Clouds and the Earth's Radiant Energy System

From Wikipedia, the free encyclopedia
Artist representation of CERES instruments scanning Earth in Rotating Azimuth Plane mode.

Clouds and the Earth's Radiant Energy System (CERES) is an on-going NASA climatological experiment from Earth orbit.[1][2] The CERES are scientific satellite instruments, part of the NASA's Earth Observing System (EOS), designed to measure both solar-reflected and Earth-emitted radiation from the top of the atmosphere (TOA) to the Earth's surface. Cloud properties are determined using simultaneous measurements by other EOS instruments such as the Moderate Resolution Imaging Spectroradiometer (MODIS).[3] Results from the CERES and other NASA missions, such as the Earth Radiation Budget Experiment (ERBE),[4] could enable nearer to real-time tracking of Earth's energy imbalance (EEI) and better understanding of the role of clouds in global climate change.[1][5]

Incoming, top-of-atmosphere (TOA) shortwave flux radiation, shows energy received from the sun (Jan 26–27, 2012).
Outgoing, longwave flux radiation at the top-of-atmosphere (Jan 26–27, 2012). Heat energy radiated from Earth (in watts per square meter) is shown in shades of yellow, red, blue and white. The brightest-yellow areas are the hottest and are emitting the most energy out to space, while the dark blue areas and the bright white clouds are much colder, emitting the least energy.
Cumulative planetary heat content anomaly of Earth since year 2000 as observed by CERES

Scientific goals[edit]

CERES experiment has four main objectives:

  • Continuation of the ERBE record of radiative fluxes at the top of the atmosphere (TOA) for climate change analysis.
  • Doubling the accuracy of estimates of radiative fluxes at TOA and the Earth's surface.
  • Provide the first long-term global estimates of the radiative fluxes within the Earth's atmosphere.
  • Provide cloud property estimates that are consistent with the radiative fluxes from surface to TOA.

Each CERES instrument is a radiometer which has three channels – a shortwave (SW) channel to measure reflected sunlight in 0.2–5 µm region, a channel to measure Earth-emitted thermal radiation in the 8–12 µm "window" or "WN" region, and a Total channel to measure entire spectrum of outgoing Earth's radiation (>0.2 µm). The CERES instrument was based on the successful Earth Radiation Budget Experiment which used three satellites to provide global energy budget measurements from 1984 to 1993.[6]

Missions[edit]

First launch[edit]

The first CERES instrument Proto-Flight Module (PFM) was launched aboard the NASA Tropical Rainfall Measuring Mission (TRMM) in November 1997 from Japan. However, this instrument failed to operate after 8 months due to an on-board circuit failure.

CERES on the EOS and JPSS mission satellites[edit]

An additional six CERES instruments were launched on the Earth Observing System and the Joint Polar Satellite System. The Terra satellite, launched in December 1999, carried two (Flight Module 1 (FM1) and FM2) and the Aqua satellite, launched in May 2002, carried two more (FM3 and FM4). A fifth instrument (FM5) was launched on the Suomi NPP satellite in October 2011 and a sixth (FM6) on NOAA-20 in November 2017. With the failure of the PFM on TRMM and the 2005 loss of the SW channel of FM4 on Aqua, there are five of the CERES Flight Modules that are fully operational as of 2017.[7][8]

Radiation Budget Instruments[edit]

The measurements of the CERES instruments was to be furthered by the Radiation Budget Instrument (RBI) to be launched on Joint Polar Satellite System-2 (JPSS-2) in 2021, JPSS-3 in 2026, and JPSS-4 in 2031.[8] The project was cancelled on January 26, 2018; NASA cited technical, cost, and schedule issues and the impact of anticipated RBI cost growth on other programs.[9]

Libera[edit]

NASA announced in February 2020 its selection of the Libera instrument to launch on JPSS-3 by the end of 2027.[10] Libera is planned to provide data continuity and updated capabilities. LASP is the lead instrument developer.[11]

Operating modes[edit]

CERES operates in three scanning modes: across the satellite ground track (cross-track), along the direction of the satellite ground track (along-track), and in a Rotating Azimuth Plane (RAP). In RAP mode, the radiometers scan in elevation as they rotate in azimuth, thus acquiring radiance measurement from a wide range of viewing angles. Until February 2005, on Terra and Aqua satellites one of CERES instruments scanned in cross-track mode while the other was in RAP or along-track mode. The instrument operating in RAP scanning mode took two days of along-track data every month. However the multi-angular CERES data allowed to derive new models which account for anisotropy of the viewed scene, and allow TOA radiative flux retrieval with enhanced precision.[12]

