شناسایی و ردیابی کمارتفاعهای بریده موثر در بارشهای سنگین ایران | ||
| پژوهشهای دانش زمین | ||
| دوره 15، شماره 3 - شماره پیاپی 59، 1403، صفحه 137-155 اصل مقاله (1.36 M) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.48308/esrj.2023.103188 | ||
| نویسندگان | ||
| شهرام لطفی قرانچای1؛ طیبه اکبری ازیرانی* 1؛ علیرضا شکیبا2؛ آمنه دشت بزرگی2؛ فاطمه ربانی3 | ||
| 1گروه جغرافیای طبیعی، دانشکده علوم زمین، دانشگاه شهید بهشتی، تهران، ایران | ||
| 2گروه سنجش از دور و GIS، دانشکده علوم زمین، دانشگاه شهید بهشتی، تهران، ایران | ||
| 3دانشگاه پیام نور تهران، واحد پرند، تهران، ایران | ||
| چکیده | ||
| مقدمه کمارتفاعهای بریده، سیکلونهای هسته سرد در وردسپهر فوقانی هستند که معمولاً به عنوان کمینههای محلی میدانهای ارتفاع ژئوپتانسیل در محدوده سطوح 500 و 200 هکتوپاسکال شناسایی میشوند (Muñoz et al, 2020; Pinheiro et al, 2017; Nito et al, 2008;). کمارتفاعهای بریده در بیشتر فصول سال و اغلب در اواخر زمستان و اوایل بهار جلوه میکنند. یکی از الگوهای همدیدی موثر در دما و بارش و همچنین بارشهای سنگین در ایران، کمارتفاعهای بریده هستند. این پژوهش با توجه به اهمیت و ارتباط بین کمارتفاعهای بریده و بارشهای سنگین در دوره آماری 33 ساله (2018 -1986) تدوین شده است. در این پژوهش به اقلیمشناسی سیستمهای کمارتفاع بریده سطح 500 هکتوپاسکال نیمکره شمالی موثر در بارش سنگین ایران پرداخته شد. برای شناسایی و ردیابی کمارتفاعهای بریده از دادههای بازتحلیل شده سایت ECMWF، و کمارتفاعهای بریده با عمر بیش از 48 ساعت در دوره آماری 33 سال (2018 - 1986) استفاده شد. دادههای ارتفاع ژئوپتانسیل، باد مداری و دمای تراز 500 هکتوپاسکال نیز برای تحلیل همدید به کار رفت. مواد و روشها در این پژوهش از دادههای متوسط روزانه: ارتفاع ژئوپتانسیل، باد مداری و دمای تراز 500 هکتوپاسکال باز تحلیل شده ECMWF سایت اروپا با گام شبکهای 125/0 * 125/0 درجهای در دوره آماری 33 سال (1986 - 2018) در منطقهای شامل 0 تا 80 درجه عرض شمالی و 0 تا 80 درجه طول شرقی استفاده شد. برای شناسایی کمارتفاعهای بریده از شاخص تیبالدی-مولتنی استفاده گردید. و کمارتفاعهای بریدهای که در بارش سنگین ایران موثر بودند مورد مطالعه قرار گرفت. نتایج و بحث توزیع سالانه، ماهانه و فصلی کمارتفاعهای بریده در طول دوره آماری در دوره آماری 33 سال (2018 -1986) در مجموع 632 رخداد کمارتفاع بریده با طول عمر 2 روز و بیشتر با میانگین 87/18 رخداد برای هر سال شناسایی شد. خط روند یا رگرسیون در طول دوره آماری نشان میدهد مقدار کمارتفاعهای بریده رو به افزایش است. سهم کمارتفاع بریده در بارش سنگین مناطق چهارگانه ایران در منطقه شمالغرب ایران بیشترین درصد اثر کمارتفاعهای بریده بر بارش سنگین به ترتیب در ایستگاههای کاشان، تکاب، مهاباد، مراغه و تبریز و کمترین درصد تاثیر این پدیده در بارش سنگین به ترتیب در ایستگاههای خرمآباد، کرج، بابلسر و پارسآباد بود. در منطقه جنوبشرق بیشترین درصد تاثیر در ایستگاههای چابهار، بندرعباس و سیرجان و کمترین درصد تاثیر در ایستگاههای جاسک، زابل، خاش بوده است. در منطقه جنوبغرب بیشترین درصد تاثیر در ایستگاههای بوشهر و کیش و کمترین تاثیر در ایستگاههای امیدیه و مسجدسلیمان است. در شمالشرق بیشترین درصد تاثیر در ایستگاههای بیرجند، فردوس و طبس و کمترین تاثیر در ایستگاههای گرگان، مشهد، قوچان و بجنورد بوده است. مقدار بارش سنگین و تاثیر کمارتفاع بریده در آن در مناطق مختلف و ایران بیشترین رخداد بارش سنگین در اثر کمارتفاع بریده در منطقه شمالغرب با (62/36 رخداد) و کمترین در منطقه جنوبشرق با (5/8 رخداد) بوده است. در ایستگاههای مطالعاتی پژوهش (76 ایستگاه) نیز فراوانی رخداد بارش سنگین در طول دوره مطالعاتی بهطور میانیگن (76/124 رخداد) بوده است و تاثیر کمارتفاع بریده در بارش سنگین در کل (1/26 رخداد) در ایستگاهها بوده است. نتیجه گیری در مجموع 632 کمارتفاع بریده با طول عمر 2 روز و بیشتر در منطقه پژوهش شناسایی شد. خط روند طول دوره آماری دارای شیب ملایم مثبت و افزایشی است، بیشترین رخداد کمارتفاع بریده در ماههای اکتبر، مارس و ژانویه است. کمترین فراوانی رخداد کمارتفاع