CLARREO
The CLARREO (Climate Absolute Radiance and Refractivity Observatory) was selected as a high priority NASA decadal survey mission by the National Research Council in 2007.[1] The CLARREO mission is intended to provide a metrology laboratory in orbit to accurately quantify and attribute Earth's climate change (see List of climate research satellites). If launched at the earliest opportunity,[2] CLARREO's observations could be used to detect the largest of climate trends above natural variability by the year 2039.[3] Then it may go on to further test, validate, and improve prediction by climate models. The mission also might provide the first orbiting radiometers with enough accuracy to serve as reference calibration standards that can fine-tune other spaceborne sensors and climate research,[4] making climate trends apparent in their data sets within a 30-year time frame.
When the mission was scaled back in 2012 due to cuts in funding, the CLARREO science team turned their focus to instrument studies that would further enhance the mission’s key climate measurements and develop the new concepts to meet the specified accuracy standards.[5]
In the President's FY16 budget request, CLARREO was provided $76.9M to demonstrate essential measurement technologies of the CLARREO Tier 1 Decadal Survey mission. That funding will potentially support the flight of two instruments, Reflected Solar (RS) and Infrared (IR) spectrometers, hosted on the International Space Station in FY 2019.[6]
The mission concept
CLARREO is currently in an extended planning phase or "Pre-Phase A," where the mission and science teams are funded to continue advancing the science of CLARREO, explore alternative implementation strategies, and reduce technical risk.[7]
Below is the mission concept presented at the Mission Concept Review in November 2010.[8] CLARREO was then envisioned to consist of four observatories on two dual-manifested launches on Minotaur IV+ vehicles.
- Three Instruments (two of each)
- Infrared (IR) Spectrometer
- Reflected Solar (RS) Spectrometer
- Global Navigation Satellite System-Radio Occultation (GNSS-RO)
- Four Observatories, two dual-manifested launches on Minotaur IV+ vehicles
- July 2018: Two infrared observatories, each with GNSS-RO
- May 2020: Two reflected solar observatories
- 609 km polar orbits (90 degree inclination)
Now due to reduced funding, the International Space Station (ISS) is being investigated as a possible platform, but due to the ISS orbital inclination of 51.65 degrees this negates the possibility of global climate change monitoring by CLARREO.
The science behind CLARREO
CLARREO could make highly accurate decadal change observations that are traceable to International Systems of Units (SI) standards. At solar wavelengths this is intended to be confirmed after launch using comparison of actual data to theoretical simulations of lunar/solar radiance generated within a hi fidelity sensor model.[9] The Earth observations then made by CLARREO have sensitivity to the most critical but least understood climate radiative forcings, responses, and feedbacks, such as:
- Infrared spectra to infer temperature and water vapor feedbacks, cloud feedbacks, and decadal change of temperature profiles, water vapor profiles, clouds, and greenhouse gas radiative effects
- GNSS-RO to infer decadal change of temperature profiles
- Solar reflected spectra to infer cloud feedbacks, snow/ice albedo feedbacks, and decadal change of clouds, radiative fluxes, aerosols, snow cover, sea ice, and land use[10]
Reference intercalibration
Current satellite-based sensors are not designed to meet the accuracy requirements of CLARREO. Many sensors used for climate measurements were designed to meet operational weather needs and are not optimized for climate sampling. These sensors, along with older instruments designed for climate, lack the on-board ability to test for systematic errors on orbit. The CLARREO mission will meet these goals through careful consideration of the instrument design, calibration traceability at all stages of development and operation, with spectral, spatial and temporal sampling focused specifically on the creation of climate records. Then after development of new cross-calibration methodologies far more accurate than those achieved today,[12] CLARREO may serve as an in-orbit standard to provide reference intercalibration for missions like the broadband Clouds and the Earth's Radiant Energy System (CERES), operational sounders including the Cross-track Infrared Sounder (CrIS) and Infrared Atmospheric Sounding Interferometer (IASI), and imagers such as the Visible Infrared Imaging Radiometer Suite (VIIRS) and Advanced Very High Resolution Radiometer (AVHRR).[13]
CLARREO selection
The 2007 National Research Council (NRC) Decadal Survey report,[1] "Earth Science and Applications from Space: National Imperatives for the Next Decade and Beyond," provides the basis for the future direction of NASA’s space-based Earth observation system. Missions were ranked according to scientific merit, contributions to long-term observational records, societal benefits, affordability, and technological readiness. The four missions recommended for earliest implementation by NASA were classified as “Tier 1” missions and included CLARREO. The NRC Decadal Survey concluded that the single most critical issue for current climate change observations was their lack of accuracy and low confidence in observing the small climate change signals over decade time scales. CLARREO observations of climate change on decadal scales address this issue by achieving the required levels of accuracy and traceability to SI standards for a set of observations sensitive to a wide range of key climate change observations.
