and international funding agencies.

Employed at Inst. Energy Clim. Res. (IEK-7), Forschungszentrum Jülich Lead author, author, contributer and reviewer WMO ozone assessments (1998-2018) Lead author, IPCC special report on safeguarding the ozone layer and the global climate system (2004-2005) Reviewer IPCC reports AR4 to AR6 (2006-2020) Regular lectures on a variety of topics at the University of Wuppertal. Reviewer for various scientific journals and international funding agencies.

Dr. Gabriele Stiller is an expert for remote sensing of the atmospheric composition. Her scientific interest covers the physics and chemistry of the atmosphere from the upper troposphere to the mesopause. In the last years she has been working on the analysis of the mean meridional circulation of the stratosphere and mesosphere, ozone recovery and water vapour trends in the UTLS, and transport from the troposphere into the stratosphere. She leads the 'Satellite-borne remote sensing of trace gases' group at Karlsruhe Institute of Technology, Institute of Meteorology and Climate Research - Atmospheric Trace Gases and Remote Sensing (KIT/IMK-ASF).

Dr. Gabriele Stiller is an expert for remote sensing of the atmospheric composition. Her scientific interest covers the physics and chemistry of the atmosphere from the upper troposphere to the mesopause. In the last years she has been working on the analysis of the mean meridional circulation of the stratosphere and mesosphere, ozone recovery and water vapour trends in the UTLS, and transport from the troposphere into the stratosphere. She leads the 'Satellite-borne remote sensing of trace gases' group at Karlsruhe Institute of Technology, Institute of Meteorology and Climate Research - Atmospheric Trace Gases and Remote Sensing (KIT/IMK-ASF).

Franziska's research focusses on the dynamics of the atmospheric water cycle. Her scientific work is driven by a deep fascination for the complexity and diversity of the processes that a water molecule undergoes from the oceanic source of evaporation, to transport through weather systems, to cloud formation and infiltration as part of a raindrop in the soil. She is an expert on stable water isotope physics and has 10 years experience in multi-platform observations of water isotopes using laser spectrometers. She has contributed to various field campaigns from the tropics to the poles with observations conducted on ships, aircrafts and at observatories. In her research, she combines observations with trajectory-based approaches, as well as high-resolution model simulations using a regional isotope-enabled climate model. Given the interconnected nature of the water cycle with other Earth system components, she collaborates with experts in meteorology, hydrology, snow physics, remote sensing and chemistry. She is currently an assistant professor at the University of Bern in Switzerland. Her team's work serves as a basis for reliable forecasts of the rapid changes in the water cycle with global warming.

Franziska's research focusses on the dynamics of the atmospheric water cycle. Her scientific work is driven by a deep fascination for the complexity and diversity of the processes that a water molecule undergoes from the oceanic source of evaporation, to transport through weather systems, to cloud formation and infiltration as part of a raindrop in the soil. She is an expert on stable water isotope physics and has 10 years experience in multi-platform observations of water isotopes using laser spectrometers. She has contributed to various field campaigns from the tropics to the poles with observations conducted on ships, aircrafts and at observatories. In her research, she combines observations with trajectory-based approaches, as well as high-resolution model simulations using a regional isotope-enabled climate model. Given the interconnected nature of the water cycle with other Earth system components, she collaborates with experts in meteorology, hydrology, snow physics, remote sensing and chemistry. She is currently an assistant professor at the University of Bern in Switzerland. Her team's work serves as a basis for reliable forecasts of the rapid changes in the water cycle with global warming.

Allison C. Aiken is a scientist in the Earth & Environmental Sciences Division at Los Alamos National Laboratory (LANL). She is an analytical chemist specializing in the direct measurement of aerosol chemistry, physical and optical properties to elucidate complex aerosol processes in the atmosphere. Her research focus on the dynamic nature of aerosols uses chemistry to understand the changes in aerosol optical properties, water uptake and the physical properties that drive transport, particle growth and atmospheric lifetimes. Aiken is known for developing new analytical techniques in the laboratory using real-time aerosol measurements and applying them to complex ambient datasets and is considered one of the World’s Most Influential Scientific Minds by Thomson-Reuters as of 2014 due to her highly cited publication record (top 1%) in her field. Aiken received her PhD in Chemistry from the University of Colorado at Boulder for her work on aerosol mass spectrometry with a NASA Earth System Science Graduate Student Fellowship. Aiken developed a novel and largely applied method that allowed for the measurement of Oxygen-to-Carbon ratios from high-time resolution online in situ measurements. In 2011 as a Director’s Postdoctoral Fellow at LANL she focused on aerosol optical and physical properties in addition to aerosol chemistry. From 2013-2018 Aiken was the Operations Lead for three Aerosol Observing Systems (AOS) for the U.S. Department of Energy’s (DOE) Atmospheric Radiation Measurement (ARM) Facility. She is the co-founder and co-Director of the Center for Aerosol and Trace Gas Forensics (CAFE) and is the point of contact for DOE Atmospheric Systems Research (ASR) at LANL. Her elected service roles include the Board of Directors for the American Association for Aerosol Research (AAAR, 2019-22) and serving as the chair of the User Executive Committee (2021-22) for the U.S. DOE ARM facility.

Allison C. Aiken is a scientist in the Earth & Environmental Sciences Division at Los Alamos National Laboratory (LANL). She is an analytical chemist specializing in the direct measurement of aerosol chemistry, physical and optical properties to elucidate complex aerosol processes in the atmosphere. Her research focus on the dynamic nature of aerosols uses chemistry to understand the changes in aerosol optical properties, water uptake and the physical properties that drive transport, particle growth and atmospheric lifetimes. Aiken is known for developing new analytical techniques in the laboratory using real-time aerosol measurements and applying them to complex ambient datasets and is considered one of the World’s Most Influential Scientific Minds by Thomson-Reuters as of 2014 due to her highly cited publication record (top 1%) in her field. Aiken received her PhD in Chemistry from the University of Colorado at Boulder for her work on aerosol mass spectrometry with a NASA Earth System Science Graduate Student Fellowship. Aiken developed a novel and largely applied method that allowed for the measurement of Oxygen-to-Carbon ratios from high-time resolution online in situ measurements. In 2011 as a Director’s Postdoctoral Fellow at LANL she focused on aerosol optical and physical properties in addition to aerosol chemistry. From 2013-2018 Aiken was the Operations Lead for three Aerosol Observing Systems (AOS) for the U.S. Department of Energy’s (DOE) Atmospheric Radiation Measurement (ARM) Facility. She is the co-founder and co-Director of the Center for Aerosol and Trace Gas Forensics (CAFE) and is the point of contact for DOE Atmospheric Systems Research (ASR) at LANL. Her elected service roles include the Board of Directors for the American Association for Aerosol Research (AAAR, 2019-22) and serving as the chair of the User Executive Committee (2021-22) for the U.S. DOE ARM facility.

+44 1613068532

+41-(0)56 310-4049

I am an enthusiastic aerosol scientist with over 20 years of research experience. I did my PhD in 2010 at the University of Helsinki. Since 2008, I work at the Finnish Meteorological Institute (FMI), except the years abroad as a visiting scientist, first in Université Blaise Pascal (UBP) in Clermont-Ferrand, France and then in Servicio Meteorológico Nacional (SMN) in Buenos Aires, Argentina. I have about 100 peer-reviewed publications related to global experimental aerosol research. Recently, my research focus has been aerosol climate impacts on snow/ice -covered regions. I lead a research group called "Aerosols and Climate" consisting of about 25 researchers at FMI.

I am an enthusiastic aerosol scientist with over 20 years of research experience. I did my PhD in 2010 at the University of Helsinki. Since 2008, I work at the Finnish Meteorological Institute (FMI), except the years abroad as a visiting scientist, first in Université Blaise Pascal (UBP) in Clermont-Ferrand, France and then in Servicio Meteorológico Nacional (SMN) in Buenos Aires, Argentina. I have about 100 peer-reviewed publications related to global experimental aerosol research. Recently, my research focus has been aerosol climate impacts on snow/ice -covered regions. I lead a research group called "Aerosols and Climate" consisting of about 25 researchers at FMI.

Roya Bahreini is a Professor of Atmospheric Science in the Department of Environmental Sciences at University of California, Riverside. She specializes in airborne, ground-based, and laboratory measurements of aerosol composition and microphysical properties to understand aerosol sources and formation process, influence on air quality, and direct- and indirect-effects on climate.

Roya Bahreini is a Professor of Atmospheric Science in the Department of Environmental Sciences at University of California, Riverside. She specializes in airborne, ground-based, and laboratory measurements of aerosol composition and microphysical properties to understand aerosol sources and formation process, influence on air quality, and direct- and indirect-effects on climate.

My research focuses on the links between aerosol and climate. Aerosols, through their interactions with radiation, influence both the temperatures and the hydrological cycle. I study how aerosol physical properties modify precipitation. Since dust emissions depend on the presence of vegetation, I am currently coupling the vegetation with the dust cycle.

My research focuses on the links between aerosol and climate. Aerosols, through their interactions with radiation, influence both the temperatures and the hydrological cycle. I study how aerosol physical properties modify precipitation. Since dust emissions depend on the presence of vegetation, I am currently coupling the vegetation with the dust cycle.

+33-(0)1-69087725

I work on chemistry with relevance to cold regions of Earth’s atmosphere and develop near ambient pressure X-ray excited electron spectroscopy at the Swiss Light Source (SLS) for atmospheric research. Multiphase chemistry of aerosol, in snow, and in ice is fascinating due to the environmental impact and because the understudied chemistry under the dry and cold conditions shows surprising deviations from our text-book knowledge. Results from this laboratory based research address the molecular level up to the environmental scale.

I work on chemistry with relevance to cold regions of Earth’s atmosphere and develop near ambient pressure X-ray excited electron spectroscopy at the Swiss Light Source (SLS) for atmospheric research. Multiphase chemistry of aerosol, in snow, and in ice is fascinating due to the environmental impact and because the understudied chemistry under the dry and cold conditions shows surprising deviations from our text-book knowledge. Results from this laboratory based research address the molecular level up to the environmental scale.

+41563104301

Kelvin Bates is an atmospheric chemist studying the oxidation of organic molecules in the troposphere and their contribution to ozone pollution and aerosol formation. With a particular focus on the atmospheric reactions of isoprene and other biogenic molecules, Kelvin has expertise in laboratory experiments, field observations, and chemical transport modeling.

Kelvin Bates is an atmospheric chemist studying the oxidation of organic molecules in the troposphere and their contribution to ozone pollution and aerosol formation. With a particular focus on the atmospheric reactions of isoprene and other biogenic molecules, Kelvin has expertise in laboratory experiments, field observations, and chemical transport modeling.

Thomas Berkemeier is a research group leader at the Max Planck Institute for Chemistry, Mainz, Germany. His research is centered around the mathematical description of multiphase processes in the atmosphere and the human body. His research team develops kinetic models and conducts laboratory experiments with the goal of understanding the chemistry and physics of atmospherically- and health-relevant processes at and across interfaces. The modelling of detailed chemical, physical and biological processes is supported by data-centric approaches and algorithms, including machine learning.

Thomas Berkemeier is a research group leader at the Max Planck Institute for Chemistry, Mainz, Germany. His research is centered around the mathematical description of multiphase processes in the atmosphere and the human body. His research team develops kinetic models and conducts laboratory experiments with the goal of understanding the chemistry and physics of atmospherically- and health-relevant processes at and across interfaces. The modelling of detailed chemical, physical and biological processes is supported by data-centric approaches and algorithms, including machine learning.

Dr. Brown received a Ph. D. in physical chemistry with Professor Fleming Crim at the University of Wisconsin-Madison. He came to NOAA in 1997 as an NRC post-doctoral fellow working with Dr. A. R. Ravishankara, was a Research Scientist with CIRES at the University of Colorado from 2000 - 2005, and has served as a federal Research Chemist since then. He currently leads the Atmospheric Remote Sensing Program, and the Tropospheric Chemistry Program, a group that conducts field measurements to understand atmospheric composition with applications in air quality and climate. His major research theme at NOAA has been the chemistry and impacts of nitrogen oxides in the Earth's atmosphere, with an emphasis on nighttime chemical cycles. He has also led the development of high sensitivity optical instrumentation for laboratory and field studies of atmospheric trace gases and aerosols.