بریده در ماههای جولای، آگوست و ژوئن است. از لحاظ فصلی، بیشترین تعداد رخداد کمارتفاع بریده در فصول بهار، زمستان و پاییز بود. همچنین بیشترین رخداد بارش سنگین تحتتاثیر کمارتفاع بریده در منطقه شمالغرب و کمترین در منطقه جنوبشرق در طول دوره مطالعاتی بوده است. بنابراین میتوان نتیجه گرفت که ورود کمارتفاعهای بریده از شمالغرب و نزدیکی منطقه شمالغرب به محل تشکیل کمارتفاعهای بریده میتواند عامل فراوانی بیشترین رخداد بارش سنگین تحتتاثیر کم ارتفاع بریده باشد. همچنین دوری منطقه جنوبشرق از کمارتفاعهای بریده، تاثیر کم این پدیده در بارش سنگین این منطقه را نشان میدهد. | ||
| کلیدواژهها | ||
| ایران؛ بارش سنگین؛ رودباد؛ شاخص (تیبالدی - مولتنی)؛ کمارتفاع بریده | ||
| عنوان مقاله [English] | ||
| Identifying and tracking cut-off lows effective in Iranian heavy rains | ||
| نویسندگان [English] | ||
| shahram lotfi gharanchai1؛ Tayebeh Akbari Azirani1؛ Alireza Shakoba2؛ Amemeh Dasht Bozorgi2؛ Fatemeh Rabbani3 | ||
| 1Department of Physical Geography, Faculty of earth sciences, Shahid Beheshti University, Tehran, Iran | ||
| 2Department of R.S. and GIS Studies, Faculty of earth sciences, Shahid Beheshti University, Tehran, Iran | ||
| 3Payam Noor University, Parand Branch, Tehran, Iran | ||
| چکیده [English] | ||
| Introduction Cut-off lows are cold -core cyclones in the upper troposphere that are identified as local minimums of geopotential elevation fields in the range of 500 and 200 hPa )Nito et al, 2008; Pinheiro et al, 2017; Muñoz et al, 2020(. Cut-off lows occur in most seasons, often in late winter and early spring. One of the synoptic patterns affecting temperature and precipitation as well as heavy rainfall in Iran is cut-off lows. This study has been compiled according to the importance and relationship between cut-off lows and heavy rainfall in the statistical period of 33 years (1986-2018). In this study, the climatology of cut-off lows systems at the level of 500 hPa of the northern hemisphere effective on heavy rainfall in Iran has been discussed. The ECMWF reanalysis data were used to identify and track cut-off lows that lasted for more than 48 hours in the statistical period of 33 years (1986-2018). For this purpose, geopotential, wind, and temperature data also were used. Materials and Methods In this study, from the average daily data: Geopotential height, wind orbit, and temperature level of 500 hPa of the re-analyzed ECMWF European site with a grid step of 0.125 * 0.125 in the statistical period of 33 years (1986-2018) Used in areas including 0 to 80 degrees north latitude and 0 to 80 degrees east longitude. The Tibaldi-Multney index was used to identify Cut-Off low. And the Cut-Off lows that were effective in Iran's heavy rainfall were studied. Results and Discussion Annual, monthly and seasonal distribution of cut-off lows during the statistical period In the statistical period of 33 years (1986-2018), a total of 632 cut-off lows with a lifespan of 2 days and more were identified. The average was 18.87 days for each year. The trend line or regression during the statistical period shows that the amount of cut-off lows is increasing. The share of cut-off lows in heavy rainfall in the four regions of Iran In the northwestern region of Iran, the highest percentage of the effect of shear compressions on heavy rainfall is in Kashan, Takab, Mahabad, Maragheh, and Tabriz stations, respectively. The lowest percentage of the impact of this phenomenon on heavy rainfall was in Khorramabad, Karaj, Babolsar, and Parsabad stations, respectively. In the southeast region, the highest percentage in Chabahar, Bandar Abbas, and Sirjan stations and the lowest