Relationships between Large Precipitating Systems and Atmospheric Factors at a Grid Scale

Chen, Baohua; Liu, Chuntao; Mapes, Brian E.

doi:10.1175/jas-d-16-0049.1

Cited by 20 publications

(24 citation statements)

References 137 publications

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“…The convective thermodynamic and dynamic (e.g., shear) environment is known to strongly influence the development of moist convection (Stevens 2005;Sherwood 2010; Sherwood et al 2010;de Rooy et al 2013;Kim et al 2014;Virman et al 2018). These sensitivities have been examined from an observational perspective (Johnson and Lin 1997;Holloway andNeelin 2009, 2010;Tobin et al 2012;Masunaga 2012Masunaga , 2013Kumar et al 2014;Pereira de Oliveira and Oyama 2015;Bergemann and Jakob 2016;Hannah et al 2016;Schiro et al 2016;Yuan 2016;Chen et al 2017;Stevens et al 2017;Virman et al 2018), as well as via the use of high-resolution numerical models (Crook 1996;Derbyshire et al 2004;Mapes 2004;Raymond and Sessions 2007;Eitzen and Xu 2008;Wandishin et al 2008;Kuang 2010;Tulich and Mapes 2010;Cui et al 2011;Kirshbaum 2011;Hagos and Leung 2012;Böing et al 2012a,b;Hohenegger and Stevens 2013;Sessions et al 2015;Takemi 2015;Hernandez-Deckers and Sherwood 2016;Hannah 2017;Tsai and Wu 2017;Wang and Sobel 2017). Cloud microphysical processes have also bee...…”

Section: Introductionmentioning

confidence: 99%

On the Relative Sensitivity of a Tropical Deep Convective Storm to Changes in Environment and Cloud Microphysical Parameters

Posselt

Bukowski

et al. 2019

Journal of the Atmospheric Sciences

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Monte Carlo and Morris screening techniques are used to examine the relative sensitivity of deep convective simulations to changes in initial conditions (IC) versus changes to microphysical parameters (MP). IC are perturbed using a set of empirical orthogonal function–principal component pairs obtained from a database of tropical soundings, while MP are perturbed consistent with their range of realistic values. Monte Carlo experiments provide a broad overview of parameter–output response, while Morris screening techniques identify the most significant influences on specific model output variables. Changes to MP produce a similar order-of-magnitude response in convective hydrologic cycle, dynamics, and latent heating as changes to IC. Changes in IC appear to have a larger effect on radiative fluxes than perturbations to MP. The distribution of low-level latent heating reveals that changes in MP have a larger influence on cold pool properties than changes to the environment. The dominant effects are produced by a subset of cloud MP and thermodynamic structure functions, indicating perturbation of a subset of the control factors may be used to produce most of the variability in a short-term convective-scale ensemble forecast. The most influential MP are the autoconversion threshold, the rain particle size distribution intercept, and the ice particle fall speed parameters. The most influential EOFs are those that correspond to variability in lower- to midtropospheric temperature and water vapor, as well as zonal low-level shear. The results have implications for both the understanding of what influences convective development and the design of ensemble-based prediction and data assimilation systems.

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Section: Introductionmentioning

confidence: 99%

On the Relative Sensitivity of a Tropical Deep Convective Storm to Changes in Environment and Cloud Microphysical Parameters

Posselt

Bukowski

et al. 2019

Journal of the Atmospheric Sciences

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“…The relatively high spatial correlations for LCL and RHM suggest that they are also useful in the prediction of intense thunderstorms. TCWV, a useful predictor for large precipitating systems (Chen et al, ), with the combination of CAPE, CIN, and SHEAR 1–3 km , does not show good performance in the estimation of intense thunderstorms with high‐flash rate. The spatial correlation related to LI 500 is relatively low, compared to other variables.…”

Section: Resultsmentioning

confidence: 99%

A Bayesian‐Like Approach to Describe the Regional Variation of High‐Flash Rate Thunderstorms From Thermodynamic and Kinematic Environment Variables

Liu

Tissot

2019

JGR Atmospheres

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A 16‐year Tropical Rainfall Measuring Mission convective feature (CF) data set and ERA‐Interim reanalysis data are used to examine the nonlinear relationships between thermodynamic environments and the probability of high‐flash rate thunderstorms. First, Bayesian‐like probability functions are established between preselected ERA‐Interim thermodynamic variables and the high‐flash rate CFs. Then, the global geographical distribution of high‐flash rate thunderstorms is validated by applying these functions to the reanalysis data. The results suggest that a sole environmental factor has limited skill to estimate the probability of these events. The combination of four variables, including Convective Available Potential Energy, convection inhibition, low‐level shear, and warm cloud depth, may be used to derive a geographical distribution of high‐flash rate events that is close to the observations. The strong land‐ocean contrast in the frequency of high‐flash rate thunderstorms and some hot spot regions can be closely reproduced based only on these four variables from the reanalysis data. This indicates that the land‐ocean contrast in the occurrence of high‐flash rate thunderstorms can be largely interpreted by the fundamental differences between the thermodynamic conditions over land and ocean.