Dr. Brown received a Ph. D. in physical chemistry with Professor Fleming Crim at the University of Wisconsin-Madison. He came to NOAA in 1997 as an NRC post-doctoral fellow working with Dr. A. R. Ravishankara, was a Research Scientist with CIRES at the University of Colorado from 2000 - 2005, and has served as a federal Research Chemist since then. He currently leads the Atmospheric Remote Sensing Program, and the Tropospheric Chemistry Program, a group that conducts field measurements to understand atmospheric composition with applications in air quality and climate. His major research theme at NOAA has been the chemistry and impacts of nitrogen oxides in the Earth's atmosphere, with an emphasis on nighttime chemical cycles. He has also led the development of high sensitivity optical instrumentation for laboratory and field studies of atmospheric trace gases and aerosols.

303 351 2115

My group uses field measurements and laboratory experiments to understand the atmospheric chemistry important for aerosol formation and growth. My research interests include the modern atmosphere as well as other planetary atmospheres (e.g., Titan, Archean Eon Earth, etc.).

My group uses field measurements and laboratory experiments to understand the atmospheric chemistry important for aerosol formation and growth. My research interests include the modern atmosphere as well as other planetary atmospheres (e.g., Titan, Archean Eon Earth, etc.).

I lead the Climate Dynamics Lab at the University of St Andrews. We use theory, models and observations to understand the physical climate system. Recently we have been working to understand extreme temperatures in a warming climate, how clouds and water vapour influence monsoons, the dynamics of the tropical rainbelt, and why continents and oceans respond differently to climate change.

I lead the Climate Dynamics Lab at the University of St Andrews. We use theory, models and observations to understand the physical climate system. Recently we have been working to understand extreme temperatures in a warming climate, how clouds and water vapour influence monsoons, the dynamics of the tropical rainbelt, and why continents and oceans respond differently to climate change.

Dr. Abhishek Chatterjee is an expert on carbon cycle science, Earth system models, and utilization of greenhouse gas data for understanding and quantifying carbon-climate feedbacks. He is currently the Project Scientist for NASA’s OCO-3 mission and Deputy Project Scientist for the OCO-2 mission. His research primarily focuses on understanding the variability of sources and sinks of carbon dioxide and methane, processes that govern them and predicting their response to future patterns of human society and demographics as they interact with (and disrupt) the carbon-climate system.

Dr. Abhishek Chatterjee is an expert on carbon cycle science, Earth system models, and utilization of greenhouse gas data for understanding and quantifying carbon-climate feedbacks. He is currently the Project Scientist for NASA’s OCO-3 mission and Deputy Project Scientist for the OCO-2 mission. His research primarily focuses on understanding the variability of sources and sinks of carbon dioxide and methane, processes that govern them and predicting their response to future patterns of human society and demographics as they interact with (and disrupt) the carbon-climate system.

626-372-2234

00861062750508

+49-(0)6131-305-7201

Dr. Matthew Christensen is a staff scientist at the Pacific Northwest National Laboratory. His research focuses on quantifying the impact of natural and anthropogenic aerosols on boundary layer cloud processes, cloud lifetime and precipitation, and radiative forcing. He has developed retrievals for remote sensing and modeling for cloud systems, ship tracks and natural laboratories, and aerosol-cloud-interactions. He has been a co-I in two field campaigns: Atmospheric Composition and Radiative forcing changes due to UN International Ship Emission regulations (ACRUISE) and Atlantic Climate System Integrated Study (ACSIS). Dr. Christensen is also a steering committee member of Aerosols, Clouds, Precipitation and Climate (ACPC) and co-convener for several years of sessions at the AGU fall meeting.

Dr. Matthew Christensen is a staff scientist at the Pacific Northwest National Laboratory. His research focuses on quantifying the impact of natural and anthropogenic aerosols on boundary layer cloud processes, cloud lifetime and precipitation, and radiative forcing. He has developed retrievals for remote sensing and modeling for cloud systems, ship tracks and natural laboratories, and aerosol-cloud-interactions. He has been a co-I in two field campaigns: Atmospheric Composition and Radiative forcing changes due to UN International Ship Emission regulations (ACRUISE) and Atlantic Climate System Integrated Study (ACSIS). Dr. Christensen is also a steering committee member of Aerosols, Clouds, Precipitation and Climate (ACPC) and co-convener for several years of sessions at the AGU fall meeting.

I am involved in field observations and laboratory measurements of trace gases, atmospheric ions, and aerosol properties, especially measuring precursor gases for aerosol nucleation. This includes aircraft-borne observations (HALO aircraft) as well as laboratory studies of aerosol nucleation and precursor chemistry at the CLOUD chamber at CERN.

I am involved in field observations and laboratory measurements of trace gases, atmospheric ions, and aerosol properties, especially measuring precursor gases for aerosol nucleation. This includes aircraft-borne observations (HALO aircraft) as well as laboratory studies of aerosol nucleation and precursor chemistry at the CLOUD chamber at CERN.

+49-(0)69-79840258

Guy's research primarily focuses on the role of clouds in the climate system, particularly in relation to climate change. His specific interests lie in studying the interactions between clouds and the large-scale circulation of the atmosphere, employing both models and observational data. His research encompasses various aspects of aerosol-cloud interaction, cloud feedback mechanisms, as well as anthropogenic-driven changes in precipitation and atmospheric circulation patterns.

Guy's research primarily focuses on the role of clouds in the climate system, particularly in relation to climate change. His specific interests lie in studying the interactions between clouds and the large-scale circulation of the atmosphere, employing both models and observational data. His research encompasses various aspects of aerosol-cloud interaction, cloud feedback mechanisms, as well as anthropogenic-driven changes in precipitation and atmospheric circulation patterns.

Frank Dentener works since 25 years in the field climate change, agriculture and atmospheric pollution. Frank is senior expert and group leader at the European Commission’s Joint Research Centre. He completed a Ph.D. in Physics with Nobel prize-laureate Paul Crutzen at Utrecht University. He is member of the scientific advisory board of the JPI FACCE, and co-chair of WMO’s Scientific Advisory Group on near-real-time applications, and he has served on a variety of international commissions. He has (co-) authored more than 200 peer-reviewed publications and 3 IPCC reports, Hirsch factor 80, and is a Clarivate highly cited scientist. Frank held assistant professorships at Wageningen and Utrecht University, in the Nettherlands, and recently taught at at the ETH in Zurich. He supervised and examined ca. 10 Ph.D. and Habilitation candidates. Frank is an expert in atmospheric chemistry-land interactions, including ozone impacts on agriculture, agricultural production systems, and climate change and mitigation and adaptation.

Frank Dentener works since 25 years in the field climate change, agriculture and atmospheric pollution. Frank is senior expert and group leader at the European Commission’s Joint Research Centre. He completed a Ph.D. in Physics with Nobel prize-laureate Paul Crutzen at Utrecht University. He is member of the scientific advisory board of the JPI FACCE, and co-chair of WMO’s Scientific Advisory Group on near-real-time applications, and he has served on a variety of international commissions. He has (co-) authored more than 200 peer-reviewed publications and 3 IPCC reports, Hirsch factor 80, and is a Clarivate highly cited scientist. Frank held assistant professorships at Wageningen and Utrecht University, in the Nettherlands, and recently taught at at the ETH in Zurich. He supervised and examined ca. 10 Ph.D. and Habilitation candidates. Frank is an expert in atmospheric chemistry-land interactions, including ozone impacts on agriculture, agricultural production systems, and climate change and mitigation and adaptation.

+390332786392

Dr. Bryan N. Duncan is an atmospheric scientist in the Atmospheric Chemistry and Dynamics Laboratory (ACDL) at NASA Goddard Space Flight Center. He is Project Scientist for the NASA Aura satellite mission, which observes atmospheric constituents in the troposphere, stratosphere and mesosphere. He has expertise in air quality and tropospheric trace gas composition. He's a member of NASA's Health and Air Quality Applied Sciences Team, which facilitates the use of NASA satellite data by the health and air quality communities.

Dr. Bryan N. Duncan is an atmospheric scientist in the Atmospheric Chemistry and Dynamics Laboratory (ACDL) at NASA Goddard Space Flight Center. He is Project Scientist for the NASA Aura satellite mission, which observes atmospheric constituents in the troposphere, stratosphere and mesosphere. He has expertise in air quality and tropospheric trace gas composition. He's a member of NASA's Health and Air Quality Applied Sciences Team, which facilitates the use of NASA satellite data by the health and air quality communities.

Dr. (Mrs.) Suvarna S. Fadnavis Indian Institute of tropical Meteorology, Dr Homi Bhabha Road, Pashan, Pune, India. e-mail: suvarna@tropmet.res.in Tel: 91 (020) 25893600, Fax: 91 (020) 25893825 Designation: Scientist-F Awards: WMO’s International Nobert-Gerbier Mumm Award for 2005 Steering Committee member of Stratospheric Sulfur and its Role in Climate, a SPARC program. Steering Committee member of CCMI − Chemistry-Climate Model Initiative, a SPARC program. The reviewer of International panel for climate Change (IPCC) AR6 chapter-11. Expertise: (1) Long-range transport of air pollutants and regional impact, (2) Chemical - Climate Modelling (focus on South Asia), (3) Troposphere stratosphere exchange processes and their impact on climate, (4) Urban air pollution, Middle Atmospheric Dynamics

Dr. (Mrs.) Suvarna S. Fadnavis Indian Institute of tropical Meteorology, Dr Homi Bhabha Road, Pashan, Pune, India. e-mail: suvarna@tropmet.res.in Tel: 91 (020) 25893600, Fax: 91 (020) 25893825 Designation: Scientist-F Awards: WMO’s International Nobert-Gerbier Mumm Award for 2005 Steering Committee member of Stratospheric Sulfur and its Role in Climate, a SPARC program. Steering Committee member of CCMI − Chemistry-Climate Model Initiative, a SPARC program. The reviewer of International panel for climate Change (IPCC) AR6 chapter-11. Expertise: (1) Long-range transport of air pollutants and regional impact, (2) Chemical - Climate Modelling (focus on South Asia), (3) Troposphere stratosphere exchange processes and their impact on climate, (4) Urban air pollution, Middle Atmospheric Dynamics

Graham Feingold is a research scientist at NOAA's Chemical Laboratory in Boulder, Colorado. His interests lie in aerosol-cloud-precipitation interactions and implications for climate change. His focus is on process level studies using high resolution models and observations (aircraft and surface remote sensing) at the cloud scale (10s of meters to 10s of kms). He received his PhD in Geophysics and Planetary Sciences (summa cum laude) from the Tel Aviv University in 1989. His research interests include lidar and radar remote sensing of clouds and aerosol, modeling and remote sensing of aerosol-cloud interactions ("indirect effects"), "cloud burning" or the "semi-direct effect," and cloud processing of aerosol through multiphase chemistry. He has authored or co-authored more than 180 peer-reviewed articles on these subjects. Feingold was a lead author on the IPCC AR5 Chapter 7 (Clouds and Aerosols), an is associate editor of the online journal Atmospheric Chemistry and Physics (ACP), a contributor to the Climate Change Science Program, and a chapter author of the International Aerosol-Precipitation Scientific Assessment Project. He currently serves on the Aerosol-Cloud-Precipitation-Climate (ACPC) steering committee, and the NASA Aerosol and Cloud-Convection-and-Precipitation (A-CCP) Scientific Community Cohort (SCC) Advisory Group.

Graham Feingold is a research scientist at NOAA's Chemical Laboratory in Boulder, Colorado. His interests lie in aerosol-cloud-precipitation interactions and implications for climate change. His focus is on process level studies using high resolution models and observations (aircraft and surface remote sensing) at the cloud scale (10s of meters to 10s of kms). He received his PhD in Geophysics and Planetary Sciences (summa cum laude) from the Tel Aviv University in 1989. His research interests include lidar and radar remote sensing of clouds and aerosol, modeling and remote sensing of aerosol-cloud interactions ("indirect effects"), "cloud burning" or the "semi-direct effect," and cloud processing of aerosol through multiphase chemistry. He has authored or co-authored more than 180 peer-reviewed articles on these subjects. Feingold was a lead author on the IPCC AR5 Chapter 7 (Clouds and Aerosols), an is associate editor of the online journal Atmospheric Chemistry and Physics (ACP), a contributor to the Climate Change Science Program, and a chapter author of the International Aerosol-Precipitation Scientific Assessment Project. He currently serves on the Aerosol-Cloud-Precipitation-Climate (ACPC) steering committee, and the NASA Aerosol and Cloud-Convection-and-Precipitation (A-CCP) Scientific Community Cohort (SCC) Advisory Group.

