Evaluation of the added value of a high‐resolution regional climate model simulation of the South Asian summer monsoon climatology

Karmacharya, J.; Jones, R. G.; Moufouma-Okia, Wilfran; New, Mark

doi:10.1002/joc.4944

Cited by 21 publications

(21 citation statements)

References 86 publications

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“…However, there are five experiments in which AV is found which indicates an improvement in the representation of spatial patterns of precipitation by the RCMs. These results further corroborate with the previous findings that AV shown by an RCM varies significantly in space over a region (Di Luca et al, ; Karmacharya et al, ; Rummukainen, ) and, hence, considering the spatial pattern over entire India the improvement may not be seen. A similar finding for the AV of CORDEX‐SA RCMs over India was made by Choudhary et al .…”

Section: Resultssupporting

confidence: 91%

“…() was recently used by Karmacharya et al . () for determining AV of a high resolution RCM simulation of ISM. This method is chosen because of the simplicity of computation and direct connection of AV with the reduction in magnitude of bias.…”

Section: Methodsmentioning

confidence: 99%

“…The issue of AV of RCMs has gathered a lot of attention in the recent years (Castro et al, ; Sotillo et al, ; Duffy et al, ; Feser ; Kanamitsu and Kanamaru, ; Rauscher et al, ; Sanchez‐Gomez et al, ; Winterfeldt and Weisse, ; De Sales and Xue, ; Prömmel et al, ; Paeth and Mannig, ; Di Luca et al, , , ; Karmacharya et al, ). The AV of an RCM implies that the additional information given by the RCM is reliable and/or has some utility (Rummukainen, ).…”

Section: Introductionmentioning

confidence: 99%

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Added value of CORDEX‐SA experiments in simulating summer monsoon precipitation over India

Choudhary

Dimri

Paeth

2018

Intl Journal of Climatology

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Regional climate models (RCMs) serve as an important tool to perform high resolution climate simulations for a limited area. However, there remains a crucial issue regarding the efficacy of RCMs that whether they are able to produce added value (AV) in representing the regional climatic features compared to their coarse scale driving Global climate models (GCMs). The present study aims at assessing the AV of a set of RCM simulations performed under the Coordinated Regional Climate Downscaling Experiments-South Asia (CORDEX-SA) compared with their respective driving GCMs in representing the Indian summer monsoon (ISM) precipitation and its dynamical features. For this purpose, the performance of RCMs and GCMs is compared for the present day climate against observations and reanalysis datasets in terms of various ISM features, that is, the spatial distribution of precipitation, the evolution of vertical shear of zonal wind and the onset phase of ISM in terms of delayed or early arrival of monsoon. The RCMs show a clear improvement upon their corresponding driving GCMs in simulating spatial features of precipitation distribution that are characteristically associated with ISM. Regionally, the RCMs also show skill in capturing the precipitation amount as a reduction in bias is found compared with their driving GCMs. There is a significant improvement in the simulation of onset dates of ISM by only some of the experiments particularly, RegCM4 driven with IPSL-CM5A-LR. The study concludes that the present set of CORDEX-SA RCM simulations do indeed add value to their driving GCMs for a number of features associated with the ISM precipitation but this value varies with region, driving GCM and the particular feature of ISM under focus.

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Section: Resultssupporting

confidence: 91%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Added value of CORDEX‐SA experiments in simulating summer monsoon precipitation over India

Choudhary

Dimri

Paeth

2018

Intl Journal of Climatology

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“…Unfortunately, these models also rarely agree on the magnitude of future change, a phenomenon classified as "uncertainty" in model results (Walker et al 2013). Uncertainty can be inherited from GCMs due to factors such as internal variability, modeling assumptions, and greenhouse gas emissions scenarios (Kirtman et al 2013), and can also arise from the spatial resolution of the RCM used in impact assessment (Leung and Qian 2003;Rauscher et al 2010Rauscher et al , 2016Prein et al 2016a;Mendoza et al 2016;Karmacharya et al 2017) and the MOS technique used in downscaling (Tryhorn and DeGaetano 2011;Gudmundsson et al 2012;Bürger et al 2013;Chen et al 2013;Srivastav et al 2014a;Sunyer et al 2014;Cannon et al 2015).…”

Section: Introductionmentioning

confidence: 99%

The effect of modeling choices on updating intensity-duration-frequency curves and stormwater infrastructure designs for climate change