percentage were in Jask, Zabol, and Khash stations. In the southwestern region, the highest effect is in Bushehr and Kish stations and the least effect is in Omidieh and Masjed Soleiman stations. In the Northeast, the highest share was in Birjand, Ferdows, and Tabas stations and the lowest impact was in Gorgan, Mashhad, Quchan, and Bojnourd stations. The amount of heavy rainfall and the effect of cut-off lows in it in different regions and Iran The highest occurrence of heavy rainfall due to cut-off lows was in the northwest region with (36.62 occurrences) and the lowest in the southeast region with (8.5 occurrences). In research study stations (76 stations), the frequency of heavy rainfall during the study period was average (124.76 events) and the effect of shear cut-off lows on heavy rainfall in total (26.1 events) in the station has been. Conclusion A total of 632 cut-off lows with a lifespan of 2 days or more were identified in the research area. The trend line of the statistical period has a slight positive and increasing slope; the most occurrences of cut-off lows is in October, March, and January. The lowest incidence of cut-off lows is in July, August, and June. Seasonally, the highest number of cut-off low events was in spring, winter, and autumn. The highest occurrence of heavy rainfall under the influence cut-off lows was in the northwest region and the lowest in the southeast region during the study period. Therefore, it can be concluded that the entry of cut-off lows from the northwest and the proximity of the northwest region to the formation location of cut-off lows may be a factor contributing to the highest frequency of heavy precipitation events influenced by cut-off lows. Furthermore, the distance of the southeast region from cut-off lows indicates a lesser impact of this phenomenon on heavy precipitation in this area. | ||
| کلیدواژهها [English] | ||
| IRAN, Heavy Rain, Jet Stream, Index (TIBALDI - MULTENI), Cut-Off Lows | ||
| مراجع | ||
|
Azizi, Q., Moradi, M. and Rezaei, H., 2017. Climatology Cut-Off Low affecting Iran and its relationship with NAO and ENSO, Geographical Research Quarterly, v. 1, p. 158-173 (In Persian). Alijani, B., 1385. Climate of Iran, Payam Noor University Press (In Persian). Naseri, N., 2016. The effect of the blocking system on Iran's rainfall, Master's thesis, Dr. Ali Shariati Faculty of Literature and Humanities, Ferdowsi University of Mashhad (In Persian). Ashraf, S., 2013. Synoptic analysis of flood systems in the Qarasu basin, Master's thesis, Faculty of Literature and Humanities, Mohaghegh Ardabili University (In Persian). Balyani, S. and Saligheh, M., 2015. Analysis and extraction of atmospheric patterns leading to daily heavy rains in the north of the Persian Gulf under study: Helleh and Mand watersheds. Spatial Analysis of Environmental Hazards, v. 3(2), p. 79-98 (In Persian). Bell, G. and Bosart, L.F., 1989. A 15-year climatology of Northern Hemisphere 500 mb closed cyclone and anticyclone centers. Mon. Wea. Rev., v. 117, p. 2142-2164, https://doi.org/10.1175/1520-0493(1989)117,2142:AYCONH.2.0.CO;2. Bozkurt, D., Rondanelli, R., Garreaud, R. and Arriagada, A., 2016. Impact of warmer eastern tropical Pacific SST on the March 2015. Atacama floods. Mon. Wea. Rev., v. 144, p. 4441-4460, https://doi.org/10.1175/MWR-D-16-0041.1. Buckley, B.W., Leslie, L.M., Sullivan, W., Leplastrier, M. and Qi, L., 2007. A rare East Indian Ocean autumn season tropical cut-off low: impacts and a high-resolution modelling study. Meteorol Atmos Phys, v. 96, p. 61-84. Davies, J.M., 2006. Tornadoes