1-865-974-2629

I am Associate Professor in Physics of the Earth System at the IUSS School for Advanced Studies in Pavia since 2022, where I teaches Climate Dynamics and Change to undergraduate and PhD students, and am head of the research centre Climate change impAct studies for RISk MAnagement (CARISMA). During my research work, I participated in several research projects and field campaigns at national and international level. Namely, African Monsoon Multidisciplinary Analysis (AMMA-FP6), Climate change and impact research: the Mediterranean environment (CIRCE-FP6), Dynamics-aerosol-chemistry-cloud interactions in West Africa (DACCIWA-FP7), Aerosol, Radiation and Clouds in southern Africa (AEROCLO-sA) and Clouds–Atmospheric Dynamics–Dust Interactions in West Africa (CADDIWA). My research focuses on atmosphere dynamics and past, present and future climate variability and change. In particular, I study the West African monsoon dynamics and teleconnections, the climate variability of the Euro-Atlantic region, the transport of aerosols from the African continent. He is also interested in the impact of climate variability and change on human activities, agriculture and energy sectors in particular.

I am Associate Professor in Physics of the Earth System at the IUSS School for Advanced Studies in Pavia since 2022, where I teaches Climate Dynamics and Change to undergraduate and PhD students, and am head of the research centre Climate change impAct studies for RISk MAnagement (CARISMA). During my research work, I participated in several research projects and field campaigns at national and international level. Namely, African Monsoon Multidisciplinary Analysis (AMMA-FP6), Climate change and impact research: the Mediterranean environment (CIRCE-FP6), Dynamics-aerosol-chemistry-cloud interactions in West Africa (DACCIWA-FP7), Aerosol, Radiation and Clouds in southern Africa (AEROCLO-sA) and Clouds–Atmospheric Dynamics–Dust Interactions in West Africa (CADDIWA). My research focuses on atmosphere dynamics and past, present and future climate variability and change. In particular, I study the West African monsoon dynamics and teleconnections, the climate variability of the Euro-Atlantic region, the transport of aerosols from the African continent. He is also interested in the impact of climate variability and change on human activities, agriculture and energy sectors in particular.

Drew Gentner is an Associate Professor of Chemical and Environmental Engineering at Yale University whose work focuses on air pollutant emissions including reactive organic carbon, their subsequent atmospheric chemistry and air quality impacts, as well as advancements in analytical chemistry capabilities to measure known, understudied, and emerging pollutants in a variety of environments.

Drew Gentner is an Associate Professor of Chemical and Environmental Engineering at Yale University whose work focuses on air pollutant emissions including reactive organic carbon, their subsequent atmospheric chemistry and air quality impacts, as well as advancements in analytical chemistry capabilities to measure known, understudied, and emerging pollutants in a variety of environments.

My research focuses on the characterization of atmospheric aerosol microphysical, chemical, and climate-relevant properties, and analysis of aerosol sources, transportation, and atmospheric processing. I Study atmospheric light absorbing particles (black carbon, organic aerosol, and dust) to identify their sources, transport mechanisms, and impacts on the cryosphere of high altitude regions and polar areas. I'm also involved in the identification of climate core variables and development of open access integrated database within SIOS (Svalbard Integrated Observing System). I'm interested in the application and development of aerosol source apportionment models, analysis of black carbon variability and trend in the Arctic region using Generalized Additive Models, study of cloud - aerosol interaction to reduce Arctic climate model uncertainty, and analysis and identification of mitigation measures to reduce back carbon emissions.

My research focuses on the characterization of atmospheric aerosol microphysical, chemical, and climate-relevant properties, and analysis of aerosol sources, transportation, and atmospheric processing. I Study atmospheric light absorbing particles (black carbon, organic aerosol, and dust) to identify their sources, transport mechanisms, and impacts on the cryosphere of high altitude regions and polar areas. I'm also involved in the identification of climate core variables and development of open access integrated database within SIOS (Svalbard Integrated Observing System). I'm interested in the application and development of aerosol source apportionment models, analysis of black carbon variability and trend in the Arctic region using Generalized Additive Models, study of cloud - aerosol interaction to reduce Arctic climate model uncertainty, and analysis and identification of mitigation measures to reduce back carbon emissions.

My research interests focus on the global-scale atmospheric circulation and its role in variability and long-term change in Earth’s climate system. In my research, I investigate the mechanisms responsible for variability and change in the atmospheric general circulation (e.g., Hadley cell, jet streams), the circulation’s impact on local climate (e.g., hydroclimate), and its feedbacks on the global climate system (e.g., cloud-circulation feedbacks).

My research interests focus on the global-scale atmospheric circulation and its role in variability and long-term change in Earth’s climate system. In my research, I investigate the mechanisms responsible for variability and change in the atmospheric general circulation (e.g., Hadley cell, jet streams), the circulation’s impact on local climate (e.g., hydroclimate), and its feedbacks on the global climate system (e.g., cloud-circulation feedbacks).

+49 2461 619184

00431 58801 165122

My research combines field measurements and laboratory studies to characterize the chemical-physical properties of organic aerosols, explore the SOA formation from land-ocean-atmosphere interactions via multiple oxidation pathways under atmospheric-relevant conditions, and address aerosol health and climate effects.

My research combines field measurements and laboratory studies to characterize the chemical-physical properties of organic aerosols, explore the SOA formation from land-ocean-atmosphere interactions via multiple oxidation pathways under atmospheric-relevant conditions, and address aerosol health and climate effects.

015257193621

Dr. Heus is an associate professor, working at Cleveland State University since 2014. Before that, he worked at the University of Cologne, the Max Planck Institute for Meteorology, and the Royal Dutch Meteorological Institution (KNMI). Dr. Heus achieved his PhD in 2008 from Delft University, and did his undergraduate work in Utrecht. His field of interest is on the physics of atmospheric boundary layers and clouds, with a focus on Large Eddy Simulations thereof.

Dr. Heus is an associate professor, working at Cleveland State University since 2014. Before that, he worked at the University of Cologne, the Max Planck Institute for Meteorology, and the Royal Dutch Meteorological Institution (KNMI). Dr. Heus achieved his PhD in 2008 from Delft University, and did his undergraduate work in Utrecht. His field of interest is on the physics of atmospheric boundary layers and clouds, with a focus on Large Eddy Simulations thereof.

+49 721 608 23249

Jianping Huang is a distinguished professor and founder of the College of Atmospheric Sciences, Lanzhou University, China. His research focuses on semi-arid climate change by combining observations, numerical modeling, and theoretical studies. He established the theoretical framework of a semi-arid climate change mechanism that emphasizes the effects of aerosol-cloud-precipitation, land-atmosphere and ocean-atmosphere interactions on climate change in semi-arid regions. In recent years, Huang has pioneered a series of studies on oxygen cycle and land cancer, which opened up a new field of climate change research. In addition, Huang is among the most highly cited researchers according to Clarivate in 2021 and 2022. He has received several awards for his research achievements, including the Second Prize of National Natural Science Award in 2013 and the First National Innovation Award in 2017.

Jianping Huang is a distinguished professor and founder of the College of Atmospheric Sciences, Lanzhou University, China. His research focuses on semi-arid climate change by combining observations, numerical modeling, and theoretical studies. He established the theoretical framework of a semi-arid climate change mechanism that emphasizes the effects of aerosol-cloud-precipitation, land-atmosphere and ocean-atmosphere interactions on climate change in semi-arid regions. In recent years, Huang has pioneered a series of studies on oxygen cycle and land cancer, which opened up a new field of climate change research. In addition, Huang is among the most highly cited researchers according to Clarivate in 2021 and 2022. He has received several awards for his research achievements, including the Second Prize of National Natural Science Award in 2013 and the First National Innovation Award in 2017.

Dr Yi Huang is a Senior Lecturer in Climate Science at the School of Geography, Earth and Atmospheric Sciences, The University of Melbourne. She is also a Chief Investigator of the ARC Centre of Excellence for Climate Extremes. My research seeks to address some of the fundamental yet climatically important questions that underpin the understanding of atmospheric processes, Earth’s energy budget and water cycle: How do clouds and precipitation modulate the Earth’s climate system? What processes control the properties of clouds and precipitation? How do these processes differ geographically? I believe this can only be achieved by innovative use of targeted field observations, state-of-the-art remote-sensing data and numerical modelling. Ultimately, my work aims to harness the critical knowledge that will help improve weather and climate predictions at multiple scales.

Dr Yi Huang is a Senior Lecturer in Climate Science at the School of Geography, Earth and Atmospheric Sciences, The University of Melbourne. She is also a Chief Investigator of the ARC Centre of Excellence for Climate Extremes. My research seeks to address some of the fundamental yet climatically important questions that underpin the understanding of atmospheric processes, Earth’s energy budget and water cycle: How do clouds and precipitation modulate the Earth’s climate system? What processes control the properties of clouds and precipitation? How do these processes differ geographically? I believe this can only be achieved by innovative use of targeted field observations, state-of-the-art remote-sensing data and numerical modelling. Ultimately, my work aims to harness the critical knowledge that will help improve weather and climate predictions at multiple scales.

+34868888175

+49-(0)8153-28-2565

+44-(0)1603-593393

+30-2810545033

+43 512 507 54455

　Kimitaka Kawamura worked on unsaturated fatty acids and related lipid compounds in a 200-me long sediment core taken from Lake Biwa in central Japan as part of Ph. D study at Tokyo Metropolitan University. After JSPS young scholar, he joined to I. R. Kaplan’s group of University of California, Los Angeles (UCLA) as a postdoctoral scholar for the study of rainwater chemistry where he developed new techniques to measure low molecular weight (LMW) C1-C10 mono- and C2-C10 di-carboxylic acids using a capillary gas chromatography and mass spectrometry. Kawamura worked at Woods Hole Oceanographic Institution (WHOI) as a visiting investigator on marine aerosols, in which he discovered a series of ω-oxocarboxylic acids with the predominance of 9-oxononanoic acid and proposed an importance of photochemical oxidation of unsaturated fatty acids of phytoplankton origin for the production of secondary organic aerosols in the marine atmosphere. 　　After coming back to Tokyo Metropolitan University as a faculty in 1987, Kawamura organized the studies of lipid class compounds, LMW dicarboxylic acids in urban rain and aerosols as well as remote marine aerosols and Arctic and Antarctic aerosols. He also started ice core studies for organics from Greenland and Antarctica. In 1996, Kawamura moved to Institute of Low Temperature Science, Hokkaido University, where he built a new laboratory of organic geochemistry and atmospheric chemistry. He continued atmospheric chemistry and organic geochemical studies with focus on long-range atmospheric transport and photochemical aging of aerosols in South/Southeast Asia and the outflow region in the western North Pacific. 　　In 2016, Kawamura moved to Chubu University to continue the studies of atmospheric chemistry and global environmental sciences. He continue the aerosol sampling at Canadian High Arctic (Alert) and remote Chichijima Island in the western North Pacific.

