Scale‐aware parameterization of liquid cloud inhomogeneity and its impact on simulated climate in CESM

Xie, Xiaoning; Zhang, Minghua

doi:10.1002/2015jd023565

Cited by 28 publications

(40 citation statements)

References 39 publications

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“…For example, the underestimation of precipitation in the late spring is present in both UNIF and VR‐CESM simulations (Figure ), which was also found in three of six RCMs (Wang et al, ). Such model biases may be reduced by using scale‐aware parameterizations (e.g., Xie & Zhang, ). Despite this, our results show that the current version of VR‐CESM has the capability to simulate the key aspects of regional climate in the Rocky Mountain region.…”

Section: Discussionmentioning

confidence: 99%

Exploring a Variable‐Resolution Approach for Simulating Regional Climate in the Rocky Mountain Region Using the VR‐CESM

Liu

Lin

et al. 2017

JGR Atmospheres

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The reliability of climate simulations and projections, particularly in the regions with complex terrains, is greatly limited by the model resolution. In this study we evaluate the variable‐resolution Community Earth System Model (VR‐CESM) with a high‐resolution (0.125°) refinement over the Rocky Mountain region. The VR‐CESM results are compared with observations, as well as CESM simulation at a quasi‐uniform 1° resolution (UNIF) and Canadian Regional Climate Model version 5 (CRCM5) simulation at a 0.11° resolution. We find that VR‐CESM is effective at capturing the observed spatial patterns of temperature, precipitation, and snowpack in the Rocky Mountains with the performance comparable to CRCM5, while UNIF is unable to do so. VR‐CESM and CRCM5 simulate better the seasonal variations of precipitation than UNIF, although VR‐CESM still overestimates winter precipitation whereas CRCM5 and UNIF underestimate it. All simulations distribute more winter precipitation along the windward (west) flanks of mountain ridges with the greatest overestimation in VR‐CESM. VR‐CESM simulates much greater snow water equivalent peaks than CRCM5 and UNIF, although the peaks are still 10–40% less than observations. Moreover, the frequency of heavy precipitation events (daily precipitation ≥ 25 mm) in VR‐CESM and CRCM5 is comparable to observations, whereas the same events in UNIF are an order of magnitude less frequent. In addition, VR‐CESM captures the observed occurrence frequency and seasonal variation of rain‐on‐snow days and performs better than UNIF and CRCM5. These results demonstrate the VR‐CESM's capability in regional climate modeling over the mountainous regions and its promising applications for climate change studies.

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Section: Discussionmentioning

confidence: 99%

Exploring a Variable‐Resolution Approach for Simulating Regional Climate in the Rocky Mountain Region Using the VR‐CESM

Liu

Lin

et al. 2017

JGR Atmospheres

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“…(27) from the MODIS retrieval of COT and CER. Several previous studies have shown that the subpixellevel surface contamination, subpixel cloud inhomogeneity, and three-dimensional radiative transfer effects can cause significant errors in the MODIS CER retrievals, especially over broken cloud regions (Zhang and Platnick, 2011;Zhang et al, 2012Zhang et al, , 2016. Given the fact that the CDNC retrieval is highly sensitive to CER error as a result of N d ∼ r − 5 2 e , the influence of retrieval uncertainty on subgrid CDNC variation cannot be ruled out.…”

Section: Influence Of Subgrid Variance Of Cdncmentioning

confidence: 99%

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Zhang¹

2018

Preprint

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“…A number of predictors for the FSD were investigated and cloud depth above the melting level was found to be a more successful discriminant between high and low FSD samples for ice cloud than either cloud-top height, height above ground, atmospheric stability (in the form of a moist static energy difference between the mid-troposphere and surface, as suggested in Xie and Zhang, 2015) or variables scaling directly with height and latitude (such as e.g. temperature or humidity).…”

Section: Regime Dependencementioning

confidence: 99%

“…Observations of cloud properties can provide guidance on this topic, and conclusions from previous studies include characterization of cloud heterogeneity by a single global parameter (Shonk et al, 2010), or from a climatology of cloud heterogeneity from satellite observations (Oreopoulos and Cahalan, 2005). However, observations also show that condensate heterogeneity varies systematically with cloud regime (Oreopoulos and Cahalan, 2005;Boutle et al, 2014;Huang and Liu, 2014;Xie and Zhang, 2015;Ahlgrimm and Forbes, 2016), and thus it is desirable to understand and capture this regime dependence for a more accurate representation of subgrid-scale process rates.…”

Section: Introductionmentioning

confidence: 99%

Regime dependence of ice cloud heterogeneity – a convective life‐cycle effect?

Ahlgrimm

Forbes

2017

Quart J Royal Meteoro Soc

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Cloud condensate varies on scales smaller than those typically resolved by global weather and climate models. In order to accurately predict the radiative and microphysical process rates representative of the entire model grid box, the effect of the subgrid‐scale heterogeneity of cloud must be taken into account. In this study, observed ice water content retrieved from A‐Train satellite observations is used to explore how spatial ice condensate variability, characterized by the fractional standard deviation (FSD, the standard deviation divided by the mean), varies with cloud regime. FSD is generally lower for overcast cloud scenes, but an additional predictor based on convective activity is needed to capture the high FSD associated with more turbulent clouds and reproduce the observed latitudinal and height variations of FSD. Convective clouds that extend only a few kilometres above the freezing level are likely to be smaller at an earlier stage in their life cycle, and actively growing with a higher FSD. In contrast, more mature clouds reaching the tropopause are larger and generally have a lower variability and smaller FSD. To capture this life‐cycle effect, a new parametrization is tested which uses the ratio of a model's convectively detrained condensate to the existing cloud condensate mass as a proxy for the cloud's convective life stage to highlight areas with enhanced condensate variability. The parametrization is scale‐adaptive, situation‐dependent and captures seasonally varying global patterns and the zonal mean vertical structure of observed ice condensate variability well. Ground‐based observations obtained from five Atmospheric Radiation Measurement sites provide independent confirmation that the parametrization satisfactorily captures condensate variability in high‐altitude ice clouds.

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Scale‐aware parameterization of liquid cloud inhomogeneity and its impact on simulated climate in CESM

Cited by 28 publications

References 39 publications

Exploring a Variable‐Resolution Approach for Simulating Regional Climate in the Rocky Mountain Region Using the VR‐CESM

Exploring a Variable‐Resolution Approach for Simulating Regional Climate in the Rocky Mountain Region Using the VR‐CESM

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Regime dependence of ice cloud heterogeneity – a convective life‐cycle effect?

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