Impact of physical parameterization schemes on numerical simulation of super cyclone Gonu

Deshpande, Medha; Pattnaik, Sandeep; Salvekar, P. S.

doi:10.1007/s11069-010-9521-x

Cited by 55 publications

(28 citation statements)

References 42 publications

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“…Dynamics and physical processes are very important in numerical models for understanding and forecast of TC [9]. Reference [10] revealed the sensitivity of TC development to cloud microphysics schemes in a hydrostatic model.…”

Section: Introductionmentioning

confidence: 99%

Impacts of Microphysics Schemes and Topography on the Prediction of the Heavy Rainfall in Western Myanmar Associated with Tropical Cyclone ROANU (2016)

Maw

Min

2017

Advances in Meteorology

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The impacts of different microphysics and boundary schemes and terrain settings on the heavy rainfall over western Myanmar associated with the tropical cyclone (TC) ROANU (2016) are investigated using the Weather Research and Forecasting (WRF) model. The results show that the microphysics scheme of Purdue Lin (LIN) scheme produces the strongest cyclone. Six experiments with various combinations of microphysics and boundary schemes indicated that a combination of WRF Single-Moment 6-class (WSM6) scheme and Mellor-Yamada-Janjic (MYJ) best fits to the Joint Typhoon Warning Center (JTWC) data. WSM6-MYJ also performs the best for the track and intensity of rainfall and obtains the best statistics skill scores in the range of maximum rainfall intensity for 48-h. Sensitivity experiments on different terrain settings with Normal Rakhine Mountain (NRM), with Half of Rakhine Mountain (HRM), and Without Rakhine Mountain (WoRM) are designed with the use of WSM6-MYJ scheme. The track of TC ROANU moved northwestward in WoRM and HRM. Due to the presence of Rakhine Mountain, TC track moved into Myanmar and the peak rainfall occurred on the leeward side of the Mountain. In the absence of Rakhine Mountain, a shift in peak rainfall was observed in north side of the Mountain.

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Section: Introductionmentioning

confidence: 99%

Impacts of Microphysics Schemes and Topography on the Prediction of the Heavy Rainfall in Western Myanmar Associated with Tropical Cyclone ROANU (2016)

Maw

Min

2017

Advances in Meteorology

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“…(e.g. Mohanty et al, 2004;Bhaskar Rao et al, 2006, 2007Prasad and Rama Rao, 2003;Trivedi et al, 2006;Srinivas et al, 2007Srinivas et al, , 2010Deshpande et al, 2010;Krishna et al, 2010;Mukhopadhyay et al, 2011;Singh et al, 2008Singh et al, , 2011Singh et al, , 2012Pattanik andMohanty, 2008, 2010;Raju et al, 2011a). Very few studies have reported the performance of numerical models statistically for the cyclones over the NIO.…”

Section: Introductionmentioning

confidence: 99%

Tropical cyclone predictions over the Bay of Bengal using the high‐resolution Advanced Research Weather Research and Forecasting (ARW) model

Srinivas¹,

Rao²,

Yesubabu³

et al. 2012

Quart J Royal Meteoro Soc

124

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“…Mandal et al (2004) studied the impact of various physical parameterization schemes on the prediction of two tropical cyclones formed during November 1995 over the Bay of Bengal using MM5. Deshpande et al (2010) studied the sensitivity of various physical parameterization schemes on the numerical simulation of Super Cyclone Gonu and reported that the forecast track and intensity of the cyclone are most sensitive to CPS, compared to other physical parameterization schemes (e.g. PBL and MPS).…”

Section: Introductionmentioning

confidence: 99%

Impact of cloud parameterization on the numerical simulation of a super cyclone

2012

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Abstract. This study examines the role of parameterization of convection and explicit moisture processes on the simulated track, intensity and inner core structure of Orissa super cyclone (1999) in Bay of Bengal (north Indian Ocean). Sensitivity experiments are carried out to examine the impact of cumulus parameterization schemes (CPS) using MM5 model (Version 3.7) in a two-way nested domain (D1 and D2) configuration at horizontal resolutions (45-15 km). Three different cumulus parameterization schemes, namely Grell (Gr), Betts-Miller (BM) and updated Kain Fritsch (KF2), are tested. It is noted that track and intensity both are very sensitive to CPS and comparatively, KF2 predicts them reasonably well. Particularly, the rapid intensification phase of the super cyclone is best simulated by KF2 compared to other CPS. To examine the effect of the cumulus parameterization scheme at high resolution (5 km), the three-domain configuration (45-15-5 km resolution) is utilized. Based on initial results, KF2 scheme is used for both the domains (D1 and D2). Two experiments are conducted: one in which KF2 is used as CPS and another in which no CPS is used in the third domain. The intensity is well predicted when no CPS is used in the innermost domain. The sensitivity experiments are also carried out to examine the impact from microphysics parameterization schemes (MPS). Four cloud microphysics parameterization schemes, namely mixed phase (MP), Goddard microphysics with Graupel (GG), Reisner Graupel (RG) and Schultz (Sc), are tested in these experiments. It is noted that the tropical cyclone tracks and intensity variation have considerable sensitivity to the varying cloud microphysical parameterization schemes. The MPS of MP and Sc could very well capture the rapid intensification phase. The final intensity is well predicted by MP, which is overestimated by Sc. The MPS of GG and RG underestimates the intensity.

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Impact of physical parameterization schemes on numerical simulation of super cyclone Gonu

Cited by 55 publications

References 42 publications

Impacts of Microphysics Schemes and Topography on the Prediction of the Heavy Rainfall in Western Myanmar Associated with Tropical Cyclone ROANU (2016)

Impacts of Microphysics Schemes and Topography on the Prediction of the Heavy Rainfall in Western Myanmar Associated with Tropical Cyclone ROANU (2016)

Tropical cyclone predictions over the Bay of Bengal using the high‐resolution Advanced Research Weather Research and Forecasting (ARW) model

Impact of cloud parameterization on the numerical simulation of a super cyclone

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