　Kimitaka Kawamura worked on unsaturated fatty acids and related lipid compounds in a 200-me long sediment core taken from Lake Biwa in central Japan as part of Ph. D study at Tokyo Metropolitan University. After JSPS young scholar, he joined to I. R. Kaplan’s group of University of California, Los Angeles (UCLA) as a postdoctoral scholar for the study of rainwater chemistry where he developed new techniques to measure low molecular weight (LMW) C1-C10 mono- and C2-C10 di-carboxylic acids using a capillary gas chromatography and mass spectrometry. Kawamura worked at Woods Hole Oceanographic Institution (WHOI) as a visiting investigator on marine aerosols, in which he discovered a series of ω-oxocarboxylic acids with the predominance of 9-oxononanoic acid and proposed an importance of photochemical oxidation of unsaturated fatty acids of phytoplankton origin for the production of secondary organic aerosols in the marine atmosphere. 　　After coming back to Tokyo Metropolitan University as a faculty in 1987, Kawamura organized the studies of lipid class compounds, LMW dicarboxylic acids in urban rain and aerosols as well as remote marine aerosols and Arctic and Antarctic aerosols. He also started ice core studies for organics from Greenland and Antarctica. In 1996, Kawamura moved to Institute of Low Temperature Science, Hokkaido University, where he built a new laboratory of organic geochemistry and atmospheric chemistry. He continued atmospheric chemistry and organic geochemical studies with focus on long-range atmospheric transport and photochemical aging of aerosols in South/Southeast Asia and the outflow region in the western North Pacific. 　　In 2016, Kawamura moved to Chubu University to continue the studies of atmospheric chemistry and global environmental sciences. He continue the aerosol sampling at Canadian High Arctic (Alert) and remote Chichijima Island in the western North Pacific.

Stelios research deals with aerosol and solar radiation measurements and modelling. His interests cover aspects related with aerosol metrology, aerosol radiative effects, aerosol-cloud interactions and also solar radiation measurements and applications (solar energy). Stelios leads the WMO defined World aerosol Optical depth and calibration center, is a member of the International Radiation Committee and of the WMO aerosol advisory group for aerosols. He teaches atmospheric remote sensing at Master students in ETH Zurich, Switzerland.

Stelios research deals with aerosol and solar radiation measurements and modelling. His interests cover aspects related with aerosol metrology, aerosol radiative effects, aerosol-cloud interactions and also solar radiation measurements and applications (solar energy). Stelios leads the WMO defined World aerosol Optical depth and calibration center, is a member of the International Radiation Committee and of the WMO aerosol advisory group for aerosols. He teaches atmospheric remote sensing at Master students in ETH Zurich, Switzerland.

+41 58 467 5137

I am a meteorologist with expertise in atmospheric modelling and remote sensing of trace gases. Especially, the combination of both measurements and models and the evaluation of these comprises large parts of my research activity.

I am a meteorologist with expertise in atmospheric modelling and remote sensing of trace gases. Especially, the combination of both measurements and models and the evaluation of these comprises large parts of my research activity.

+49 2461 61 96479

I study the physicochemical properties of aerosol particles and their role in multiphase chemical processes and ice cloud formation. These research topics are addresses by means of laboratory work, field measurements, and modeling studies.

I study the physicochemical properties of aerosol particles and their role in multiphase chemical processes and ice cloud formation. These research topics are addresses by means of laboratory work, field measurements, and modeling studies.

+1-(0)631-6323092

+46-(0)8-6747224

https://www.iitkgp.ac.in/department/CL/faculty/cl-jayan

https://www.iitkgp.ac.in/department/CL/faculty/cl-jayan

Luis is an Associate Professor at the Institute for Atmospheric Sciences and Climate Change at the National Autonomous University of Mexico (UNAM), Mexico. He is a member of the International Commission on Clouds and Precipitation (ICCP) and the Dust Alliance for North America (DANA). He is also the president of the new Latin American and Caribbean Association for Aerosol Studies (ALACEA). His main research interest focuses on atmospheric aerosols, cloud microphysics, atmospheric chemistry, aerosol-cloud interactions, and air pollution.

Luis is an Associate Professor at the Institute for Atmospheric Sciences and Climate Change at the National Autonomous University of Mexico (UNAM), Mexico. He is a member of the International Commission on Clouds and Precipitation (ICCP) and the Dust Alliance for North America (DANA). He is also the president of the new Latin American and Caribbean Association for Aerosol Studies (ALACEA). His main research interest focuses on atmospheric aerosols, cloud microphysics, atmospheric chemistry, aerosol-cloud interactions, and air pollution.

+551128105669

5093929097

Matt's research focuses on aerosol-cloud-precipitation interactions and cloud-climate-feedback using observations. His interests also include the representation of the relevant turbulent and microphysical processes in global models to improve the representation of these interactions.

Matt's research focuses on aerosol-cloud-precipitation interactions and cloud-climate-feedback using observations. His interests also include the representation of the relevant turbulent and microphysical processes in global models to improve the representation of these interactions.

Dr. Li received his Ph.D. from McGill University in 1991. After one year of postdoctoral research at the Meteorological Service of Canada, he was employed by the Canada Centre for Remote Sensing, and joined the Department of Atmospheric and Oceanic Science at the University of Maryland in 2001 as the youngest full professor. Since 2022, he has become a distinguished university professor. Dr. Li has engaged in meteorological, climate and environmental studies concerning cloud, radiation budget, aerosol, terrestrial environment, forest fire, air pollution, etc. He has published 360 peer-reviewed articles chiefly in world’s leading journals including Nature, Science, Nature-Geoscience, PNAS, Review of Geophysics, JGR, J. Climate, etc., with `20000 citations and h-index of 76 by Google Scholar. Dr. Li is an elected fellow of the AAAS, AGU and AMS. He received 10 awards in Canada, United States and Germany, including the AGU’s Kaufman Outstanding Research and Unselfish Collaboration award (the highest in the atmospheric section), the German’s Humboldt Research Award, the Head of Public Service Award of Canada, the Alouette Medal of the Canadian Aeronautics and Space Institute, etc. Dr. Li has served as an editor of the Journal Geophysical Research -Atmosphere since 2013, and the Atmospheric Chemistry and Physics since 2020 and an editor of the Advance in Meteorology (2008-2012)

Dr. Li received his Ph.D. from McGill University in 1991. After one year of postdoctoral research at the Meteorological Service of Canada, he was employed by the Canada Centre for Remote Sensing, and joined the Department of Atmospheric and Oceanic Science at the University of Maryland in 2001 as the youngest full professor. Since 2022, he has become a distinguished university professor. Dr. Li has engaged in meteorological, climate and environmental studies concerning cloud, radiation budget, aerosol, terrestrial environment, forest fire, air pollution, etc. He has published 360 peer-reviewed articles chiefly in world’s leading journals including Nature, Science, Nature-Geoscience, PNAS, Review of Geophysics, JGR, J. Climate, etc., with `20000 citations and h-index of 76 by Google Scholar. Dr. Li is an elected fellow of the AAAS, AGU and AMS. He received 10 awards in Canada, United States and Germany, including the AGU’s Kaufman Outstanding Research and Unselfish Collaboration award (the highest in the atmospheric section), the German’s Humboldt Research Award, the Head of Public Service Award of Canada, the Alouette Medal of the Canadian Aeronautics and Space Institute, etc. Dr. Li has served as an editor of the Journal Geophysical Research -Atmosphere since 2013, and the Atmospheric Chemistry and Physics since 2020 and an editor of the Advance in Meteorology (2008-2012)

1-301-405-6699

416-739-4840

Dr. Xiaohong Liu is a Professor and the Reta Haynes Chair in Geosciences at Texas A&M University. His research focuses on cloud-aerosol-precipitation-radiation interactions and effects on climate change; multi-scale modeling of clouds and aerosols and their interactions in the climate system; and developments of cloud and aerosol parameterizations for Earth System Models.

Dr. Xiaohong Liu is a Professor and the Reta Haynes Chair in Geosciences at Texas A&M University. His research focuses on cloud-aerosol-precipitation-radiation interactions and effects on climate change; multi-scale modeling of clouds and aerosols and their interactions in the climate system; and developments of cloud and aerosol parameterizations for Earth System Models.

9798455566

Dr. Jianzhong Ma was born in 1964 in Tianjin, China. He studied at Peking University as undergraduate and graduate students in succession during the period 1982-92. He was an undergraduate student at the Chemistry Department from 1982 to 1986, and received his bachelor degree in 1986. From 1986 to 1992, he was a graduate student at the Center for Environmental Sciences of Peking University, and received his master and doctoral degrees in Environmental Chemistry in 1989 and 1992, respectively. After graduation from Peking University in 1992, he worked at the Tianjin Institute of Environmental Sciences until 1994. From 1994 to 1996 he worked as a post doctor at the TNO Institute of Environmental Sciences and partly at the Institute of Marine and Atmospheric Research at Utrecht University in the Netherlands for two and half years. From 1997 to now on, he has worked at the Chinese Academy of Meteorological Sciences, as associate researcher, researcher, and leading research scientist in succession. The main research of Dr. Jianzhong Ma focuses on atmospheric chemical and physical processes related to air quality and climate change.

Dr. Jianzhong Ma was born in 1964 in Tianjin, China. He studied at Peking University as undergraduate and graduate students in succession during the period 1982-92. He was an undergraduate student at the Chemistry Department from 1982 to 1986, and received his bachelor degree in 1986. From 1986 to 1992, he was a graduate student at the Center for Environmental Sciences of Peking University, and received his master and doctoral degrees in Environmental Chemistry in 1989 and 1992, respectively. After graduation from Peking University in 1992, he worked at the Tianjin Institute of Environmental Sciences until 1994. From 1994 to 1996 he worked as a post doctor at the TNO Institute of Environmental Sciences and partly at the Institute of Marine and Atmospheric Research at Utrecht University in the Netherlands for two and half years. From 1997 to now on, he has worked at the Chinese Academy of Meteorological Sciences, as associate researcher, researcher, and leading research scientist in succession. The main research of Dr. Jianzhong Ma focuses on atmospheric chemical and physical processes related to air quality and climate change.

+86-(0)10-58995270

Rob MacKenzie joined the University of Birmingham in August 2011 as Professor of Atmospheric Science. Rob’s expertise is in computer simulation of various atmospheric processes, including the effects of vegetation on the composition of the atmosphere. In November 2013, Rob became the inaugural Director of the Birmingham Institute of Forest Research, a cross-campus initiative to provide fundamental science, social science and cultural research of direct relevance to forested landscapes – urban and rural - anywhere in the world.

Rob MacKenzie joined the University of Birmingham in August 2011 as Professor of Atmospheric Science. Rob’s expertise is in computer simulation of various atmospheric processes, including the effects of vegetation on the composition of the atmosphere. In November 2013, Rob became the inaugural Director of the Birmingham Institute of Forest Research, a cross-campus initiative to provide fundamental science, social science and cultural research of direct relevance to forested landscapes – urban and rural - anywhere in the world.

+44-(0)121 414 6142

My research interests are primarily based on Earth Sciences, focusing on atmospheric chemistry, climate, and air pollution. My past work is on climatically relevant trace gases such as reactive halogen species (RHS), volatile organic compounds (VOCs, including dimethyl sulphide) and ozone. My work concentrates on quantifying the effect of these gases on the oxidation capacity, aerosol formation and Earth’s radiation budget. Additionally, I am involved in studies on air pollution and its impact on health and productivity. Over the last twenty years, I have participated in numerous projects designed to improve our understanding of these compounds and their effect on the atmosphere. To do this, I use a three-pronged approach: instrument development, field observations and computer modelling at different scales. I have led large projects, including the most recent Indian Scientific Expedition to the Southern Ocean.

My research interests are primarily based on Earth Sciences, focusing on atmospheric chemistry, climate, and air pollution. My past work is on climatically relevant trace gases such as reactive halogen species (RHS), volatile organic compounds (VOCs, including dimethyl sulphide) and ozone. My work concentrates on quantifying the effect of these gases on the oxidation capacity, aerosol formation and Earth’s radiation budget. Additionally, I am involved in studies on air pollution and its impact on health and productivity. Over the last twenty years, I have participated in numerous projects designed to improve our understanding of these compounds and their effect on the atmosphere. To do this, I use a three-pronged approach: instrument development, field observations and computer modelling at different scales. I have led large projects, including the most recent Indian Scientific Expedition to the Southern Ocean.

