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  • Author or Editor: D. W. O'Sullivan x
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Robert M. Rauber
,
Bjorn Stevens
,
Harry T. Ochs III
,
Charles Knight
,
B. A. Albrecht
,
A. M. Blyth
,
C. W. Fairall
,
J. B. Jensen
,
S. G. Lasher-Trapp
,
O. L. Mayol-Bracero
,
G. Vali
,
J. R. Anderson
,
B. A. Baker
,
A. R. Bandy
,
E. Burnet
,
J.-L. Brenguier
,
W. A. Brewer
,
P. R. A. Brown
,
R Chuang
,
W. R. Cotton
,
L. Di Girolamo
,
B. Geerts
,
H. Gerber
,
S. Göke
,
L. Gomes
,
B. G. Heikes
,
J. G. Hudson
,
P. Kollias
,
R. R Lawson
,
S. K. Krueger
,
D. H. Lenschow
,
L. Nuijens
,
D. W. O'Sullivan
,
R. A. Rilling
,
D. C. Rogers
,
A. P. Siebesma
,
E. Snodgrass
,
J. L. Stith
,
D. C. Thornton
,
S. Tucker
,
C. H. Twohy
, and
P. Zuidema

Shallow, maritime cumuli are ubiquitous over much of the tropical oceans, and characterizing their properties is important to understanding weather and climate. The Rain in Cumulus over the Ocean (RICO) field campaign, which took place during November 2004–January 2005 in the trades over the western Atlantic, emphasized measurements of processes related to the formation of rain in shallow cumuli, and how rain subsequently modifies the structure and ensemble statistics of trade wind clouds. Eight weeks of nearly continuous S-band polarimetric radar sampling, 57 flights from three heavily instrumented research aircraft, and a suite of ground- and ship-based instrumentation provided data on trade wind clouds with unprecedented resolution. Observational strategies employed during RICO capitalized on the advances in remote sensing and other instrumentation to provide insight into processes that span a range of scales and that lie at the heart of questions relating to the cause and effects of rain from shallow maritime cumuli.

Full access
Robert M. Rauber
,
Harry T. Ochs III
,
L. Di Girolamo
,
S. Göke
,
E. Snodgrass
,
Bjorn Stevens
,
Charles Knight
,
J. B. Jensen
,
D. H. Lenschow
,
R. A. Rilling
,
D. C. Rogers
,
J. L. Stith
,
B. A. Albrecht
,
P. Zuidema
,
A. M. Blyth
,
C. W. Fairall
,
W. A. Brewer
,
S. Tucker
,
S. G. Lasher-Trapp
,
O. L. Mayol-Bracero
,
G. Vali
,
B. Geerts
,
J. R. Anderson
,
B. A. Baker
,
R. P. Lawson
,
A. R. Bandy
,
D. C. Thornton
,
E. Burnet
,
J-L. Brenguier
,
L. Gomes
,
P. R. A. Brown
,
P. Chuang
,
W. R. Cotton
,
H. Gerber
,
B. G. Heikes
,
J. G. Hudson
,
P. Kollias
,
S. K. Krueger
,
L. Nuijens
,
D. W. O'Sullivan
,
A. P. Siebesma
, and
C. H. Twohy
Full access
D. R. Feldman
,
A. C. Aiken
,
W. R. Boos
,
R. W. H. Carroll
,
V. Chandrasekar
,
S. Collis
,
J. M. Creamean
,
G. de Boer
,
J. Deems
,
P. J. DeMott
,
J. Fan
,
A. N. Flores
,
D. Gochis
,
M. Grover
,
T. C. J. Hill
,
A. Hodshire
,
E. Hulm
,
C. C. Hume
,
R. Jackson
,
F. Junyent
,
A. Kennedy
,
M. Kumjian
,
E. J. T. Levin
,
J. D. Lundquist
,
J. O’Brien
,
M. S. Raleigh
,
J. Reithel
,
A. Rhoades
,
K. Rittger
,
W. Rudisill
,
Z. Sherman
,
E. Siirila-Woodburn
,
S. M. Skiles
,
J. N. Smith
,
R. C. Sullivan
,
A. Theisen
,
M. Tuftedal
,
A. C. Varble
,
A. Wiedlea
,
S. Wielandt
,
K. Williams
, and
Z. Xu

