WRF模式中台风“启德”模拟对参数化方案的敏感性分析

doi:10.3969/j.issn.1001-909X.2019.01.001

海洋学研究 ›› 2019, Vol. 37 ›› Issue (1): 1-8.DOI: 10.3969/j.issn.1001-909X.2019.01.001

• 研究论文 • 下一篇

WRF模式中台风“启德”模拟对参数化方案的敏感性分析

伍志元^1,2,3, 蒋昌波^*1,2, 邓斌^1,2, 曹永港⁴

1.长沙理工大学水利工程学院,湖南长沙 410004;
2.水沙科学与水灾害防治湖南省重点实验室,湖南长沙 410004;
3.美国麻省大学海洋科学与技术学院,马萨诸塞州新贝德福德 02744;
4.国家海洋局南海调查技术中心,广东广州 510300

收稿日期:2018-04-04 修回日期:2018-11-29 出版日期:2019-03-15 发布日期:2022-11-21
通讯作者: *蒋昌波(1970-),男,教授,主要从事河流、海岸动力过程及其模拟技术研究。E-mail: jiangchb@csust.edu.cn
作者简介:伍志元(1989-),男,湖南新化县人,博士(后),主要从事海岸、海洋多尺度动力过程及其模拟技术研究。E-mail: zwu@csust.edu.cn
基金资助:
国家自然科学基金重点项目资助(51839002);国家自然科学基金项目资助(51509023, 51809023,51879015);水利部珠江河口动力学及伴生过程调控重点实验室开放研究基金项目资助([2018]KJ03);国家海洋局南海维权技术与应用重点实验室开放基金项目资助(SCS1606);水沙科学与水灾害防治湖南省重点实验室开放基金资助(2017SS04)

Sensitivity of different parameterization schemes on Typhoon Kai-tak prediction based on the WRF model

WU Zhi-yuan^1,2,3, JIANG Chang-bo^*1,2, DENG Bin^1,2, CAO Yong-gang⁴

1. School of Hydraulic Engineering, Changsha University of Science & Technology, Changsha 410004, China;
2. Key Laboratory of Water-Sediment Sciences and Water DisasterPrevention of Hunan Province, Changsha 410004, China;
3. School for Marine Science andTechnology, University of Massachusetts Dartmouth, New Bedford 02744, USA;
4. Key Laboratory of Technology for Safeguarding of Maritime Rights and Interests andApplication, State Oceanic Administration, Guangzhou 510310, China

Received:2018-04-04 Revised:2018-11-29 Online:2019-03-15 Published:2022-11-21

摘要/Abstract

摘要： 为准确模拟台风路径和强度,采用WRF模式比较不同微物理过程和积云对流过程参数化方案对台风路径和强度模拟的影响,并基于集合预报方法考虑对台风预报系统误差进行优化。选用4种微物理过程方案和3种积云对流参数化方案,针对1213号台风“启德”进行模拟,结果表明不同的参数化方案对台风路径和强度的预报结果有明显影响,积云对流过程参数化方案相对于微物理过程参数化方案更加敏感。基于不同参数化方案扰动成员的集合平均预报方法,对于台风路径和强度的模拟误差均有明显改善,台风路径误差随时间增幅较小,其结果优于全部12个单方案试验的模拟结果;从台风强度方面来看,基于集合预报方法模拟得到的台风强度变化趋势与实况结果一致,且误差较小,优于大多数试验方案。结果表明:采用不同微物理过程和积云对流过程参数化方案的组合构建的集合预报模型,对于台风路径和强度的模拟均有一定程度改善,减小了采用不同参数化方案产生的路径不确定性,使其在台风“启德”的路径模拟上与实况更为接近,可为提升台风预报能力提供科学参考。

关键词: 台风, 中尺度大气模型, 微物理参数化, 积云对流参数化, 集合预报

Abstract: To accurately simulate the typhoon track and intensity, the WRF model was used to compare the sensitivity of different microphysical processes parameterization and cumulus convection parameterization on typhoon track and intensity simulation. The ensemble prediction method was been considered on the effect of the track and intensity error of typhoon Kai-tak. Four microphysical parameterization schemes and three cumulus convection parameterization schemes were selected to simulate for the track and intensity of Typhoon Kai-tak. The results show that different parameterization schemes have obvious influence on the simulation results of the track and intensity of typhoon. The parameterization scheme of cumulus convection is more sensitive than the parameterization scheme of microphysical process. Based on the ensemble prediction method of disturbing members based on different parameterization schemes, the simulation accurate of typhoon track and intensity is improved obviously. The error of typhoon track increases little with time, and the result is better than the simulation results of all twelve single schemes. From the aspect of typhoon intensity, the trend of typhoon intensity based on the ensemble prediction method is consistent with the actual result, which is better than the most of the test schemes. The results show that the ensemble prediction model constructed with different microphysical parameterization schemes and cumulus convection parameterization schemes can improve the simulation of typhoon track and intensity, reducing the track uncertainty produced by different parameterization schemes, which can provide a scientific reference for improving the forecasting ability of typhoon.

