Variations in constituents such as ozone and aerosols affect air quality, weather, and climate. Atmospheric composition is central to Earth system dynamics because the atmosphere integrates spatially varying surface emissions globally on time scales from weeks to years. NASA works to provide monitoring and evaluation tools to assess the effects of climate change on ozone recovery and future atmospheric composition, improved climate forecasts based on the understanding of the forcings of global environmental change, and air quality modeling that take into account the relationship between regional air quality and global climate change. Achievements in these areas via advances in observations, data assimilation, and modeling enable improved predictive capabilities for describing how future changes in atmospheric composition affect air quality, weather, and climate. NASA draws on global observations from space, augmented by suborbital and ground-based measurements to address these issues.
Atmospheric Composition addresses the following overarching questions:
- How is atmospheric composition changing?
- What trends in atmospheric composition and solar radiation influence global climate?
- How does atmospheric composition respond to and affect global environmental change?
- What are the effects of global atmospheric composition and climate changes on regional air quality?
- How will future changes in atmospheric composition affect ozone, climate, and global air quality?
Upper Atmosphere Research Program (UARP)
The Upper Atmosphere Research Program (UARP) concentrates on observations to study processes that control ozone concentrations in the upper troposphere and stratosphere, and therefore surface ultraviolet radiation. The program funds laboratory studies, ground-based network observations, and field campaigns that contribute to quantifying scientific understanding of ozone changes. These activities complement the observations from and data analysis using the NASA EOS Aura satellite as well as other satellites that observe the upper troposphere and stratosphere. Typical laboratory studies include kinetics studies of key reactions that either directly or indirectly destroy and create ozone or the precursors to ozone destroying compounds, as well as spectroscopic studies required to accurately monitor the key atmospheric constituents. Typical field studies include airborne in situ and remote sensing instrumentation for focused aircraft field campaigns, high altitude balloon remote sensing and in situ observations, and long-term ground-based in situ and remote sensing programs [such as Advanced Global Atmospheric Gases Experiment (AGAGE) and Network for the Detection of Atmospheric Composition Change (NDACC)]. The WMO/UNEP quadrennial assessments on ozone depletion, as mandated by the Montreal Protocol, rely heavily on many of these observations, and investigators in this and other NASA atmospheric composition programs contribute heavily to these assessments.
Tropospheric Composition Program (TCP)
The Tropospheric Composition Program (TCP) seeks to improve the utility of satellite measurements in understanding of global tropospheric ozone and aerosols, including their precursors and transformation processes in the atmosphere. Ozone and aerosols are fundamental to both air quality and climate. The program emphasizes suborbital and ground-based measurements acquired during focused field deployments. Along with the other Atmospheric Composition programs, TCP also sponsors interpretation of these comprehensive but infrequent measurements to improve the continuous monitoring of tropospheric ozone and aerosols from space and the improvement of prognostic models. TCP also supports limited laboratory studies that are directly relevant to improved understanding of tropospheric chemistry.
Radiation Sciences Program (RSP)
The Radiation Sciences Program (RSP) strives to develop a quantitative and predictive understanding of how aerosols, clouds, and radiatively active gases scatter and absorb radiation (including both solar and terrestrially originated radiation) in the Earth’s atmosphere, especially as it relates to climate variability and change. The program supports studies to improve the theoretical understanding of radiative transfer as well as field measurements of aerosol and cloud particle concentration, composition, microphysics, and optical properties. These measurements include both airborne and surface-based remote and in situ measurements. The program also supports the analysis of satellite remote sensing and field data as well as the development of process models, which contribute to an Earth system modeling capability.
Atmospheric Composition Modeling and Analysis Program (ACMAP)
The Atmospheric Composition Modeling and Analysis Program (ACMAP) supports studies of air quality and oxidation efficiency in the troposphere, how pollution-sourced aerosols affect cloud properties, stratospheric chemistry and ozone depletion, and interactions between atmospheric chemistry and climate. Studies of long-term trends in atmospheric composition are also of interest, where the connection between cause and effect is elucidated using models. The program is particularly interested in studies that integrate observations from multiple instruments with models to address attribution and predictions. Use of satellite and suborbital data sets and ground-based measurements are encouraged for modeling constraints and verification where applicable.
Guiding and Planning
Atmospheric Composition Research Priorities Workshop
- Outstanding Questions in Atmospheric Composition, Chemistry, Dynamics and Radiation for the Coming Decade, May 2014
Responding to the Challenge of Climate and Environmental Change
- NASA's Plan for a Climate-Centric Architecture for Earth Observations and Applications from Space, June 2010
Associated Earth Science Division Missions, Instruments, and Data Sets
The table below lists all Earth missions that are relevant to the Atmospheric Composition Focus Area in all phases. Learn more about the mission phases: operating, under development, under study, and past.
|CERES FM5 (on Suomi NPP)|
|OMPS (on Suomi NPP)|
|CERES FM6 (on JPSS-1)|
|RBI (on JPSS-2)|
|Suborbital Investigations: Aircraft Missions||CAMP2Ex|
|SAGE III Meteop-3M|
|CATS (on ISS)|
|Suborbital Investigations: Aircraft Missions||SEAC4RS|
For solicited program elements relevant to Atmospheric Composition, search for and view open, closed, and future Research Opportunities in Space and Earth Sciences (ROSES) NASA Research Announcements (NRAs) on the NASA Solicitation and Proposal Integrated Review and Evaluation System (NSPIRES) website.
- Atmospheric Science Data Center (SDC DAAC) at NASA Langley Research Center
- Goddard Earth Sciences Atmospheric Composition Data and Information Services Center
Topics relevant to Atmospheric Composition are also being pursued through the following:
NASA Applied Sciences Programs
NASA Center Organizations
- Goddard Space Flight Center Atmospheric Sciences Program
- Goddard Institute for Space Studies
- Langley Science Directorate
- Ames Earth Science Division
- Marshall Global Hydrology and Climate Center
- Jet Propulsion Laboratory Earth Atmospheric Sciences Section
- CEOS Atmospheric Composition Constellation
- Group on Earth Observations
- U.S. Global Change Research Program
- SPARC Chemistry-Climate Model Initiative (CCMI) Working Group
- IGAC Chemistry-Climate Model Initiative (CCMI) Working Group
Hal Maring, Radiation Sciences Program
Ken Jucks, Upper Atmosphere Research Program
Barry Lefer, Tropospheric Composition Program
Richard Eckman, Atmospheric Composition Modeling and Analysis Program
Felix Seidel, Atmospheric Composition Programs