with cold core 500-mb lows. Wea. Forecasting, v. 21, p. 1051-1062, https://doi.org/10.1175/WAF967.1. Davis, J.C., 1998. Statistics and data Analysis in geology: 2nded. New Yourk: John, wily&sons. Favre, A., Hewitson, B., Tadross, M., Lennard, C. and Mota, R., 2012. Relationships between CutOff Lows and the Semiannual and Southern Oscillations, Climate Dynamics, v. 38, p. 1473-1487 Favre, A., Hewitson, B., Lennard, C., Cerezo-Mota, R. and Tadross, M., 2014. Cut-off Lows in the South Africa region and their contribution to precipitation, 14 July 2012 / Accepted: 29 October 2012 Springer-Verlag Berlin Heidelberg 2012. Fuenzalida, H.A., Sánchez, R. and Garreaud, R.D., 2005. A climatology of cutoff lows in the Southern Hemisphere. J. Geophys. Res., v. 110, D18101, https://doi.org/10.1029/2005JD005934. Griffiths, M., Reeder, M.J., Low, D.J. and Vincent, R.A., 1998. Observations of a cut-off low over southern Australia. Quart. J. Roy. Meteor. Soc., v. 124, p. 1109-1132, https://doi.org/10.1002/qj.49712454805. Haji Khani, N., 2017. The role of mid-latitude atmospheric Cut-Off Low in the continuation of daily rainfall in western Iran, Master's thesis, Faculty of Literature and Human Sciences, Razi University (In Persian). Heydari Monfard, Z., 2012. Statistical and observational analysis of hail in the northwest region of Iran, Master's thesis, Faculty of Literature and Humanities, Zanjan University (In Persian). Hirota, N.Y.N., Takayabu, M. and Arakane, S., 2016. Roles of an atmospheric river and a cutoff low in the extreme precipitation event in Hiroshima on 19 August 2014. Mon.Wea. Rev., v. 144, p. 1145-1160, https://doi.org/10.1175/MWR-D-15-0299.1. Homar, V., Gaya, M. and Ramis, C., 2001. A synoptic and mesoscale diagnosis of a tornado outbreak in the Balearic Islands. Atmos. Res., v. 56, p. 31-55, https://doi.org/10.1016/S0169-8095(00)00087-9. Kentarchos, A. and Davies, T.D., 1998. A climatology of cut-off lows at 200 hPa in the Northern Hemisphere, 1990–1994. Int. J. Climatol., v. 18, p. 379-390, https://doi.org/10.1002/(SICI)1097-0088(19980330)18:4,379::AID-JOC257.3.0.CO;2-F. Llasat, M.C., Martín, F. and Barrera, A., 2007. From the concept of ‘‘Kaltlufttropfen’’ (cold air pool) to the cut-off low. The case of September 1971 in Spain as an example of their role in heavy rainfalls. Meteor. Atmos. Phys., v. 96, p. 43-60, https://doi.org/10.1007/s00703-006-0220-9. Mohr, S., Wilhelm, J., Wandel, J., Kunz, M., Portmann, R., Punge, H.J., Schmidberger, M., Quinting, J.F. and Grams, Ch.M., 2020. The role of large-scale dynamics in an exceptional sequence of severe thunderstorms in Europe May–June 2018. Wea. Climate Dyn., v. 1, p. 325-348, https://doi.org/10.5194/wcd-1-325-2020. Muñoz, C., Schultz, D. and Vaughan, G., 2020. A midlatitude climatology and interannual variability of 200- and 500-hPa cutoff lows. J. Climate, v. 33, p. 2201-2222, https://doi.org/10.1175/JCLI-D-19-0497.1. Ndarana, Th. and Waugh, D.W., 2010. The link between cut-off lows and Rossby wave breaking in the Southern Hemisphere, Quarterly Journal of the Royal Meteorological Society Q. J. R. Meteorol. Soc., v. 136, p. 869-885, April 2010 Part B. Nieto, N., Gimeno, L., De, L., Torre, L., Ribera, P., Gallego, D., Garcíaherrera, R., García, J.A., Nuñez, M., Redaño, A. and lorente, J., 2004. Climatological Features of Cut off Low Systems in the Northern Hemisphere. Nieto, R., Gimeno, L., Torre, L., Ribera, P., Barriopedro, D., Herrera, R., Serrano, A., Gordillo, A., Redano, A. and Lorente, J., 2007. Interannual Varibility of Cut-Off Low Systems over the European Sector: The Role