Greg McFarquhar is the Director of the Cooperative Institute for Severe and High Impact Weather Research and Operations (CIWRO) and a professor in the School of Meteorology at the University of Oklahoma. He completed his B.Sc. in Mathematics & Physics at the University of Toronto, and a M.Sc. and Ph.D. in Atmospheric Physics at the University of Toronto. He has worked as a faculty member at the University of Illinois, a project scientist at the National Center for Atmospheric Research (NCAR), and a postdoctoral fellow at the Scripps Institution of Oceanography. He is a Fellow of the American Meteorological Society and American Geophysical Union and President of the International Commission on Clouds and Precipitation. His research is making advances in understanding the properties of clouds and the processes occurring in clouds in order to improve the ability to represent clouds in weather and climate models. His work uses field observations, satellite retrievals and numerical modeling studies. He has conducted 36 field campaigns measuring clouds using aircraft in locations such as Alaska, Oklahoma, Newfoundland, Australia, Namibia, French Guyana, Costa Rica, Malaysia, Fiji, the Maldives and others. He is Chief Editor of the American Meteorological Society Monograph Collection, Associate Editor of the Quarterly Journal of the Royal Meteorological Society, and Special Editor for the Journal of Geophysical Research. He serves on the College of Atmospheric and Geographic Sciences Diversity Equity and Inclusion (DEI) committee and heads the DEI committee within CIWRO.

Greg McFarquhar is the Director of the Cooperative Institute for Severe and High Impact Weather Research and Operations (CIWRO) and a professor in the School of Meteorology at the University of Oklahoma. He completed his B.Sc. in Mathematics & Physics at the University of Toronto, and a M.Sc. and Ph.D. in Atmospheric Physics at the University of Toronto. He has worked as a faculty member at the University of Illinois, a project scientist at the National Center for Atmospheric Research (NCAR), and a postdoctoral fellow at the Scripps Institution of Oceanography. He is a Fellow of the American Meteorological Society and American Geophysical Union and President of the International Commission on Clouds and Precipitation. His research is making advances in understanding the properties of clouds and the processes occurring in clouds in order to improve the ability to represent clouds in weather and climate models. His work uses field observations, satellite retrievals and numerical modeling studies. He has conducted 36 field campaigns measuring clouds using aircraft in locations such as Alaska, Oklahoma, Newfoundland, Australia, Namibia, French Guyana, Costa Rica, Malaysia, Fiji, the Maldives and others. He is Chief Editor of the American Meteorological Society Monograph Collection, Associate Editor of the Quarterly Journal of the Royal Meteorological Society, and Special Editor for the Journal of Geophysical Research. He serves on the College of Atmospheric and Geographic Sciences Diversity Equity and Inclusion (DEI) committee and heads the DEI committee within CIWRO.

Luis Millán received the degree in Telecommunications Engineering from the Monterrey Institute of Technology and Higher Education, Mexico City, Mexico, in 2003; the M.S. degree in Radio Astronomy and Space Science from Chalmers University of Technology, Gothenburg, Sweden, in 2005; and the D.Phil. degree in Atmospheric Physics from the University of Oxford, Oxford, U.K., in 2009. Since 2010, he has been a member of the Stratosphere and Upper Troposphere Group at the Jet Propulsion Laboratory, California Institute of Technology, Pasadena, California.

Luis Millán received the degree in Telecommunications Engineering from the Monterrey Institute of Technology and Higher Education, Mexico City, Mexico, in 2003; the M.S. degree in Radio Astronomy and Space Science from Chalmers University of Technology, Gothenburg, Sweden, in 2005; and the D.Phil. degree in Atmospheric Physics from the University of Oxford, Oxford, U.K., in 2009. Since 2010, he has been a member of the Stratosphere and Upper Troposphere Group at the Jet Propulsion Laboratory, California Institute of Technology, Pasadena, California.

Employed at Inst. Energy Clim. Res. (IEK-7), Forschungszentrum Jülich Lead author, author, contributer and reviewer WMO ozone assessments (1998-2018) Lead author, IPCC special report on safeguarding the ozone layer and the global climate system (2004-2005) Reviewer IPCC reports AR4 to AR6 (2006-2020) Regular lectures on a variety of topics at the University of Wuppertal. Reviewer for various scientific journals and international funding agencies.

Employed at Inst. Energy Clim. Res. (IEK-7), Forschungszentrum Jülich Lead author, author, contributer and reviewer WMO ozone assessments (1998-2018) Lead author, IPCC special report on safeguarding the ozone layer and the global climate system (2004-2005) Reviewer IPCC reports AR4 to AR6 (2006-2020) Regular lectures on a variety of topics at the University of Wuppertal. Reviewer for various scientific journals and international funding agencies.

My research has mainly been on atmospheric compositional change and quantifications of radiative forcing of greenhouse gases and aerosols. More recently, my research interest has included the global energy budget, precipitation, and extreme precipitation.

My research has mainly been on atmospheric compositional change and quantifications of radiative forcing of greenhouse gases and aerosols. More recently, my research interest has included the global energy budget, precipitation, and extreme precipitation.

34425578

Sergey Nizkorodov was born in 1971 in Almaty, Kazakhstan. He received his undergraduate degree in biochemistry from Novosibirsk State University, Russia, in 1993 and graduate degree in physical chemistry from Basel University, Switzerland, in 1997. After doing his postdoctoral research in chemical kinetics and reaction dynamics at the University of Colorado at Boulder, and in atmospheric chemistry at the California Institute of Technology, he joined the faculty of the Department of Chemistry, University of California, Irvine (UCI) in 2002. He teaches general, analytical, and atmospheric chemistry courses at UCI, and does research on chemistry of particulate matter in the ambient atmosphere and in indoor environments using state-of-the-art spectroscopic and mass-spectrometric techniques. He has been a research mentor to over 100 graduate, undergraduate, high-school, and postdoctoral students. His research, education, service and public outreach work have been recognized by several awards including Fulbright Scholarship, AAAS Fellowship, Camille Dreyfus Teacher-Scholar Award, AGU Ascent Award, Coblentz Award, UCI Chancellor's Award for Excellence in Fostering Undergraduate Research, Daniel G. Aldrich, Jr. Distinguished University Service Award, and UCI Professor of the Year Award. He served as the President of the American Association for Aerosol Research (AAAR) in 2020-21, a professional organization of about 1000 scientists and engineers working to advance the field of aerosol research and technology, and been active in various service roles at UCI and in the research community.

Sergey Nizkorodov was born in 1971 in Almaty, Kazakhstan. He received his undergraduate degree in biochemistry from Novosibirsk State University, Russia, in 1993 and graduate degree in physical chemistry from Basel University, Switzerland, in 1997. After doing his postdoctoral research in chemical kinetics and reaction dynamics at the University of Colorado at Boulder, and in atmospheric chemistry at the California Institute of Technology, he joined the faculty of the Department of Chemistry, University of California, Irvine (UCI) in 2002. He teaches general, analytical, and atmospheric chemistry courses at UCI, and does research on chemistry of particulate matter in the ambient atmosphere and in indoor environments using state-of-the-art spectroscopic and mass-spectrometric techniques. He has been a research mentor to over 100 graduate, undergraduate, high-school, and postdoctoral students. His research, education, service and public outreach work have been recognized by several awards including Fulbright Scholarship, AAAS Fellowship, Camille Dreyfus Teacher-Scholar Award, AGU Ascent Award, Coblentz Award, UCI Chancellor's Award for Excellence in Fostering Undergraduate Research, Daniel G. Aldrich, Jr. Distinguished University Service Award, and UCI Professor of the Year Award. He served as the President of the American Association for Aerosol Research (AAAR) in 2020-21, a professional organization of about 1000 scientists and engineers working to advance the field of aerosol research and technology, and been active in various service roles at UCI and in the research community.

949 824 1262

I lead the Chair for Artificial Intelligence in Climate and Environmental Sciences at KIT. My group works on a diverse set of scientific and methodological challenges in climate science and atmospheric chemistry. For this, we combine machine learning techniques, numerical Earth system models, and Earth observations (e.g., satellite data).

I lead the Chair for Artificial Intelligence in Climate and Environmental Sciences at KIT. My group works on a diverse set of scientific and methodological challenges in climate science and atmospheric chemistry. For this, we combine machine learning techniques, numerical Earth system models, and Earth observations (e.g., satellite data).

3152287764

Major main research areas: 1) Aerosol-cloud interactions, 2) Development of mass spectrometric methods for atmospheric aerosols and trace gases; 3) Measurement techniques for aerosol particles; 4) Long-term and field campaigns; 5) Aerosol-cloud-climate-biosphere interactions; 6) Air quality

Major main research areas: 1) Aerosol-cloud interactions, 2) Development of mass spectrometric methods for atmospheric aerosols and trace gases; 3) Measurement techniques for aerosol particles; 4) Long-term and field campaigns; 5) Aerosol-cloud-climate-biosphere interactions; 6) Air quality

With more than 30 years of experience in the measurement of aerosol particles and particularly in airborne measurement of climate relevant aerosol optical properties across the troposphere in various environments, atmospheric research is my scientific home. Today, I am heading the Research Group for Global Observation at the Institute of Energy and Climate Research – Troposphere (IEK-8) of Forschungszentrum Jülich. I am also Professor for Atmospheric Physics at the University of Wuppertal and serve as a member of the Scientific Advisory Group Aerosols of the Global Atmosphere Watch programme of WMO. One of my primary tasks is the coordination of the European Research Infrastructure IAGOS (www.iagos.org), jointly with colleagues from France and the U.K. As a convinced supporter of the concept of research infrastructures, I am contributing to the Community of the European Environmental Research Infrastructures ENVRI and coordinated the EU Project ENVRI-FAIR (www.envri-fair.eu) which connects the cluster of ENVRIs to the European Open Science Cloud.

With more than 30 years of experience in the measurement of aerosol particles and particularly in airborne measurement of climate relevant aerosol optical properties across the troposphere in various environments, atmospheric research is my scientific home. Today, I am heading the Research Group for Global Observation at the Institute of Energy and Climate Research – Troposphere (IEK-8) of Forschungszentrum Jülich. I am also Professor for Atmospheric Physics at the University of Wuppertal and serve as a member of the Scientific Advisory Group Aerosols of the Global Atmosphere Watch programme of WMO. One of my primary tasks is the coordination of the European Research Infrastructure IAGOS (www.iagos.org), jointly with colleagues from France and the U.K. As a convinced supporter of the concept of research infrastructures, I am contributing to the Community of the European Environmental Research Infrastructures ENVRI and coordinated the EU Project ENVRI-FAIR (www.envri-fair.eu) which connects the cluster of ENVRIs to the European Open Science Cloud.

+49-(0)2461-61 5795

Dr. Eva Pfannerstill's research areas include biosphere-atmosphere interactions, the impact of climate change on biogenic and anthropogenic organic emissions, and the effect of volatile organic compounds (VOCs) on air pollutant formation. She is an expert in mass spectrometric VOC and OH reactivity measurements, as well as in airborne flux observations of VOCs.

Dr. Eva Pfannerstill's research areas include biosphere-atmosphere interactions, the impact of climate change on biogenic and anthropogenic organic emissions, and the effect of volatile organic compounds (VOCs) on air pollutant formation. She is an expert in mass spectrometric VOC and OH reactivity measurements, as well as in airborne flux observations of VOCs.

Dr. Pitts’ research is focused on analysis and interpretation of aerosol and cloud remote sensing data sets that are critical for assessing key climate change issues. Over the past two decades, he has made significant contributions to polar stratospheric cloud (PSC) research, including studies of their formation, distribution, and evolution. Other areas of research include the impact of volcanic eruptions on stratospheric aerosol levels, the transport of aerosols and constituents in the vicinity of the polar vortex, and state-of-the-art retrieval approaches for remote sensing of temperature and gas species.

Dr. Pitts’ research is focused on analysis and interpretation of aerosol and cloud remote sensing data sets that are critical for assessing key climate change issues. Over the past two decades, he has made significant contributions to polar stratospheric cloud (PSC) research, including studies of their formation, distribution, and evolution. Other areas of research include the impact of volcanic eruptions on stratospheric aerosol levels, the transport of aerosols and constituents in the vicinity of the polar vortex, and state-of-the-art retrieval approaches for remote sensing of temperature and gas species.

