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Bruce A. Wielicki
,
D. F. Young
,
M. G. Mlynczak
,
K. J. Thome
,
S. Leroy
,
J. Corliss
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J. G. Anderson
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C. O. Ao
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R. Bantges
,
F. Best
,
K. Bowman
,
H. Brindley
,
J. J. Butler
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W. Collins
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J. A. Dykema
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D. R. Doelling
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D. R. Feldman
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N. Fox
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X. Huang
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R. Holz
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Y. Huang
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Z. Jin
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D. Jennings
,
D. G. Johnson
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K. Jucks
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S. Kato
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D. B. Kirk-Davidoff
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R. Knuteson
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G. Kopp
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D. P. Kratz
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X. Liu
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C. Lukashin
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A. J. Mannucci
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N. Phojanamongkolkij
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P. Pilewskie
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V. Ramaswamy
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H. Revercomb
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J. Rice
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Y. Roberts
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C. M. Roithmayr
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F. Rose
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S. Sandford
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E. L. Shirley
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Sr. W. L. Smith
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B. Soden
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P. W. Speth
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W. Sun
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P. C. Taylor
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D. Tobin
, and
X. Xiong

The Climate Absolute Radiance and Refractivity Observatory (CLARREO) mission will provide a calibration laboratory in orbit for the purpose of accurately measuring and attributing climate change. CLARREO measurements establish new climate change benchmarks with high absolute radiometric accuracy and high statistical confidence across a wide range of essential climate variables. CLARREO's inherently high absolute accuracy will be verified and traceable on orbit to Système Internationale (SI) units. The benchmarks established by CLARREO will be critical for assessing changes in the Earth system and climate model predictive capabilities for decades into the future as society works to meet the challenge of optimizing strategies for mitigating and adapting to climate change. The CLARREO benchmarks are derived from measurements of the Earth's thermal infrared spectrum (5–50 μm), the spectrum of solar radiation reflected by the Earth and its atmosphere (320–2300 nm), and radio occultation refractivity from which accurate temperature profiles are derived. The mission has the ability to provide new spectral fingerprints of climate change, as well as to provide the first orbiting radiometer with accuracy sufficient to serve as the reference transfer standard for other space sensors, in essence serving as a “NIST [National Institute of Standards and Technology] in orbit.” CLARREO will greatly improve the accuracy and relevance of a wide range of space-borne instruments for decadal climate change. Finally, CLARREO has developed new metrics and methods for determining the accuracy requirements of climate observations for a wide range of climate variables and uncertainty sources. These methods should be useful for improving our understanding of observing requirements for most climate change observations.

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Andrew M. Vogelmann
,
Greg M. McFarquhar
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John A. Ogren
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David D. Turner
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Jennifer M. Comstock
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Graham Feingold
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Charles N. Long
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Haflidi H. Jonsson
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Anthony Bucholtz
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Don R. Collins
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Glenn S. Diskin
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Hermann Gerber
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R. Paul Lawson
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Roy K. Woods
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Elisabeth Andrews
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Hee-Jung Yang
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J. Christine Chiu
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Daniel Hartsock
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John M. Hubbe
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Chaomei Lo
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Alexander Marshak
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Justin W. Monroe
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Sally A. McFarlane
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Beat Schmid
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Jason M. Tomlinson
, and
Tami Toto

A first-of-a-kind, extended-term cloud aircraft campaign was conducted to obtain an in situ statistical characterization of continental boundary layer clouds needed to investigate cloud processes and refine retrieval algorithms. Coordinated by the Atmospheric Radiation Measurement (ARM) Aerial Facility (AAF), the Routine AAF Clouds with Low Optical Water Depths (CLOWD) Optical Radiative Observations (RACORO) field campaign operated over the ARM Southern Great Plains (SGP) site from 22 January to 30 June 2009, collecting 260 h of data during 59 research flights. A comprehensive payload aboard the Center for Interdisciplinary Remotely-Piloted Aircraft Studies (CIRPAS) Twin Otter aircraft measured cloud microphysics, solar and thermal radiation, physical aerosol properties, and atmospheric state parameters. Proximity to the SGP's extensive complement of surface measurements provides ancillary data that support modeling studies and facilitates evaluation of a variety of surface retrieval algorithms. The five-month duration enabled sampling a range of conditions associated with the seasonal transition from winter to summer. Although about twothirds of the flights during which clouds were sampled occurred in May and June, boundary layer cloud fields were sampled under a variety of environmental and aerosol conditions, with about 77% of the cloud flights occurring in cumulus and stratocumulus. Preliminary analyses illustrate use of these data to analyze aerosol– cloud relationships, characterize the horizontal variability of cloud radiative impacts, and evaluate surface-based retrievals. We discuss how an extended-term campaign requires a simplified operating paradigm that is different from that used for typical, short-term, intensive aircraft field programs.