Decadal Survey recommendations represent the community's input on the future direction of space-based Earth science; therefore, NASA will continue to engage the scientific community to refine mission requirements during the planning for CLARREO.
The CLARREO team
CLARREO was originally recommended as a joint NASA/NOAA mission[14] where NOAA would contribute the total and spectral solar irradiance measurements and the Earth energy budget climate data records by flying the Total Solar Irradiance Sensor (TSIS) and the Clouds and the Earth’s Radiant Energy System (CERES) sensors. The NASA portion involved the measurement of spectrally resolved thermal IR and reflected solar radiation at high absolute accuracy. However, recent events have put such allocations in question.[15]
A NASA team led by Langley Research Center with contributions from other NASA Centers, government organizations, academia, and NASA HQ, developed a mission concept that passed its Mission Concept Review (MCR) on November 17, 2010.[16] The team’s successful completion of this suggested CLARREO might proceed into Phase A and then begin to prove its new design concepts, however, proceeding onto Phase A has been delayed.[17]
Societal benefits of an improved climate observing system
Due to natural variability and a launch date at least 25 years after that of other missions, the CLARREO team predicts that it will not provide the data necessary for decisions on public policy concerning climate change until several years after say the existing CERES observing system (first launched in 1997, Fig. 3). They have however also calculated that if better informed decisions could by some means be justified and made around 15–20 years prior to arrival of useful CERES or CLARREO results, it would provide a large economic benefit to the United States and the world (estimated to be about 12 Trillion dollars at 3% discount rate over the next 40–60 years[18]). Reduction of climate prediction uncertainties impacts civil Government and military planning (i.e., Navy bases), disaster mitigation, response, and recovery (i.e., insurance industry), and U.S. international policy decisions.
References
- 1 2 National Research Council, Earth Science and Applications from Space: National Imperatives for the Next Decade and Beyond. National Academies Press, Washington, D.C., 426pp, 2007.
- ↑ Wielicki, Bruce; Baize, Rosemary (November 16, 2012). "SDT Meeting Intro/Goals" (PDF).
- ↑ Wielicki et al., "Achieving Climate Change Absolute Accuracy," Bull. Amer. Meteor. Soc., 1829 pp. 1519–1539, 2013.
- ↑ N. Fox et al., "Accurate radiometry from space: an essential tool for climate studies," Phil. Trans. R. Soc. A., 369 pp. 4028–4063, 2011.
- ↑ LaRC, Denise Lineberry : (June 6, 2013). "Budget issues delay Earth science mission".
- ↑ "FY 2016 President's Budget Request Summary" (PDF). www.nasa.gov.
- ↑ http://www.spacenews.com/civil/110225-climate-missions-nasa-budget.html
- ↑ CLARREO Science Definition Team (January 21, 2011). "CLARREO Mission Overview 2011" (PDF). Retrieved July 18, 2012.
- ↑ http://clarreo.larc.nasa.gov/2014-10STM/Tuesday/Thome_rs_cds_summary_oct2014.pdf
- ↑ http://clarreo.larc.nasa.gov/pdf/CLARREO_Extended_Pre-Phase_A_Study_Plan_V9.2_no_budget.pdf
- ↑ C. M. Roithmayr et al., "Opportunities to Intercalibrate Radiometric Sensors from International Space Station," J. Atmos. Oceanic Technol., 31, 890–902, 2014.
- ↑ M. Goldberg et al., "The Global Space-Based Inter-Calibration System". Bull. Amer. Meteor. Soc., 92, 467–475., 2011.
- ↑ http://clarreo.larc.nasa.gov/docs/CLARREO_Mission_Overview_Jan%202011.pdf
- ↑ http://spacenews.com/civil/nasa-langley-research-center-selected-lead-clarreo-mission.html[]
- ↑ "NASA Satellite Crash Complicates Gloomy Climate Budget Picture". March 9, 2011.
- ↑ Finneran, Michael (November 23, 2010). "CLARREO Passes First Big Test". Langley Research Center.
- ↑ "Two High-priority Climate Missions Dropped from NASA's Budget Plans - SpaceNews.com". February 25, 2011.
- ↑ R. Cooke, B.A. Wielicki, D.F. Young, M. Mlynczak, "Value of Information for Climate Observing Systems," Environ. Syst. Decis., 12 pp., 201, DOI 10.1007/s10669-013-9451-8.
External links
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- http://clarreo.larc.nasa.gov/index.php/
- http://science.nasa.gov/missions/clarreo/
- http://clarreo.larc.nasa.gov/docs/CLARREO_Data_from_Decadal_Survey.pdf