John Plane obtained his BA degree in 1979 and PhD in 1984 at the University of Cambridge. He was a Research Fellow at St. John’s College, Cambridge, between 1982 and 1985, before moving to the University of Miami, Florida, where he was an Assistant and then Associate Professor at the Rosenstiel School of Marine and Atmospheric Science. In 1991 he moved to the School of Environmental Sciences at the University of East Anglia (UK), being made Professor of Environmental Science in 1999. In 2006 he moved to his present position as Professor of Atmospheric Chemistry at the University of Leeds. Aeronomy and atmospheric chemistry. The mesosphere and lower thermosphere region of the Earth’s atmosphere: sources of cosmic dust, meteoric ablation, meteoric metal layers, ion chemistry, meteoric smoke formation, polar mesospheric clouds, energetic particle precipitation, the coupling of chemistry with tides and gravity waves, long-term changes including the impact of very long-lived greenhouse gases. Chemistry of the troposphere: the oxidizing capacity of nitrate and halogen oxide radicals, air-sea exchange of halogen species, new particle production in the marine boundary layer. Kinetics and photochemistry. Experimental and theoretical studies of neutral and ion-molecule reactions in the gas phase, uptake on ice surfaces. Use of laser flash photolysis and fast flow tube techniques, reactions of metallic species over extreme temperature ranges; detection of radical species by time-resolved laser induced fluorescence, cavity ring-down, and photo-ionization time-of-flight spectroscopy. Ab initio quantum calculations of molecular properties and reaction potential energy surfaces; reaction rate theories. Differential optical absorption spectroscopy techniques. Lidar and satellite observations of the upper atmosphere. Planetary and interstellar chemistry. Impacts of cosmic dust in the atmospheres of the terrestrial planets and Titan; production of dust in stellar outflows.

John Plane obtained his BA degree in 1979 and PhD in 1984 at the University of Cambridge. He was a Research Fellow at St. John’s College, Cambridge, between 1982 and 1985, before moving to the University of Miami, Florida, where he was an Assistant and then Associate Professor at the Rosenstiel School of Marine and Atmospheric Science. In 1991 he moved to the School of Environmental Sciences at the University of East Anglia (UK), being made Professor of Environmental Science in 1999. In 2006 he moved to his present position as Professor of Atmospheric Chemistry at the University of Leeds. Aeronomy and atmospheric chemistry. The mesosphere and lower thermosphere region of the Earth’s atmosphere: sources of cosmic dust, meteoric ablation, meteoric metal layers, ion chemistry, meteoric smoke formation, polar mesospheric clouds, energetic particle precipitation, the coupling of chemistry with tides and gravity waves, long-term changes including the impact of very long-lived greenhouse gases. Chemistry of the troposphere: the oxidizing capacity of nitrate and halogen oxide radicals, air-sea exchange of halogen species, new particle production in the marine boundary layer. Kinetics and photochemistry. Experimental and theoretical studies of neutral and ion-molecule reactions in the gas phase, uptake on ice surfaces. Use of laser flash photolysis and fast flow tube techniques, reactions of metallic species over extreme temperature ranges; detection of radical species by time-resolved laser induced fluorescence, cavity ring-down, and photo-ionization time-of-flight spectroscopy. Ab initio quantum calculations of molecular properties and reaction potential energy surfaces; reaction rate theories. Differential optical absorption spectroscopy techniques. Lidar and satellite observations of the upper atmosphere. Planetary and interstellar chemistry. Impacts of cosmic dust in the atmospheres of the terrestrial planets and Titan; production of dust in stellar outflows.

44 113 3438044

+49 6131 305 4600

Regional and global climate modeling Aerosol-climate interaction Snow and glacier impurities and climatic impact Land-atmosphere-water interactions Human impact on climate (Irrigation, urbanization, wildfire) Coastal environment modeling Uncertainty Quantification in climate modeling

Regional and global climate modeling Aerosol-climate interaction Snow and glacier impurities and climatic impact Land-atmosphere-water interactions Human impact on climate (Irrigation, urbanization, wildfire) Coastal environment modeling Uncertainty Quantification in climate modeling

+49-341-9732852

Xavier Querol Carceller (Morella, Spain, 1963), research Professor at the Institute of Environmental Assessment and Water Research (IDAEA) from the Spanish Research Council (CSIC). His research focuses on environmental geochemistry applied to air pollution. PhD on Geology by the University of Barcelona, he did the postdoc at British Geological Survey (BGS) del Natural Environment Research Council (NERC), UK; later on, he joined the Institute of Earth Sciences “Jaume Almera” from CSIC; and since 2008 in the IDAEA. He has led numerous research projects, such as RI-URBASNs (https://riurbans.eu/), AIRUSE (http://airuse.eu/) and CAIAC (https://www.idaea.csic.es/egar/portfolio-items/caiac/). During his carrier he has supervised 29 PhD students and has co-authored around 700 articles (WoS, https://www.webofscience.com/wos/author/record/1845612). His work has received 42,300 citation to his publications (WoS) and reaches an ih=104 WoS, and since 2014 (year of the fist list) his is in the Thomson and Reuters/Clarivate list of highly cited scientific authors (excluding 2017). In the last decade, he has been member of working groups assessing Clean Air for Europe from DG ENV, member of WHO-Scientific Assessing Committee of REVIHAAP and HRAPIE. Currently, assessing on air quality to the Spanish Ministry of Ecological Transition and several cities and regions of Spain, Vice chair of EMEP-UNECE, member of the IPCC working group on short-lived greenhouse pollutants; member of TAG Working groups of WHO on air quality. Environment Award of the Generalitat de Catalunya 2009. King Jaume I Award 2013 for the Protection of the Environment. National Research Award on Natural Resources in 2020, Cady Award, Geological Society of America, Energy Geology Division in 2021, Member of the Royal Academy of Sciences and Arts of Barcelona since 2019.

Xavier Querol Carceller (Morella, Spain, 1963), research Professor at the Institute of Environmental Assessment and Water Research (IDAEA) from the Spanish Research Council (CSIC). His research focuses on environmental geochemistry applied to air pollution. PhD on Geology by the University of Barcelona, he did the postdoc at British Geological Survey (BGS) del Natural Environment Research Council (NERC), UK; later on, he joined the Institute of Earth Sciences “Jaume Almera” from CSIC; and since 2008 in the IDAEA. He has led numerous research projects, such as RI-URBASNs (https://riurbans.eu/), AIRUSE (http://airuse.eu/) and CAIAC (https://www.idaea.csic.es/egar/portfolio-items/caiac/). During his carrier he has supervised 29 PhD students and has co-authored around 700 articles (WoS, https://www.webofscience.com/wos/author/record/1845612). His work has received 42,300 citation to his publications (WoS) and reaches an ih=104 WoS, and since 2014 (year of the fist list) his is in the Thomson and Reuters/Clarivate list of highly cited scientific authors (excluding 2017). In the last decade, he has been member of working groups assessing Clean Air for Europe from DG ENV, member of WHO-Scientific Assessing Committee of REVIHAAP and HRAPIE. Currently, assessing on air quality to the Spanish Ministry of Ecological Transition and several cities and regions of Spain, Vice chair of EMEP-UNECE, member of the IPCC working group on short-lived greenhouse pollutants; member of TAG Working groups of WHO on air quality. Environment Award of the Generalitat de Catalunya 2009. King Jaume I Award 2013 for the Protection of the Environment. National Research Award on Natural Resources in 2020, Cady Award, Geological Society of America, Energy Geology Division in 2021, Member of the Royal Academy of Sciences and Arts of Barcelona since 2019.

+34-(0)93-4095410

+49-(0)421-21862103

Lynn M. Russell is Professor of Climate, Atmospheric Science & Physical Oceanography at Scripps Institution of Oceanography on the faculty of University of California at San Diego, where she has led the Climate Sciences Curricular Group since 2009. Her research focuses on the processes that control atmospheric aerosols and their cloud interactions. Her work uses both modeling and measurement studies of atmospheric particles and their chemical composition. Her recent work has studied marine aerosols, flux and entrainment in the marine boundary layer, terrestrial biogenic particles, combustion emissions, and feedbacks between climate and particle sources. She completed undergraduate degrees at Stanford University, and she received her Ph.D. in Chemical Engineering from the California Institute of Technology for her studies of marine aerosols. Her postdoctoral work as part of the National Center for Atmospheric Research Advanced Studies Program investigated aerosol and trace gas flux and entrainment in the marine boundary layer. She served on the faculty of Princeton University in the Department of Chemical Engineering before accepting her current position at Scripps in 2003. She has been honored with young investigator awards from ONR, NASA, Dreyfus Foundation, NSF, and the James S. McDonnell Foundation, and she received the Kenneth T. Whitby Award from AAAR (2003) for her contributions on atmospheric aerosol processes. In 2013 she received the UCSD Sustainability Outstanding Faculty Award. She was named a Fellow of the American Association for Aerosol Research in 2013 and of the American Geophysical Union in 2017.

Lynn M. Russell is Professor of Climate, Atmospheric Science & Physical Oceanography at Scripps Institution of Oceanography on the faculty of University of California at San Diego, where she has led the Climate Sciences Curricular Group since 2009. Her research focuses on the processes that control atmospheric aerosols and their cloud interactions. Her work uses both modeling and measurement studies of atmospheric particles and their chemical composition. Her recent work has studied marine aerosols, flux and entrainment in the marine boundary layer, terrestrial biogenic particles, combustion emissions, and feedbacks between climate and particle sources. She completed undergraduate degrees at Stanford University, and she received her Ph.D. in Chemical Engineering from the California Institute of Technology for her studies of marine aerosols. Her postdoctoral work as part of the National Center for Atmospheric Research Advanced Studies Program investigated aerosol and trace gas flux and entrainment in the marine boundary layer. She served on the faculty of Princeton University in the Department of Chemical Engineering before accepting her current position at Scripps in 2003. She has been honored with young investigator awards from ONR, NASA, Dreyfus Foundation, NSF, and the James S. McDonnell Foundation, and she received the Kenneth T. Whitby Award from AAAR (2003) for her contributions on atmospheric aerosol processes. In 2013 she received the UCSD Sustainability Outstanding Faculty Award. She was named a Fellow of the American Association for Aerosol Research in 2013 and of the American Geophysical Union in 2017.

Harald Saathoff leads the Aerosol Chemistry and Air Quality Group at the Institute of Meteorology and Climate Research at the Karlsruhe Institute of Technology, Germany. He recieved his PhD in Physical-Chemistry in 1993 from the University of Göttingen with a focus on gas-phase reaction kinetics and optical spectroscopy. His studies on atmospheric aerosols include simulation chamber experiments covering a wide temperature range as well as field studies in urban, rural (forest), and remote (mountain) locations.

Harald Saathoff leads the Aerosol Chemistry and Air Quality Group at the Institute of Meteorology and Climate Research at the Karlsruhe Institute of Technology, Germany. He recieved his PhD in Physical-Chemistry in 1993 from the University of Göttingen with a focus on gas-phase reaction kinetics and optical spectroscopy. His studies on atmospheric aerosols include simulation chamber experiments covering a wide temperature range as well as field studies in urban, rural (forest), and remote (mountain) locations.

I lead the Gravity Wave Research Group at the Faculty of Mathematics and Physics, Charles University. We study internal gravity waves effects on atmospheric dynamics and transport and their parameterization in models. Using a synergy of theory, observations, existing data mining and experiments with a a hierarchy of numerical models (spanning from idealized to gravity wave resolving and chemistry-climate models) we want to revisit and advance our understanding of the climate impacts of gravity waves and improve their representation in the models.

I lead the Gravity Wave Research Group at the Faculty of Mathematics and Physics, Charles University. We study internal gravity waves effects on atmospheric dynamics and transport and their parameterization in models. Using a synergy of theory, observations, existing data mining and experiments with a a hierarchy of numerical models (spanning from idealized to gravity wave resolving and chemistry-climate models) we want to revisit and advance our understanding of the climate impacts of gravity waves and improve their representation in the models.

Dr. Pablo Saide is an Assistant Professor at the Department of Atmospheric & Oceanic Sciences and in the Institute of the Environment and Sustainability at the University of California, Los Angeles (UCLA). He is originally from Chile, where he got his Bachelor and Master degrees in Mechanical Engineering. In the US he obtained his Ph.D. in Civil and Environmental Engineering at the University of Iowa. Prof. Saide’s expertise focuses on air quality models and forecasts, emission inversions and data assimilation using satellite retrievals, and assessments of aerosol-climate interactions in models. His recent research has had a strong focus on studying smoke from fires and its impacts.