Key words: typhoon, mesoscale meteorological model, microphysical parameterization, cumulus convective parameterization, ensemble prediction method

中图分类号:

P732

伍志元, 蒋昌波, 邓斌, 曹永港. WRF模式中台风“启德”模拟对参数化方案的敏感性分析[J]. 海洋学研究, 2019, 37(1): 1-8.

WU Zhi-yuan, JIANG Chang-bo, DENG Bin, CAO Yong-gang. Sensitivity of different parameterization schemes on Typhoon Kai-tak prediction based on the WRF model[J]. Journal of Marine Sciences, 2019, 37(1): 1-8.

参考文献

[1] FANG Jia-yi, LIU Wei, YANG Sai-ni, et al. Spatial-temporal changes of coastal and marine disasters risks and impacts in Mainland China[J]. Ocean & Coastal Management, 2017, 139: 125-140.
[2] GUAN Shou-de, LI Shui-qing, HOU Yi-jun, et al. Increasing threat of landfalling typhoons in the western North Pacific between 1974 and 2013[J]. International Journal of Applied Earth Observation and Geoinformation, 2018, 68: 279-286.
[3] ZHANG Xia-kun, CHEN Jian, LAI Zhen-quan, et al. Analysis of special strong wind and severe rainstorm caused by typhoon Rammasun in Guangxi, China[J]. Journal of Geoscience and Environment Protection, 2017, 5(8): 235-251.
[4] YU Xiao-long, PAN Wei-ran, ZHENG Xiang-jing, et al. Effects of wave-current interaction on storm surge in the Taiwan Strait: Insights from Typhoon Morakot[J]. Continental Shelf Research, 2017, 146: 47-57.
[5] WU Zhi-yuan, JIANG Chang-bo, DENG Bin, et al. Simulation of the storm surge in the South China Sea based on the coupled sea-air model[J]. Chin Sci Bull, 2018, 63(11): 3 494-3 504.
伍志元, 蒋昌波, 邓斌, 等. 基于海气耦合模式的南中国海北部风暴潮模拟[J]. 科学通报, 2018, 63(11): 3 494-3 504.
[6] VAN NGUYEN H, CHEN Y L. High-resolution initialization and simulations of Typhoon Morakot (2009)[J]. Monthly Weather Review, 2011, 139(5): 1 463-1 491.
[7] LI Jing, MA Wei-min, MA Zhan-hong, et al. Impacts of WRF model vertical grid resolution on typhoon numerical simulation[J]. Ocean Technology, 2013, 32(2):76-81.
李靖, 马卫民, 马占宏,等. 台风数值模拟中模式垂直分辨率的影响分析[J]. 海洋技术学报, 2013, 32(2):76-81.
[8] SUN Min, YUAN Hui-ling. Impact of microphysics and cumulus convective parameterization schemes on WRF numerical simulation of typhoon Morakot[J]. Journal of Tropical Meteorology, 2014, 30(5):941-951.
孙敏, 袁慧玲. WRF模式中微物理和积云对流参数化方案对台风“莫拉克”模拟敏感性分析[J]. 热带气象学报, 2014, 30(5):941-951.
[9] RAJU P V S, POTTY J, MOHANTY U C. Sensitivity of physical parameterizations on prediction of tropical cyclone Nargis over the Bay of Bengal using WRF model[J]. Meteorology and Atmospheric Physics, 2011, 113(3-4): 125.
[10] LI Xiang. Sensitivity of WRF simulated typhoon track and intensity over the Northwest Pacific Ocean to cumulus schemes[J]. Science China: Earth Sciences, 2012(12):1 966-1 978.
李响. WRF模式中积云对流参数化方案对西北太平洋台风路径与强度模拟的影响[J]. 中国科学:地球科学, 2012(12):1 966-1 978.
[11] ZHOU Hao, ZHU Wei-jun, PENG Shi-qiu. The impacts of different micro-physics schemes and boundary layer schemes on simulated track and intensity of super typhoon Megi (1013) [J]. Journal of Tropical Meteorology, 2013, 29(5):803-812.
周昊, 朱伟军, 彭世球. 不同微物理方案和边界层方案对超强台风“鲇鱼”路径和强度模拟的影响分析[J]. 热带气象学报, 2013, 29(5):803-812.
[12] LI Xiang. Sensitivity of WRF simulated typhoon track and intensity over the Northwest Pacific Ocean to cumulus schemes[J]. Science China Earth Sciences, 2013, 56(2): 270-281.
[13] ISLAM T, SRIVASTAVA P K, RICO-RAMIREZ M A, et al. Tracking a tropical cyclone through WRF-ARW simulation and sensitivity of model physics[J]. Natural Hazards, 2015, 76(3): 1 473-1 495.
[14] OSURI K K, MOHANTY U C, ROUTRAY A, et al. Customization of WRF-ARW model with physical parameterization schemes for the simulation of tropical cyclones over North Indian Ocean[J]. Natural Hazards, 2012, 63(3): 1 337-1 359.
[15] CHANDRASEKAR R, BALAJI C. Sensitivity of tropical cyclone Jal simulations to physics parameterizations[J]. Journal of Earth System Science, 2012, 121(4): 923-946.
[16] SUN Yuan, ZHONG Zhong, DONG Hong, et al. Sensitivity of tropical cyclone track simulation over the western North Pacific to different heating/drying rates in the Betts-Miller-Janjic' scheme[J]. Monthly Weather Review, 2015, 143(9): 3 478-3 494.
[17] SHEPHERD T J, WALSH K J. Sensitivity of hurricane track to cumulus parameterization schemes in the WRF model for three intense tropical cyclones: impact of convective asymmetry[J]. Meteorology and Atmospheric Physics, 2017, 129(4): 345-374.
[18] WANG W, BRUYÈRE C, DUDA M, et al. ARW version 3 modelling system user's guide[R]. 2009.
[19] SKAMAROCK W C, KLEMP J B, DUDHIA J, et al. A description of the advanced research WRF version 2[R]. National Center for Atmospheric Research Boulder Co Mesoscale and Microscale Meteorology Div, 2005.
[20] LAPRISE R. The Euler equations of motion with hydrostatic pressure as an independent variable[J]. Monthly weather review, 1992, 120(1): 197-207.