of Blocking and the Northern Hemisphere Circulation Modes, Meteorology and Atmospheric Physics, v. 96, p. 85-101. Nieto, R., Gimento, L., Torre, L., Ribera, P., Gallego, D., Herrera, R., Garcia, J., Nunez, M., Redano, A. and Lorente, J., 2005. Climatological Features of Cutoff Low Systems in The Northern Hemisphere, Journal of Climate, v. 18, p. 3085-3103. Nito, R., Sprenger, M., Wernli, H., Trigo, R.M. and Gimeno, L., 2008. Identification and climatology of cut-off lows near the tropopause. Ann. N. Y. Acad. Sci., v. 1146, p. 256-290, https://doi.org/ 10.1196/annals.1446.016. Nito, R., 2005. Climatological Features of cut-of-low systems, gournal of climate. Palmen, E. and Newton, C.W., 1969. Atmosphere circulation systems: New Yourk Academic press. Omidar, K., Elfati, S., Iqbali Babadi, F. and Moradi, K., 2013. Thermodynamic analysis of heavy rainfalls caused by Cut-Off Low phenomenon in the central and southwestern regions of Iran during the rainfall of 11 December 2017, Geography and Hazards Quarterly. Environment, v. 5, p. 1-19 (In Persian). Omidar, K., Safarpour, F., Mahmoodabadi, M. and Alfati, S., 2018. Collaborative analysis of the effects of Cut-Off Low in the occurrence of heavy rains in the center and southwest of Iran, Journal of Planning and Space Planning, v. 14(4), p. 161-189 (In Persian). Omidhar, K., Narangifard, M., Mahmoodabadi, M. and Fakhari Vahad, M., 2014. thermodynamic analysis and observation of exceptional spring rains and the role of cloud height in the occurrence of rains in Shiraz, The Geographical Journal of the Land, v. 12(47), p. 111-93 (In Persian). Parker S.S.J.T., Hawes, S., Colucci, J. and Hayden, B.P., 1989. Climatology of 500 mb cyclones and anticyclones 1950–85. Mon. Wea. Rev., v. 117, p. 558-571, https://doi.org/10.1175/1520-0493(1989)117,0558:COMCAA.2.0.CO;2. Pinheiro, H.R., Hodges, K.I., Gan, M.A. and Ferreira, N.J., 2017. A new perspective of the climatological features of upperlevel cut-off lows in the Southern Hemisphere, Climate Dyn., v. 48, p. 541-559, https://doi.org/10.1007/s00382-016-3093-8. Pinheiro, H.R., Hodges, K.I., Gan, M.A. and Ferreira, N.J., 2017. A new perspective of the climatological features of upperlevel cut-off lows in the Southern Hemisphere. Climate Dyn., v. 48, p. 541-559, https://doi.org/10.1007/s00382-016-3093-8. Porcu, F., Carrassi, A., Medaglia, C.M., Prodi, F. and Mugnai, A., 2007. A study on cut-off low vertical structure and precipitation in the Mediterranean region. Meteorol Atmos Phys, v. 96, p. 121-140. Pourasghar, F., Mohammadi, G.H., Soltani, M., Javanmard, S. and Omidfar, M., 2015. Synoptic analysis of Cut-Off Low of the upper levels in relation to the formation or intensification of precipitation in East Azerbaijan province in The warm period of the year, Geography and Development, v. 43, p. 171-189 (In Persian). Qi, L., Wang, Y. and Leslie, L., 2000. Numerical Simulation of a Cut-Off Low Over Southern Australia, Meteorology and Atmospheric Physics, v. 74, p. 103-115. Rasti, F. and Omidar, K., 2014. Synoptics analysis of Cut-Off Low effect on the occurrence of the heaviest rainfall in Mashhad during the statistical period of 49 years (1340-1389). The second national conference of applied researches in geography and tourism (In Persian). Rahimi, D., Atashi, N. and Bashirian, F., 2021. The effect of Bloking systems on droughts in Iran (case study: Azar and December 2013), Iran Water Resources Research, v. 17(4), p. 1-10 (In Persian). Reboita, M.S., Nieto, R., Gimeno, L., Rocha, R.P., Ambrizzi, T., Garreaud, R. and Krügger, L.F., 2010. Climatological features