Dr. Pablo Saide is an Assistant Professor at the Department of Atmospheric & Oceanic Sciences and in the Institute of the Environment and Sustainability at the University of California, Los Angeles (UCLA). He is originally from Chile, where he got his Bachelor and Master degrees in Mechanical Engineering. In the US he obtained his Ph.D. in Civil and Environmental Engineering at the University of Iowa. Prof. Saide’s expertise focuses on air quality models and forecasts, emission inversions and data assimilation using satellite retrievals, and assessments of aerosol-climate interactions in models. His recent research has had a strong focus on studying smoke from fires and its impacts.

Imre 's scientific interests cover most aspects of atmospheric aerosol research, implications on climate, human health, and built environment, especially studies on urban-type aerosol. He leads the Budapest platform for Aerosol Research and Training (BpART) Laboratory of the Eötvös Loránd University.

Imre 's scientific interests cover most aspects of atmospheric aerosol research, implications on climate, human health, and built environment, especially studies on urban-type aerosol. He leads the Budapest platform for Aerosol Research and Training (BpART) Laboratory of the Eötvös Loránd University.

My research focus is on trends and distributions of greenhouse gases in the atmosphere. I am particularlarly interested in long-range transport of trace gases, their distributions near the surface and in the UTLS, and the South Asian Monsoon. I do measuremnts of long-lived greenhouse gases and halogenated short-lived species on different measurement platformes fom the ground into the stratosphere. With a sophisticated air sampling device I contribute to the operation of the IAGOS-CARIBIC research infrastructure.

My research focus is on trends and distributions of greenhouse gases in the atmosphere. I am particularlarly interested in long-range transport of trace gases, their distributions near the surface and in the UTLS, and the South Asian Monsoon. I do measuremnts of long-lived greenhouse gases and halogenated short-lived species on different measurement platformes fom the ground into the stratosphere. With a sophisticated air sampling device I contribute to the operation of the IAGOS-CARIBIC research infrastructure.

+496979840249

I investigate the properties and multiphase processes of aerosols and their effects on atmospheric chemistry, air quality and human health. My group currently focuses on the multiphase chemistry of organic aerosol particles and reactive oxygen species.

I investigate the properties and multiphase processes of aerosols and their effects on atmospheric chemistry, air quality and human health. My group currently focuses on the multiphase chemistry of organic aerosol particles and reactive oxygen species.

949-824-2738

Dr. Manish Shrivastava is currently a senior Earth Systems Scientist at the Pacific Northwest National Laboratory (PNNL). His research bridges measurements and modeling of secondary organic aerosols (SOA), and their interactions with clouds, radiative forcing and human health. Over the past decade, he has developed and implemented several new model formulations of SOA within community regional and global models based on laboratory and field measurements. In 2018, he was awarded the highly prestigious and competitive U.S. Department of Energy Early Career Award to conduct research on finding missing links associated with aerosol-cloud interactions.

Dr. Manish Shrivastava is currently a senior Earth Systems Scientist at the Pacific Northwest National Laboratory (PNNL). His research bridges measurements and modeling of secondary organic aerosols (SOA), and their interactions with clouds, radiative forcing and human health. Over the past decade, he has developed and implemented several new model formulations of SOA within community regional and global models based on laboratory and field measurements. In 2018, he was awarded the highly prestigious and competitive U.S. Department of Energy Early Career Award to conduct research on finding missing links associated with aerosol-cloud interactions.

5093716792

+82-62-970-3276

Odran Sourdeval is an Associate Professor in Atmospheric Sciences at University of Lille. His research interests lie in the understanding of cloud processes, aerosol-cloud interactions (aci) and their radiative effects, via the combined use of remote-sensing, modelling and in-situ observations. He is an expert in the development and evaluation of novel satellite retrieval schemes, in particular for model evaluation and aci studies. Notably, he has long contributed to operating a shift from a traditional view on retrieval products (e.g. particle radius and cloud optical depth) to quantities more useful for these studies. All datasets that Odran developed were made publicly available and his work remains closely linked to developments for future spatial missions. His current research focuses on improving observation-based estimates of the effective radiative forcing due to aci for liquid but also ice clouds, by better constraining current uncertainties on key cloud parameters such as the number concentration in cloud particles. Odran has currently published 37 papers related to these research topics. Highly involved in scientific outreach, Odran is a board member of the Early Career Scientists committee of the International Association of Meteorology and Atmospheric Sciences (IAMAS) and of the International Commission for Clouds and Precipitation (ICCP). He is an editor for Atmospheric Chemistry and Physics (ACP) and a regular convener at international conferences, such as at the European Geosciences Union (EGU). Odran also is an academic coordinator for the M.Sc. in Atmospheric Sciences at University of Lille.

Odran Sourdeval is an Associate Professor in Atmospheric Sciences at University of Lille. His research interests lie in the understanding of cloud processes, aerosol-cloud interactions (aci) and their radiative effects, via the combined use of remote-sensing, modelling and in-situ observations. He is an expert in the development and evaluation of novel satellite retrieval schemes, in particular for model evaluation and aci studies. Notably, he has long contributed to operating a shift from a traditional view on retrieval products (e.g. particle radius and cloud optical depth) to quantities more useful for these studies. All datasets that Odran developed were made publicly available and his work remains closely linked to developments for future spatial missions. His current research focuses on improving observation-based estimates of the effective radiative forcing due to aci for liquid but also ice clouds, by better constraining current uncertainties on key cloud parameters such as the number concentration in cloud particles. Odran has currently published 37 papers related to these research topics. Highly involved in scientific outreach, Odran is a board member of the Early Career Scientists committee of the International Association of Meteorology and Atmospheric Sciences (IAMAS) and of the International Commission for Clouds and Precipitation (ICCP). He is an editor for Atmospheric Chemistry and Physics (ACP) and a regular convener at international conferences, such as at the European Geosciences Union (EGU). Odran also is an academic coordinator for the M.Sc. in Atmospheric Sciences at University of Lille.

+33 32043 4311

Dr. Gabriele Stiller is an expert for remote sensing of the atmospheric composition. Her scientific interest covers the physics and chemistry of the atmosphere from the upper troposphere to the mesopause. In the last years she has been working on the analysis of the mean meridional circulation of the stratosphere and mesosphere, ozone recovery and water vapour trends in the UTLS, and transport from the troposphere into the stratosphere. She leads the 'Satellite-borne remote sensing of trace gases' group at Karlsruhe Institute of Technology, Institute of Meteorology and Climate Research - Atmospheric Trace Gases and Remote Sensing (KIT/IMK-ASF).

Dr. Gabriele Stiller is an expert for remote sensing of the atmospheric composition. Her scientific interest covers the physics and chemistry of the atmosphere from the upper troposphere to the mesopause. In the last years she has been working on the analysis of the mean meridional circulation of the stratosphere and mesosphere, ozone recovery and water vapour trends in the UTLS, and transport from the troposphere into the stratosphere. She leads the 'Satellite-borne remote sensing of trace gases' group at Karlsruhe Institute of Technology, Institute of Meteorology and Climate Research - Atmospheric Trace Gases and Remote Sensing (KIT/IMK-ASF).

Dr. Jason Surratt is a Full Professor (with tenure) of Environmental Sciences & Engineering and Chemistry at the University of North Carolina (UNC) at Chapel Hill. He continues to examine atmospheric multiphase chemistry leading to fine organic aerosols. Since 2018, he has chemically characterized PFAS in NC fine aerosols, and is developing real-time CIMS methods to measure gas-phase PFAS in both outdoor and indoor air. He received the 2021 Kenneth T. Whitby Award from the American Association for Aerosol Research, and has authored over 180 peer-reviewed publications. He received his Ph.D. in chemistry from Caltech in 2010 under the supervision of John H. Seinfeld.

Dr. Jason Surratt is a Full Professor (with tenure) of Environmental Sciences & Engineering and Chemistry at the University of North Carolina (UNC) at Chapel Hill. He continues to examine atmospheric multiphase chemistry leading to fine organic aerosols. Since 2018, he has chemically characterized PFAS in NC fine aerosols, and is developing real-time CIMS methods to measure gas-phase PFAS in both outdoor and indoor air. He received the 2021 Kenneth T. Whitby Award from the American Association for Aerosol Research, and has authored over 180 peer-reviewed publications. He received his Ph.D. in chemistry from Caltech in 2010 under the supervision of John H. Seinfeld.

919 966 0470

I am an Associate Professor in the Earth and Environmental Sciences Programme of the Faculty of Science at The Chinese University of Hong Kong (CUHK), serving concurrently as the Associate Director of the Office of University General Education. I obtained my B.Sc. from MIT, Ph.D. (Environmental Science and Engineering) from Harvard, and was a Croucher Postdoctoral Fellow at MIT before joining CUHK in 2013. My research focuses on atmospheric chemistry and physics, ecoclimatology, and sustainable agriculture and forestry, combining Earth system modeling and data analytics to address pressing issues such as the impacts of air pollution and climate change on ecosystems and agriculture, and how land and food systems can be transformed to mitigate climate change and air pollution. My work has been published in top-ranking journals in the atmospheric and environmental sciences and earned me the World Meteorological Organization (WMO) Research Award for Young Scientists, Research Grants Council Early Career Award, Faculty of Science Young Researcher Award, and founding membership of the Hong Kong Young Academy of Sciences.

I am an Associate Professor in the Earth and Environmental Sciences Programme of the Faculty of Science at The Chinese University of Hong Kong (CUHK), serving concurrently as the Associate Director of the Office of University General Education. I obtained my B.Sc. from MIT, Ph.D. (Environmental Science and Engineering) from Harvard, and was a Croucher Postdoctoral Fellow at MIT before joining CUHK in 2013. My research focuses on atmospheric chemistry and physics, ecoclimatology, and sustainable agriculture and forestry, combining Earth system modeling and data analytics to address pressing issues such as the impacts of air pollution and climate change on ecosystems and agriculture, and how land and food systems can be transformed to mitigate climate change and air pollution. My work has been published in top-ranking journals in the atmospheric and environmental sciences and earned me the World Meteorological Organization (WMO) Research Award for Young Scientists, Research Grants Council Early Career Award, Faculty of Science Young Researcher Award, and founding membership of the Hong Kong Young Academy of Sciences.

Toshihiko Takemura is a professor in the Section of Climate Change Science at the Research Institute for Applied Mechanics, Kyushu University. He is the primary developer of the aerosol climate model SPRINTARS, which has been incorporated into an atmospheric general circulation model, a global cloud-resolving model, and a regional model. He was the lead author of the Fifth Assessment Report of the Intergovernmental Panel on Climate Change and is a recipient of the Japan Academy Medal.

Toshihiko Takemura is a professor in the Section of Climate Change Science at the Research Institute for Applied Mechanics, Kyushu University. He is the primary developer of the aerosol climate model SPRINTARS, which has been incorporated into an atmospheric general circulation model, a global cloud-resolving model, and a regional model. He was the lead author of the Fifth Assessment Report of the Intergovernmental Panel on Climate Change and is a recipient of the Japan Academy Medal.

Dr. Ivy Tan's research centres on better understanding the role of clouds and their microphysical processes in climate and climate change, primarily using remote sensing observations and large-scale climate models. She is particularly interested in polar processes and radiative feedbacks.

Dr. Ivy Tan's research centres on better understanding the role of clouds and their microphysical processes in climate and climate change, primarily using remote sensing observations and large-scale climate models. She is particularly interested in polar processes and radiative feedbacks.

+1 (514) 399-9032

+49 (0)341 97 36660

Dr. Simone Tilmes is a Project Scientist II at National Center for Atmospheric Research (NCAR) and the liaison for the Community Earth System Model (CESM) chemistry-climate working group. Her scientific interests cover the understanding and evaluation of chemical, aerosol and dynamical processes in chemistry-climate models. She has investigated past, present and future evolution of the ozone hole in both hemispheres based on models and observations. Her recent work also focuses on tropospheric chemistry, aerosols, air quality, long-range transport of pollutants, and of tropospheric ozone. She further studies the impact of geoengineering on the Earth’s climate system, the hydrological cycle, and the impact of solar radiation management on dynamics and chemistry in both troposphere and stratosphere. She published more than 100 peer reviewed papers.