2020

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Intensity-duration-frequency (IDF) curves, commonly used in stormwater infrastructure design to represent characteristics of extreme rainfall, are gradually being updated to reflect expected changes in rainfall under climate change. The modeling choices used for updating lead to large uncertainties; however, it is unclear how much these uncertainties affect the design and cost of stormwater systems. This study investigates how the choice of spatial resolution of the regional climate model (RCM) ensemble and the spatial adjustment technique affect climatecorrected IDF curves and resulting stormwater infrastructure designs in 34 US cities for the period 2020 to 2099. In most cities, IDF values are significantly different between three spatial adjustment techniques and two RCM spatial resolutions. These differences have the potential to alter the size of stormwater systems designed using these choices and affect the results of climate impact modeling more broadly. The largest change in the engineering decision results when the design storm is selected from the upper bounds of the uncertainty distribution of the IDF curve, which changes the stormwater pipe design size by five increments in some cases, nearly doubling the cost. State and local agencies can help reduce some of this variability by setting guidelines, such as avoiding the use of the upper bound of the future uncertainty range as a design storm and instead accounting for uncertainty by tracking infrastructure performance over time and preparing for adaptation using a resilience plan.

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“…Such vulnerability and exposure of the mountainous communities to the adverse socioeconomic impacts of changing climate and its induced disasters greatly highlights the importance of understanding their drivers and their subsequent impacts on various sectors of life for devising local-scale adaptation strategies. This requires, above all, fine-scale climatic information, particularly of surface air temperature (hereinafter temperature) and precipitation, which are also amongst the essential inputs to impact assessment models (Böhner and Lehmkuhl, 2005;Karmacharya et al, 2016;Gerlitz et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the added value of convection-permitting climate simulations in complex terrain: a systematic evaluation of WRF over the Himalayas

et al. 2017

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Abstract. Mesoscale dynamical refinements of global climate models or atmospheric reanalysis have shown their potential to resolve intricate atmospheric processes, their land surface interactions, and subsequently, realistic distribution of climatic fields in complex terrains. Given that such potential is yet to be explored within the central Himalayan region of Nepal, we investigate the skill of the Weather Research and Forecasting (WRF) model with different spatial resolutions in reproducing the spatial, seasonal, and diurnal characteristics of the near-surface air temperature and precipitation as well as the spatial shifts in the diurnal monsoonal precipitation peak over the Khumbu (Everest), Rolwaling, and adjacent southern areas. Therefore, the ERA-Interim (0.75 • ) reanalysis has been dynamically refined to 25, 5, and 1 km (D1, D2, and D3) for one complete hydrological year (October 2014-September 2015, using the one-way nested WRF model run with mild nudging and parameterized convection for the outer but explicitly resolved convection for the inner domains. Our results suggest that D3 realistically reproduces the monsoonal precipitation, as compared to its underestimation by D1 but overestimation by D2. All three resolutions, however, overestimate precipitation from the westerly disturbances, owing to simulating anomalously higher intensity of few intermittent events. Temperatures are generally reproduced well by all resolutions; however, winter and pre-monsoon seasons feature a high cold bias for high elevations while lower elevations show a simultaneous warm bias. Unlike higher resolutions, D1 fails to realistically reproduce the regional-scale nocturnal monsoonal peak precipitation observed in the Himalayan foothills and its diurnal shift towards high elevations, whereas D2 resolves these characteristics but exhibits a limited skill in reproducing such a peak on the river valley scale due to the limited representation of the narrow valleys at 5 km resolution. Nonetheless, featuring a substantial skill over D1 and D2, D3 simulates almost realistic shapes of the seasonal and diurnal precipitation and the peak timings even on valley scales. These findings clearly suggest an added value of the convective-scale resolutions in realistically resolving the topoclimates over the central Himalayas, which in turn allows simulating their interactions with the synoptic-scale weather systems prevailing over high Asia.Published by Copernicus Publications on behalf of the European Geosciences Union.

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Evaluation of the added value of a high‐resolution regional climate model simulation of the South Asian summer monsoon climatology

Cited by 21 publications

References 86 publications

Added value of CORDEX‐SA experiments in simulating summer monsoon precipitation over India

Added value of CORDEX‐SA experiments in simulating summer monsoon precipitation over India

The effect of modeling choices on updating intensity-duration-frequency curves and stormwater infrastructure designs for climate change

Quantifying the added value of convection-permitting climate simulations in complex terrain: a systematic evaluation of WRF over the Himalayas

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