All CERES instruments are in Sun-synchronous orbit. Comparable geostationary data between 60°S and 60°N are also applied within "balanced and filled" data products to provide a diurnally complete representation of the radiation budget and to account for cloud changes between CERES observation times.[13]

Calibration methods[edit]

The CERES instruments were designed to provide enhanced measurement stability and precision, however achieving and ensuring absolute accuracy over time was also known to remain as an ongoing challenge.[14] Despite the more advanced capability of CERES to monitor Earth's TOA radiative fluxes globally and with relative accuracy, the only practical way to estimate the absolute magnitude of EEI (as of year 2020) is through an inventory of the changes of energy in the climate system.[15] Consequently, an important constraint within CERES data products has been the anchoring of EEI at one point in time to a value which corresponds to several years of ARGO data.[13]

Ground absolute calibration[edit]

For a climate data record (CDR) mission like CERES, accuracy is of high importance and achieved for pure infrared nighttime measurements by use of a ground laboratory SI traceable blackbody to determine total and WN channel radiometric gains. This however was not the case for CERES solar channels such as SW and solar portion of the Total telescope, which have no direct un-broken chain to SI traceability. This is because CERES solar responses were measured on ground using lamps whose output energy were estimated by a cryo-cavity reference detector, which used a silver Cassegrain telescope identical to CERES devices to match the satellite instrument field of view. The reflectivity of this telescope built and used since the mid-1990s was never actually measured, estimated[16] only based on witness samples (see slide 9 of Priestley et al. (2014)[17]). Such difficulties in ground calibration, combined with suspected on-ground contamination events[18] have resulted in the need to make unexplained ground to flight changes in SW detector gains as big as 8%,[19] simply to make the ERB data seem somewhat reasonable to climate science (note that CERES currently claims[14] a one sigma SW absolute accuracy of 0.9%).

In-flight calibration[edit]

CERES spatial resolution at nadir view (equivalent diameter of the footprint) is 10 km for CERES on TRMM, and 20 km for CERES on Terra and Aqua satellites. Perhaps of greater importance for missions such as CERES is calibration stability, or the ability to track and partition instrumental changes from Earth data so it tracks true climate change with confidence. CERES onboard calibration sources intended to achieve this for channels measuring reflected sunlight include solar diffusers and tungsten lamps. However the lamps have very little output in the important ultraviolet wavelength region where degradation is greatest and they have been seen to drift in energy by over 1.4% in ground tests, without a capability to monitor them on-orbit (Priestley et al. (2001)[20]). The solar diffusers have also degraded greatly in orbit such that they have been declared unusable by Priestley et al. (2011).[21] A pair of black body cavities that can be controlled at different temperatures are used for the Total and WN channels, but these have not been proved stable to better than 0.5%/decade.[18] Cold space observations and internal calibration are performed during normal Earth scans.

Intercalibration[edit]

Data is compared between CERES instruments on different mission satellites, as well as compared to scan reference data from accompanying spectroradiometers (e.g. MODIS on Aqua). The planned CLARREO Pathfinder mission aims to provide a state-of-the-art reference standard for several existing EOS instruments including CERES.[14]

A study of annual changes to Earth's energy imbalance (EEI) spanning 2005-2019 showed good agreement between the CERES observation and EEI inferred from in-situ measurements of ocean heat uptake by the Argo float network.[22]

See also[edit]

References[edit]