Dr. Simone Tilmes is a Project Scientist II at National Center for Atmospheric Research (NCAR) and the liaison for the Community Earth System Model (CESM) chemistry-climate working group. Her scientific interests cover the understanding and evaluation of chemical, aerosol and dynamical processes in chemistry-climate models. She has investigated past, present and future evolution of the ozone hole in both hemispheres based on models and observations. Her recent work also focuses on tropospheric chemistry, aerosols, air quality, long-range transport of pollutants, and of tropospheric ozone. She further studies the impact of geoengineering on the Earth’s climate system, the hydrological cycle, and the impact of solar radiation management on dynamics and chemistry in both troposphere and stratosphere. She published more than 100 peer reviewed papers.

Professor Michael Tjernström has 35 years of research experience and is an expert on Arctic meteorology and climate with ~150 published peer-reviewed papers. He earned his BSc in Meteorology at Stockholm University 1980, and served as a Forecast Officer in the Swedish Air Force while commencing graduate studies in 1983. He got his PhD at Uppsala University 1988, became Senior Lecturer in 1994 and Professor in 2000. Appointed as a Senior Scientist with the Swedish Natural Research Council, he moved to Stockholm University in 1998 and was installed Professor in 2001. Involved in Arctic research since early 2000’s, he has led projects on five research expeditions on the Swedish research icebreaker Oden to study central Arctic meteorology, two as Chief Scientist (ASCOS in summer 2008 and ARTofMELT in spring 2023). He has been visiting scientist at California Institute of Technology in Pasadena and Naval Research Laboratory in Monterey, both in California, and at National Centre for Atmospheric Research, and as a Visiting Fellow at the Cooperative Institute of the Environmental Sciences in Boulder, Colorado. He held leading roles in the Swedish regional climate-modeling program SWECLIM, the Bolin Centre for Climate Research, the International Study of Arctic Change, was a member of European Centre for Medium Range Weather Forecasts’ Science Advisory Committee and represented Sweden in te International Arctic Science Committee Working Groups.

Professor Michael Tjernström has 35 years of research experience and is an expert on Arctic meteorology and climate with ~150 published peer-reviewed papers. He earned his BSc in Meteorology at Stockholm University 1980, and served as a Forecast Officer in the Swedish Air Force while commencing graduate studies in 1983. He got his PhD at Uppsala University 1988, became Senior Lecturer in 1994 and Professor in 2000. Appointed as a Senior Scientist with the Swedish Natural Research Council, he moved to Stockholm University in 1998 and was installed Professor in 2001. Involved in Arctic research since early 2000’s, he has led projects on five research expeditions on the Swedish research icebreaker Oden to study central Arctic meteorology, two as Chief Scientist (ASCOS in summer 2008 and ARTofMELT in spring 2023). He has been visiting scientist at California Institute of Technology in Pasadena and Naval Research Laboratory in Monterey, both in California, and at National Centre for Atmospheric Research, and as a Visiting Fellow at the Cooperative Institute of the Environmental Sciences in Boulder, Colorado. He held leading roles in the Swedish regional climate-modeling program SWECLIM, the Bolin Centre for Climate Research, the International Study of Arctic Change, was a member of European Centre for Medium Range Weather Forecasts’ Science Advisory Committee and represented Sweden in te International Arctic Science Committee Working Groups.

My research focuses on stratospheric aerosols and their impact on the Earth’s climate. My work investigates the physical processes of aerosol formation and evolution, interactions between aerosols and radiation, and the changes the aerosols produce in atmospheric circulation and surface temperatures. My team uses a hierarchy of computational models which represent physical processes on a range of scales and timescales, as well as observations and proxy data.

My research focuses on stratospheric aerosols and their impact on the Earth’s climate. My work investigates the physical processes of aerosol formation and evolution, interactions between aerosols and radiation, and the changes the aerosols produce in atmospheric circulation and surface temperatures. My team uses a hierarchy of computational models which represent physical processes on a range of scales and timescales, as well as observations and proxy data.

+1 212 6785668

+32-(0)2-3730416

Marc is a senior researcher at the Institute of Energy and Climate Research (IEK-7 – Stratosphere) at Forschungszentrum Jülich in Germany. He develops in-situ trace gas sensors and deploys them in the field mainly during airborne campaigns. His research interests include polar stratospheric ozone depletion, stratospheric aerosol, the sulfur cycle, and vertical transport in the Asian Monsoon.

Marc is a senior researcher at the Institute of Energy and Climate Research (IEK-7 – Stratosphere) at Forschungszentrum Jülich in Germany. He develops in-situ trace gas sensors and deploys them in the field mainly during airborne campaigns. His research interests include polar stratospheric ozone depletion, stratospheric aerosol, the sulfur cycle, and vertical transport in the Asian Monsoon.

+49-2461-614620

Wang has wide-ranging expertise in process and climate modeling and extensive experience in studying atmospheric aerosols, cloud physics, aerosol-cloud-precipitation interactions (ACPI), air-sea interactions, radiative feedbacks, and high-latitude climate variability and impacts. Wang performs process-level modeling of air-sea interactions, ACPI and their impacts on radiation budget and climate using the Weather Research and Forecasting (WRF) model, and transforms the process-level understanding into better treatments of aerosols, clouds, precipitation and climate processes in Earth system models, including the Community Earth System Model (CESM) and the Energy Exascale Earth System Model (E3SM).

Wang has wide-ranging expertise in process and climate modeling and extensive experience in studying atmospheric aerosols, cloud physics, aerosol-cloud-precipitation interactions (ACPI), air-sea interactions, radiative feedbacks, and high-latitude climate variability and impacts. Wang performs process-level modeling of air-sea interactions, ACPI and their impacts on radiation budget and climate using the Weather Research and Forecasting (WRF) model, and transforms the process-level understanding into better treatments of aerosols, clouds, precipitation and climate processes in Earth system models, including the Community Earth System Model (CESM) and the Energy Exascale Earth System Model (E3SM).

+852 27666059

Yuan Wang is an assistant professor in the Department of Earth System Science at the Stanford Doerr School of Sustainability. He is also an affiliated faculty in the Woods Institute for the Environment. His research group aims to advance the understanding of the physical and chemical interactions between atmospheric constituents and climate change. Specifically, his group conducts research related to aerosol-cloud-precipitation interactions and their climatic implications, air pollution and haze formation, cloud microphysics and dynamics, and the assessment of the greenhouse gas and aerosol forcings on the atmosphere, ocean, and cryosphere. They develop and use multiscale Earth system models and machine learning methods in combination with space-borne and in situ measurements to address those scientific questions.

Yuan Wang is an assistant professor in the Department of Earth System Science at the Stanford Doerr School of Sustainability. He is also an affiliated faculty in the Woods Institute for the Environment. His research group aims to advance the understanding of the physical and chemical interactions between atmospheric constituents and climate change. Specifically, his group conducts research related to aerosol-cloud-precipitation interactions and their climatic implications, air pollution and haze formation, cloud microphysics and dynamics, and the assessment of the greenhouse gas and aerosol forcings on the atmosphere, ocean, and cryosphere. They develop and use multiscale Earth system models and machine learning methods in combination with space-borne and in situ measurements to address those scientific questions.

I lead the Climate Analytics Lab (CAL) where we focus on understanding the interactions between aerosols and clouds, and their representation within global climate models. CAL is leading the development of a variety of machine learning tools and techniques to alleviate these difficulties and optimally combine a variety of observational datasets, including global satellite and aircraft measurements, to constrain and improve these models.

I lead the Climate Analytics Lab (CAL) where we focus on understanding the interactions between aerosols and clouds, and their representation within global climate models. CAL is leading the development of a variety of machine learning tools and techniques to alleviate these difficulties and optimally combine a variety of observational datasets, including global satellite and aircraft measurements, to constrain and improve these models.

Heini's research focuses on the dynamics of extratropical weather systems, in particular the role of diabatic processes for the structure and evolution of extratropical cyclones. His research group uses reanalysis data, numerical model simulations, and sophisticated diagnostics, in particular the Lagrangian analysis tool LAGRANTO, to study the dynamics of a broad variety of meteorological flow systems.

Heini's research focuses on the dynamics of extratropical weather systems, in particular the role of diabatic processes for the structure and evolution of extratropical cyclones. His research group uses reanalysis data, numerical model simulations, and sophisticated diagnostics, in particular the Lagrangian analysis tool LAGRANTO, to study the dynamics of a broad variety of meteorological flow systems.

+41-(0)44-6325480

+1-(0)919-8433928

Lisa’s research interest involves atmospheric measurements, modelling studies and laboratory experiments relating to the short-lived radical species OH, HO2 and RO2. She is experienced in using the detailed Master Chemical Mechanism (MCM) to predict radical concentrations for comparison with observations to better understand the chemistry controlling their concentrations in different environments. Her research focusses on understanding the chemistry driving secondary pollutant formation such as ozone as well as understanding the chemistry impacting OH concentrations in remote regions which can impact methane lifetimes. Her research is supported by the National Centre for Atmospheric Science (NCAS)

Lisa’s research interest involves atmospheric measurements, modelling studies and laboratory experiments relating to the short-lived radical species OH, HO2 and RO2. She is experienced in using the detailed Master Chemical Mechanism (MCM) to predict radical concentrations for comparison with observations to better understand the chemistry controlling their concentrations in different environments. Her research focusses on understanding the chemistry driving secondary pollutant formation such as ozone as well as understanding the chemistry impacting OH concentrations in remote regions which can impact methane lifetimes. Her research is supported by the National Centre for Atmospheric Science (NCAS)

Chris' research usually focuses on improving estimates of surface fluxes of greenhouse gases. Chris employs data assimilation and inverse modelling methods, together with chemical transport models of the atmosphere, in order to better understand natural and anthropogenic emissions of methane, carbon dioxide, nitrous oxide and carbon monoxide. Chris' research therefore extends to cover the biosphere, including plant ecosystems, wetlands and fires.

Chris' research usually focuses on improving estimates of surface fluxes of greenhouse gases. Chris employs data assimilation and inverse modelling methods, together with chemical transport models of the atmosphere, in order to better understand natural and anthropogenic emissions of methane, carbon dioxide, nitrous oxide and carbon monoxide. Chris' research therefore extends to cover the biosphere, including plant ecosystems, wetlands and fires.

My research career has been in weather and climate modeling, climate model diagnosis and validation, atmospheric physics developments, cloud processes research, and observational analysis and uncertainty quantification.

My research career has been in weather and climate modeling, climate model diagnosis and validation, atmospheric physics developments, cloud processes research, and observational analysis and uncertainty quantification.

Fangqun’s research focuses on the development and application of nucleation and advanced particle microphysics (APM) models, the regional and global simulations of size-resolved particle microphysical processes, aerosol-cloud-precipitation interactions, contrail formation and climate implications associated with aviation, health effects of ultrafine particles and co-pollutants, usage of machine learning methods to improve aerosol representation in 3-D models, and the climatic and environmental impacts of atmospheric particles.

Fangqun’s research focuses on the development and application of nucleation and advanced particle microphysics (APM) models, the regional and global simulations of size-resolved particle microphysical processes, aerosol-cloud-precipitation interactions, contrail formation and climate implications associated with aviation, health effects of ultrafine particles and co-pollutants, usage of machine learning methods to improve aerosol representation in 3-D models, and the climatic and environmental impacts of atmospheric particles.

+1-(0)518-437-8767

Leiming's research focuses on air-quality modeling and data analysis of multiple pollutants, covering topics of air-surface exchange, atmospheric emission and deposition, atmospheric mercury cycling, long-term trends, source apportionment, cloud microphysics, and atmospheric aerosol chemical and optical properties.

Leiming's research focuses on air-quality modeling and data analysis of multiple pollutants, covering topics of air-surface exchange, atmospheric emission and deposition, atmospheric mercury cycling, long-term trends, source apportionment, cloud microphysics, and atmospheric aerosol chemical and optical properties.

Zhonghua's research interests include environmental data science, urban climate and environment, and air quality and aerosol properties.

Zhonghua's research interests include environmental data science, urban climate and environment, and air quality and aerosol properties.