of cutoff low systems in the Southern Hemisphere. J. Geophys. Res., v. 115, D17104, https://doi.org/10.1029/2009JD013251. Rezaei, H., 2016. The role of Cut-Off Low in Iran's rainfall, Ph.D. dissertation in hydrology and meteorology, Faculty of Geography, University of Tehran (In Persian). Salahi, B., Ebrahimi Tabar, A., Roshanali, M. and Omidzadeh, H., 2017. An analysis of synoptic patterns of torrential rains (case study: 132 mm rainfall dated 22/7/2013 in Behshahr city), Journal Geographical Sciences, v. 29, p. 227-240 (In Persian). Samakosh, M., Soltani, J., Hanafi, M. Azizi, Gh., Mirzaei, E., Ranjbar SaadatAbadi, A. and Yousefi, Y., 2014. The omega blocking condition and extreme rainfall in Northwestern Iran during 25 - 28 October 2008. Journal of the Earth and Space Physics, v. 40(3), p. 55-74. Schumacher, R.S. and Johnson, R.H., 2008. Mesoscale processes contributing to extreme rainfall in a midlatitude warm-season flash flood. Mon. Wea. Rev., v. 136, p. 3964-3986, https://doi.org/10.1175/2008MWR2471.1. Seko, H., Kunii, M., Yokota, S., Tsuyuki, T. and Miyoshi, T., 2015. Ensemble experiments using a nested LETKF system to reproduce intense vortices associated with tornadoes of 6 May 2012 in Japan. Prog. Earth Planet. Sci., v. 2, p. 42-61, https://doi.org/10.1186/s40645-015-0072-3. Shafiei, S., 2016. Investigation of the threshold of extreme precipitation (Frein) and synoptic analysis of patterns affecting their occurrence in western Iran, Ph.D. dissertation in hydrology and meteorology (environmental risks), Humanities and Social Sciences Campus, Yazd University (In Persian). Singleton, A.T. and Reason, C.J.C., 2007. Variability in the characteristics of cut-off low pressure systems over subtropical southern Africa. Int. J. Climatol., v. 27, p. 295-310, https://doi.org/10.1002/joc.1399. Singleton, A.T. and Reason, C.J., 2007. A numerical model study of an intense cutoff low pressure system over South Africa. Mon. Wea. Rev., v. 135, p. 1128-1150, https://doi.org/10.1175/MWR3311.1. Smith, B.A. and Bosart, L.F. and Keyser, D., 2002. A global 500 hPa cutoff cyclone climatology: p. 1953-1999. Preprints, 19th Conf. on Weather Analysis and Forecasting, San Antonio, TX, Amer. Meteor. Soc., P1.14, https://ams.confex.com/ams/SLS_WAF_NWP/techprogram/paper_47082.htm. Smith, B.A. and Bosart, L.F. and Keyser, D., 2002. A global 500 hPa cutoff cyclone climatology, p. 1953-1999. Preprints, 19th Conf. on Weather Analysis and Forecasting, San Antonio, TX, Amer. Meteor. Soc., P1.14, https://ams.confex.com/ams/SLS_WAF_NWP/techprogram/paper_47082.htm. Taljaard, J., 1985. Cut-off lows in the South African region, South African Weather Bureau Technical Paper, v. 14, p. 153-168. Tsuboki, K. and Ogura, Y., 1999. A potential vorticity analysis of thunderstorm-related cold lows (in Japanese), Tenki, v. 46, p. 453-459. Wernli, H. and Sprenger, M., 2007. Identification and ERA-15 climatology of potential vorticity streamers and cutoffs near the extratropical tropopause. J. Atmos. Sci., v. 64, p. 1569-1586, https://doi.org/10.1175/JAS3912.1. Zakizadeh, M.B., Saligheh, M., Naserzadeh, M.H. and Akbari, M., 2017. Statistical and synoptic analysis of the most effective pattern of the river that causes heavy rains in Iran, Journal of Natural Environment Hazards, 7th Volume, v. 15, p. 31-48 (In Persian). Zhao, S. and Sun, J., 2007. Study on cutoff low-pressure systems with floods over Northeast Asia. Meteor. Atmos. Phys., v. 96, p. 159-180, https://doi.org/10.1007/s00703-006-0226-3.
| ||
|
آمار تعداد مشاهده مقاله: 20,491 تعداد دریافت فایل اصل مقاله: 532 |
||