WRF模式中台风“启德”模拟对参数化方案的敏感性分析

Sensitivity of different parameterization schemes on Typhoon Kai-tak prediction based on the WRF model

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 9

编辑推荐

Metrics

[1]	柯道勋, 张翰, 唐佑民, 等. 台风期间浮标和潜标上ADCP的空间变化、数据误差及校正#br#[J]. 海洋学研究, 2022, 40(1): 101-111.
[2]	陈升, 甘敏, 孙丽, 谢冬梅, 陈永平. 上海沿海风暴潮历史特征分析[J]. 海洋学研究, 2021, 39(4): 101-108.
[3]	潘存鸿, 潘冬子, 郑君, 陈刚. 台风对钱塘江涌潮影响研究[J]. 海洋学研究, 2020, 38(4): 40-47.
[4]	方明豹, 黄佳钰, 杨万康, 孙纯键. 海岛核电厂址的设计基准洪水位研究[J]. 海洋学研究, 2020, 38(4): 80-87.
[5]	任剑波, 何青, 沈健, 郭磊城, 徐凡. 远区台风“三巴”对河口波浪增水和波生流影响数值模拟研究[J]. 海洋学研究, 2019, 37(3): 21-30.
[6]	马志康, 付东洋, 屈科, 朱凤芹. 台风“天秤”对两种深海声道下声传播的影响[J]. 海洋学研究, 2019, 37(3): 40-48.
[7]	伍志元, 蒋昌波, 何智勇, 陈杰, 邓斌, 谢振东. 大气-海浪耦合模式及其在理想台风模拟中的应用研究[J]. 海洋学研究, 2019, 37(2): 9-15.
[8]	邹逸航, 马旭林, 姜胜, 何海伦, 郭欢. COSMIC掩星资料同化对台风“天兔”预报影响的试验[J]. 海洋学研究, 2017, 35(3): 9-19.
[9]	李程, 李欢, 王慧, 高佳, 王国松, 董军兴, 潘嵩, 刘克修. 1509号台风灿鸿期间“朱家尖-嵊山”高频地波雷达数据分析[J]. 海洋学研究, 2017, 35(1): 41-46.