Abstract

The science of mountainous hydrology spans the atmosphere through the bedrock and inherently crosses physical and disciplinary boundaries: land–atmosphere interactions in complex terrain enhance clouds and precipitation, while watersheds retain and release water over a large range of spatial and temporal scales. Limited observations in complex terrain challenge efforts to improve predictive models of the hydrology in the face of rapid changes. The Upper Colorado River exemplifies these challenges, especially with ongoing mismatches between precipitation, snowpack, and discharge. Consequently, the U.S. Department of Energy’s (DOE) Atmospheric Radiation Measurement (ARM) user facility has deployed an observatory to the East River Watershed near Crested Butte, Colorado, between September 2021 and June 2023 to measure the main atmospheric drivers of water resources, including precipitation, clouds, winds, aerosols, radiation, temperature, and humidity. This effort, called the Surface Atmosphere Integrated Field Laboratory (SAIL), is also working in tandem with DOE-sponsored surface and subsurface hydrologists and other federal, state, and local partners. SAIL data can be benchmarks for model development by producing a wide range of observational information on precipitation and its associated processes, including those processes that impact snowpack sublimation and redistribution, aerosol direct radiative effects in the atmosphere and in the snowpack, aerosol impacts on clouds and precipitation, and processes controlling surface fluxes of energy and mass. Preliminary data from SAIL’s first year showcase the rich information content in SAIL’s many datastreams and support testing hypotheses that will ultimately improve scientific understanding and predictability of Upper Colorado River hydrology in 2023 and beyond.

Open access
Edward G. Patton
,
Thomas W. Horst
,
Peter P. Sullivan
,
Donald H. Lenschow
,
Steven P. Oncley
,
William O. J. Brown
,
Sean P. Burns
,
Alex B. Guenther
,
Andreas Held
,
Thomas Karl
,
Shane D. Mayor
,
Luciana V. Rizzo
,
Scott M. Spuler
,
Jielun Sun
,
Andrew A. Turnipseed
,
Eugene J. Allwine
,
Steven L. Edburg
,
Brian K. Lamb
,
Roni Avissar
,
Ronald J. Calhoun
,
Jan Kleissl
,
William J. Massman
,
Kyaw Tha Paw U
, and
Jeffrey C. Weil

The Canopy Horizontal Array Turbulence Study (CHATS) took place in spring 2007 and is the third in the series of Horizontal Array Turbulence Study (HATS) experiments. The HATS experiments have been instrumental in testing and developing subfilterscale (SFS) models for large-eddy simulation (LES) of planetary boundary layer (PBL) turbulence. The CHATS campaign took place in a deciduous walnut orchard near Dixon, California, and was designed to examine the impacts of vegetation on SFS turbulence. Measurements were collected both prior to and following leafout to capture the impact of leaves on the turbulence, stratification, and scalar source/sink distribution. CHATS utilized crosswind arrays of fast-response instrumentation to investigate the impact of the canopy-imposed distribution of momentum extraction and scalar sources on SFS transport of momentum, energy, and three scalars. To directly test and link with PBL parameterizations of canopy-modified turbulent exchange, CHATS also included a 30-m profile tower instrumented with turbulence instrumentation, fast and slow chemical sensors, aerosol samplers, and radiation instrumentation. A highresolution scanning backscatter lidar characterized the turbulence structure above and within the canopy; a scanning Doppler lidar, mini sodar/radio acoustic sounding system (RASS), and a new helicopter-observing platform provided details of the PBL-scale flow. Ultimately, the CHATS dataset will lead to improved parameterizations of energy and scalar transport to and from vegetation, which are a critical component of global and regional land, atmosphere, and chemical models. This manuscript presents an overview of the experiment, documents the regime sampled, and highlights some preliminary key findings.

Full access