Atmospheric Measurement Techniques (Jan 2012)

The ACOS CO<sub>2</sub> retrieval algorithm – Part 1: Description and validation against synthetic observations

  • T. Taylor,
  • M. Smyth,
  • I. Polonsky,
  • F. Oyafuso,
  • V. Natraj,
  • C. E. Miller,
  • J. McDuffie,
  • M. Gunson,
  • B. Fisher,
  • D. Eldering,
  • M. Christi,
  • R. Castano,
  • C. Frankenberg,
  • D. O'Brien,
  • H. Bösch,
  • B. Connor,
  • C. W. O'Dell,
  • G. C. Toon,
  • P. O. Wennberg,
  • D. Wunch

DOI
https://doi.org/10.5194/amt-5-99-2012
Journal volume & issue
Vol. 5, no. 1
pp. 99 – 121

Abstract

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This work describes the NASA Atmospheric CO2 Observations from Space (ACOS) XCO2 retrieval algorithm, and its performance on highly realistic, simulated observations. These tests, restricted to observations over land, are used to evaluate retrieval errors in the face of realistic clouds and aerosols, polarized non-Lambertian surfaces, imperfect meteorology, and uncorrelated instrument noise. We find that post-retrieval filters are essential to eliminate the poorest retrievals, which arise primarily due to imperfect cloud screening. The remaining retrievals have RMS errors of approximately 1 ppm. Modeled instrument noise, based on the Greenhouse Gases Observing SATellite (GOSAT) in-flight performance, accounts for less than half the total error in these retrievals. A small fraction of unfiltered clouds, particularly thin cirrus, lead to a small positive bias of ~0.3 ppm. Overall, systematic errors due to imperfect characterization of clouds and aerosols dominate the error budget, while errors due to other simplifying assumptions, in particular those related to the prior meteorological fields, appear small.