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Gregory C. Johnson
,
Rick Lumpkin
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Simone R. Alin
,
Dillon J. Amaya
,
Molly O. Baringer
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Tim Boyer
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Peter Brandt
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Brendan R. Carter
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Ivona Cetinić
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Don P. Chambers
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Lijing Cheng
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Andrew U. Collins
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Cathy Cosca
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Ricardo Domingues
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Shenfu Dong
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Richard A. Feely
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Eleanor Frajka-Williams
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Bryan A. Franz
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John Gilson
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Gustavo Goni
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Benjamin D. Hamlington
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Josefine Herrford
,
Zeng-Zhen Hu
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Boyin Huang
,
Masayoshi Ishii
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Svetlana Jevrejeva
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John J. Kennedy
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Marion Kersalé
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Rachel E. Killick
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Peter Landschützer
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Matthias Lankhorst
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Eric Leuliette
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Ricardo Locarnini
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John M. Lyman
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John J. Marra
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Christopher S. Meinen
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Mark A. Merrifield
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Gary T. Mitchum
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Ben I. Moat
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R. Steven Nerem
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Renellys C. Perez
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Sarah G. Purkey
,
James Reagan
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Alejandra Sanchez-Franks
,
Hillary A. Scannell
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Claudia Schmid
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Joel P. Scott
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David A. Siegel
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David A. Smeed
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Paul W. Stackhouse
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William Sweet
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Philip R. Thompson
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Joaquin A. Triñanes
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Denis L. Volkov
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Rik Wanninkhof
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Robert A. Weller
,
Caihong Wen
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Toby K. Westberry
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Matthew J. Widlansky
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Anne C. Wilber
,
Lisan Yu
, and
Huai-Min Zhang
Free access
Rolf H. Reichle
,
Gabrielle J. M. De Lannoy
,
Qing Liu
,
Joseph V. Ardizzone
,
Andreas Colliander
,
Austin Conaty
,
Wade Crow
,
Thomas J. Jackson
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Lucas A. Jones
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John S. Kimball
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Randal D. Koster
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Sarith P. Mahanama
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Edmond B. Smith
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Aaron Berg
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Simone Bircher
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David Bosch
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Todd G. Caldwell
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Michael Cosh
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Ángel González-Zamora
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Chandra D. Holifield Collins
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Karsten H. Jensen
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Stan Livingston
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Ernesto Lopez-Baeza
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José Martínez-Fernández
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Heather McNairn
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Mahta Moghaddam
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Anna Pacheco
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Thierry Pellarin
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John Prueger
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Tracy Rowlandson
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Mark Seyfried
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Patrick Starks
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Zhongbo Su
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Marc Thibeault
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Rogier van der Velde
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Jeffrey Walker
,
Xiaoling Wu
, and
Yijian Zeng

Abstract

The Soil Moisture Active Passive (SMAP) mission Level-4 Surface and Root-Zone Soil Moisture (L4_SM) data product is generated by assimilating SMAP L-band brightness temperature observations into the NASA Catchment land surface model. The L4_SM product is available from 31 March 2015 to present (within 3 days from real time) and provides 3-hourly, global, 9-km resolution estimates of surface (0–5 cm) and root-zone (0–100 cm) soil moisture and land surface conditions. This study presents an overview of the L4_SM algorithm, validation approach, and product assessment versus in situ measurements. Core validation sites provide spatially averaged surface (root zone) soil moisture measurements for 43 (17) “reference pixels” at 9- and 36-km gridcell scales located in 17 (7) distinct watersheds. Sparse networks provide point-scale measurements of surface (root zone) soil moisture at 406 (311) locations. Core validation site results indicate that the L4_SM product meets its soil moisture accuracy requirement, specified as an unbiased RMSE (ubRMSE, or standard deviation of the error) of 0.04 m3 m−3 or better. The ubRMSE for L4_SM surface (root zone) soil moisture is 0.038 m3 m−3 (0.030 m3 m−3) at the 9-km scale and 0.035 m3 m−3 (0.026 m3 m−3) at the 36-km scale. The L4_SM estimates improve (significantly at the 5% level for surface soil moisture) over model-only estimates, which do not benefit from the assimilation of SMAP brightness temperature observations and have a 9-km surface (root zone) ubRMSE of 0.042 m3 m−3 (0.032 m3 m−3). Time series correlations exhibit similar relative performance. The sparse network results corroborate these findings over a greater variety of climate and land cover conditions.

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