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“…Although some studies have shown that shear at higher levels can be important for organization (e.g., Chen et al, 2015), focusing on the lower troposphere can be justified from the results of theoretical studies such as those of Rotunno et al (1988); Thorpe et al (1982), and observational studies such as LeMone et al (1998). Likewise, Chen et al (2017) showed that deep shear was a poor predictor for MCS activity, whereas low-level shear was a better predictor. Second, we do not expect the relative rotation of the wind profiles to have a large effect on the organization that they induce.…”

Section: Overview Of Clustering Procedures Used To Generate the Representative Wind Profilesmentioning

confidence: 99%

“…The motivation for their work was to choose optimal vertical bins for the Atmospheric Dynamics Mission Aeolus satellite, and so opportunities for comparison against the work presented here are limited as they are focused on answering different questions which means their analysis cannot easily be compared with ours. Chen et al (2017) investigated the link between large-scale predictor variables and large (rain area > 10000 km 2 ) precipitation features. They used data from the Tropical Rainfall Measuring Mission (TRMM) satellite to provide information about the distribution of MCSs, and ERA-Interim to obtain information about the large-scale environment.…”

Section: Introductionmentioning

confidence: 99%

A climatology of tropical wind shear produced by clustering wind profiles from a climate model

Muetzelfeldt¹,

Plant²,

Clark³

et al. 2021

Preprint

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Abstract. A procedure for producing a climatology of tropical wind shear from climate-model output is presented. The procedure is designed to find grid columns in the model where the organization of convection may be present. The climate-model output consists of east–west and north–south wind profiles at 20 equally spaced pressure levels from 1000 hPa to 50 hPa, and the Convective Available Potential Energy (CAPE) as diagnosed by the model’s Convection Parametrization Scheme (CPS). The procedure begins by filtering the wind profiles based on their maximum shear, and on a CAPE threshold of 100 J kg−1. The filtered profiles are normalized using the maximum wind speed at each pressure level, and rotated to align the wind at 850 hPa. From each of the filtered profiles, a sample has been produced with 40 dimensions (20 for each wind direction). The number of dimensions is reduced by using Principal Component Analysis (PCA), where the requirement is that 90 % of the variance must be explained by the principal components. This requires keeping the first seven leading principal components. The samples, as represented by their principal components, can then be clustered using the K-Means Clustering Algorithm (KMCA). 10 clusters are chosen to represent the samples, and the median of each cluster defines a Representative Wind Profile (RWP) – a profile that represents the shear conditions of the wind profiles produced by the climate model. The RWPs are analysed, first in terms of their vertical structure, and then in terms of their geographical and temporal distributions. We find that the RWPs have some features often associated with the organization of convection, such as low-level and mid-level shear. Some of the RWPs can be matched with wind profiles taken from case studies of organization of convection, such as squall lines seen in Tropical Ocean Global Atmosphere, Coupled Atmosphere Ocean Research Experiment (TOGA–COARE). The RWPs’ geographical distributions show that each RWP occurs preferentially in certain regions. Six of the RWPs occur preferentially over land, while three occur preferentially over oceans. The temporal distribution of RWPs shows that they occur preferentially at certain times of the year, with the distributions having mainly one or two modes. Their geographical and temporal distributions are compared with those seen in previous studies of organized convection, and some broad and specific similarities are noted. By performing the analysis on climate-model output, we lay the foundations for the development of the representation of shear-induced organization in a CPS. This would use the same methodology to diagnose where the organization of convection occurs, and modify the CPS in an appropriate manner to represent it.

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Relationships between Large Precipitating Systems and Atmospheric Factors at a Grid Scale

Cited by 20 publications

References 137 publications

On the Relative Sensitivity of a Tropical Deep Convective Storm to Changes in Environment and Cloud Microphysical Parameters

On the Relative Sensitivity of a Tropical Deep Convective Storm to Changes in Environment and Cloud Microphysical Parameters

A Bayesian‐Like Approach to Describe the Regional Variation of High‐Flash Rate Thunderstorms From Thermodynamic and Kinematic Environment Variables

A climatology of tropical wind shear produced by clustering wind profiles from a climate model

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