  1. ^ a b B. A. Wielicki; Harrison, Edwin F.; Cess, Robert D.; King, Michael D.; Randall, David A.; et al. (1995). "Mission to Planet Earth: Role of Clouds and Radiation in Climate". Bull. Am. Meteorol. Soc. 76 (11): 2125–2152. Bibcode:1995BAMS...76.2125W. doi:10.1175/1520-0477(1995)076<2125:MTPERO>2.0.CO;2.
  2. ^ Wielicki; et al. (1996). "Clouds and the Earth's Radiant Energy System (CERES): An Earth Observing System Experiment". Bulletin of the American Meteorological Society. 77 (5): 853–868. Bibcode:1996BAMS...77..853W. doi:10.1175/1520-0477(1996)077<0853:CATERE>2.0.CO;2.
  3. ^ P. Minnis; et al. (September 2003). "CERES Cloud Property Retrievals from Imager on TRMM, Terra and Aqua" (PDF). Proceedings of SPIE 10th International Symposium on Remote Sensing. Conference on Remote Sensing of Clouds and the Atmosphere VII. Spain. pp. 37–48.
  4. ^ Barkstrom, Bruce R. (1984). "The Earth Radiation Budget Experiment". Bulletin of the American Meteorological Society. 65 (11): 1170–1186. Bibcode:1984BAMS...65.1170B. doi:10.1175/1520-0477(1984)065<1170:TERBE>2.0.CO;2.
  5. ^ "Surface and Atmospheric Remote Sensing: Technologies, Data Analysis and Interpretation., International". Geoscience and Remote Sensing Symposium IGARSS '94. 1994.
  6. ^ NASA, Clouds and the Earth's Radiant Energy System (CERES) (accessed Sept. 9, 2014)
  7. ^ "Joint Polar Satellite System - Launch Schedule". www.jpss.noaa.gov. Archived from the original on 19 January 2017. Retrieved 23 January 2017.
  8. ^ a b "Joint Polar Satellite System: Mission and Instruments". NASA. Retrieved 14 November 2017.
  9. ^ "NASA Cancels Earth Science Sensor Set for 2021 Launch". NASA.gov. 2018-01-26. Retrieved 28 January 2018.
  10. ^ "NASA Selects New Instrument to Continue Key Climate Record". NASA. 26 February 2020. Retrieved 19 October 2023.
  11. ^ Daniel Strain (27 February 2020). "$130 million space mission to monitor Earth's energy budget". CU Boulder. Retrieved 19 October 2023.
  12. ^ Loeb, N. G.; Kato, Seiji; Loukachine, Konstantin; Manalo-Smith, Natividad; et al. (2005). "Angular distribution models for top-of-atmosphere radiative flux estimation from the Clouds and the Earth's Radiant Energy System instrument on the Terra Satellite. Part I: Methodology". Journal of Atmospheric and Oceanic Technology. 22 (4): 338–351. Bibcode:2005JAtOT..22..338L. doi:10.1175/JTECH1712.1.
  13. ^ a b Loeb, Norman G.; Doelling, David R.; Hailan, Wang; Su, Wenling; et al. (15 January 2018). "Clouds and the Earth's Radiant Energy System (CERES) Energy Balanced and Filled (EBAF) Top-of-Atmosphere (TOA) Edition-4.0 Data Product". Journal of Climate. 31 (2): 895–918. Bibcode:2018JCli...31..895L. doi:10.1175/JCLI-D-17-0208.1.
  14. ^ a b c Wielicki, Bruce A.; Young, D. F.; Mlynczak, M. G.; Thome, K. J.; Leroy, S.; et al. (1 October 2013). "Achieving Climate Change Absolute Accuracy in Orbit". Bulletin of the American Meteorological Society. 94 (10): 1519–1539. Bibcode:2013BAMS...94.1519W. doi:10.1175/BAMS-D-12-00149.1.
  15. ^ Trenberth, Kevin E; Cheng, Lijing (2022-09-01). "A perspective on climate change from Earth's energy imbalance". Environmental Research: Climate. 1 (1): 013001. doi:10.1088/2752-5295/ac6f74. ISSN 2752-5295.
  16. ^ M. Folkman et al., "Calibration of a shortwave reference standard by transfer from a blackbody standard using a cryogenic active cavity radiometer", IEEE Geoscience and Remote Sensing Symposium, pp. 2298–2300, 1994.
  17. ^ Priestley, Kory; et al. (August 5, 2014). "CERES CALCON Talk".
  18. ^ a b Matthews (2009). "In-Flight Spectral Characterization and Calibration Stability Estimates for the Clouds and the Earth's Radiant Energy System (CERES)". Journal of Atmospheric and Oceanic Technology. 28 (1): 3. Bibcode:2011JAtOT..28....3P. doi:10.1175/2010JTECHA1521.1.
  19. ^ Priestley, Kory (July 1, 2002). "CERES Gain Changes". Archived from the original on December 12, 2016. Retrieved December 8, 2017.
  20. ^ Priestley; et al. (2001). "Postlaunch Radiometric Validation of the Clouds and the Earth's Radiant Energy System (CERES) Proto-Flight Model on the Tropical Rainfall Measuring Mission (TRMM) Spacecraft through 1999". Journal of Applied Meteorology. 39 (12): 2249. Bibcode:2000JApMe..39.2249P. doi:10.1175/1520-0450(2001)040<2249:PRVOTC>2.0.CO;2.
  21. ^ Priestley; et al. (2011). "Radiometric Performance of the CERES Earth Radiation Budget Climate Record Sensors on the EOS Aqua and Terra Spacecraft through April 2007". Journal of Atmospheric and Oceanic Technology. 28 (1): 3. Bibcode:2011JAtOT..28....3P. doi:10.1175/2010JTECHA1521.1.
  22. ^ Loeb, Norman G.; Johnson, Gregory C.; Thorsen, Tyler J.; Lyman, John M.; et al. (15 June 2021). "Satellite and Ocean Data Reveal Marked Increase in Earth's Heating Rate". Geophysical Research Letters. 48 (13). Bibcode:2021GeoRL..4893047L. doi:10.1029/2021GL093047.

External links[edit]