Vertical motions of the tropical convective cloud spectrum over Darwin, Australia

Schumacher, Courtney; Stevenson, Stephanie N.; Williams, C. R.

doi:10.1002/qj.2520

Cited by 30 publications

(23 citation statements)

References 50 publications

(90 reference statements)

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“…As from Figure , we find that mass flux profiles for these congestus (dashed lines) are roughly half the values found for deeper clouds (solid lines) at the heights where both sets of clouds are available. One interpretation is that mean congestus updrafts are not substantially weaker at these altitudes, perhaps in contrast to findings from Schumacher et al []. However, it is likely that simple ETH threshold methods may also be partially influenced by catching only the peripheries (chording) of deeper clouds, or not effective at isolating congestus from growing deep cumulus cloud behaviors.…”

Section: Observational Breakdowns From the Goamazon2014/5 Campaignmentioning

confidence: 63%

“…Although aircraft studies provide reliable measurements, the cost and practical hazards for flight operations in deeper convective cells limit the availability of these data sets. Recently, radar wind profilers (RWP) have emerged as a less expensive and safer alternative to aircraft studies [e.g., Battan and Theiss , ; May and Rajopadhyaya , ; Williams , ; Giangrande et al , ; Schumacher et al , ; Kumjian et al , ]. Recent profiler upgrades have enabled the collection of vertical velocity measurements at sufficient temporal and vertical resolution for convective core studies.…”

Section: Introductionmentioning

confidence: 99%

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Convective cloud vertical velocity and mass‐flux characteristics from radar wind profiler observations during GoAmazon2014/5

et al. 2016

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A radar wind profiler data set collected during the 2 year Department of Energy Atmospheric Radiation Measurement Observations and Modeling of the Green Ocean Amazon (GoAmazon2014/5) campaign is used to estimate convective cloud vertical velocity, area fraction, and mass flux profiles. Vertical velocity observations are presented using cumulative frequency histograms and weighted mean profiles to provide insights in a manner suitable for global climate model scale comparisons (spatial domains from 20 km to 60 km). Convective profile sensitivity to changes in environmental conditions and seasonal regime controls is also considered. Aggregate and ensemble average vertical velocity, convective area fraction, and mass flux profiles, as well as magnitudes and relative profile behaviors, are found consistent with previous studies. Updrafts and downdrafts increase in magnitude with height to midlevels (6 to 10 km), with updraft area also increasing with height. Updraft mass flux profiles similarly increase with height, showing a peak in magnitude near 8 km. Downdrafts are observed to be most frequent below the freezing level, with downdraft area monotonically decreasing with height. Updraft and downdraft profile behaviors are further stratified according to environmental controls. These results indicate stronger vertical velocity profile behaviors under higher convective available potential energy and lower low‐level moisture conditions. Sharp contrasts in convective area fraction and mass flux profiles are most pronounced when retrievals are segregated according to Amazonian wet and dry season conditions. During this deployment, wet season regimes favored higher domain mass flux profiles, attributed to more frequent convection that offsets weaker average convective cell vertical velocities.

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Section: Observational Breakdowns From the Goamazon2014/5 Campaignmentioning

confidence: 63%

Section: Introductionmentioning

confidence: 99%

Convective cloud vertical velocity and mass‐flux characteristics from radar wind profiler observations during GoAmazon2014/5

et al. 2016

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“…Since BR was developed using a Darwin monsoonal dataset, we anticipate that study included modest convective diversity into congestus clouds, maritime continental and deeper convective 25 properties (those supporting additional graupel growth). Darwin may exhibit even more intense 'Break' (e.g., more continental characteristics) convective cell periods and associated DSD changes interspersed with maritime tropical 'Active' monsoonal conditions than observed from Amazon convection (e.g., May and Ballinger, 2007;Dolan et al, 2013;Schumacher et al, 2015;Giangrande et al, 2014aGiangrande et al, , 2016b. However, it appears use of BR would minimize the contributions from congestus or shallower organized convective precipitation found under Amazon conditions.…”

Section: Amazon Precipitation Properties: Cumulative Dataset Charactementioning

confidence: 96%

The Green Ocean: Precipitation Insights from the GoAmazon2014/5 Experiment

Wang

Giangrande

Bartholomew

et al. 2018

Preprint

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“…Remote sensing by means of, for example, wind profiling radars is another technique that has often been used in recent years for studying the vertical velocity in convective clouds (e.g., Kollias and Albrecht, 2010;Hogan et al, 2009;Giangrande et al, 2013;Schumacher et al, 2015). Using profiler data, May and Rajopadhyaya (1999) analyzed the vertical velocity in deep convections near Darwin, Australia.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of vertical air motion in isolated convective clouds

et al. 2016

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Abstract. The vertical velocity and air mass flux in isolated convective clouds are statistically analyzed using aircraft in situ data collected from three field campaigns: High-Plains Cumulus (HiCu) conducted over the midlatitude High Plains, COnvective Precipitation Experiment (COPE) conducted in a midlatitude coastal area, and Ice in Clouds Experiment-Tropical (ICE-T) conducted over a tropical ocean. The results show that small-scale updrafts and downdrafts ( < 500 m in diameter) are frequently observed in the three field campaigns, and they make important contributions to the total air mass flux. The probability density functions (PDFs) and profiles of the observed vertical velocity are provided. The PDFs are exponentially distributed. The updrafts generally strengthen with height. Relatively strong updrafts (> 20 m s −1 ) were sampled in COPE and ICE-T. The observed downdrafts are stronger in HiCu and COPE than in ICE-T. The PDFs of the air mass flux are exponentially distributed as well. The observed maximum air mass flux in updrafts is of the order 10 4 kg m −1 s −1 . The observed air mass flux in the downdrafts is typically a few times smaller in magnitude than that in the updrafts. Since this study only deals with isolated convective clouds, and there are many limitations and sampling issues in aircraft in situ measurements, more observations are needed to better explore the vertical air motion in convective clouds.

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Vertical motions of the tropical convective cloud spectrum over Darwin, Australia

Cited by 30 publications

References 50 publications

Convective cloud vertical velocity and mass‐flux characteristics from radar wind profiler observations during GoAmazon2014/5

Convective cloud vertical velocity and mass‐flux characteristics from radar wind profiler observations during GoAmazon2014/5

The Green Ocean: Precipitation Insights from the GoAmazon2014/5 Experiment

Characteristics of vertical air motion in isolated convective clouds

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