تحلیل فضایی مخاطرات محیطی

تحلیل فضایی مخاطرات محیطی

واکاوی تغییرات سهم سامانه هایی با منشاء کم فشار سودانی در بارندگی دوره سرد کرانه های شمالی خلیج فارس طی سال های 1976-2017

نویسندگان
دانشگاه شهید بهشتی
چکیده
تحقیق حاضر با هدف تحلیل تغییرات طولانی مدت بارش هایی با منشاء کم فشار سودان در دوره سرد سواحل شمالی خلیج فارس می باشد. به همین منظور آمار روزانه بارش در 13 ایستگاه سینوپتیک برای چهار سیکل خورشیدی طی سال های 1976-2017 و برای سه ماه پر بارش دسامبر، ژانویه و فوریه از سازمان هواشناسی کشور دریافت شد. براساس معیار بارش بالای 5 میلیمتر در هر ایستگاه، کلیه سامانه های بارشی بدست آمد. برای روزهای دارای بارش و روز قبل تر از آن، از مرکز پیش بینی جوی- اقیانوسی ایالات متحده آمریکا داده های فشار تراز دریا و ارتفاع 1000 هکتوپاسکال دریافت شد. با روش تحلیل چشمی موقعیت جغرافیایی، شکل گیری و جابجابی سامانه های فشاری شناسایی و سامانه های سودانی از سایر سامانه های جوی جداسازی شدند. در نهایت بارش‏ها با منشاء سودانی به الگوهای یک الی هفت ‏روز تقسیم‏بندی شدند. تحلیل های همدید و آماری طی چهار دهه اقلیمی صورت گرفت. نتایج نشان داد که 77 درصد بارش دوره سرد سواحل شمالی خلیج فارس از سامانه سودانی مستقل تامین می شود. فراوانی روزهای دارای بارش سودانی در تمام ایستگاه ها طی دهه اول به دهه دوم افزایش دارد. در گذر از دهه دوم به سوم تعداد روزهای دارای بارش سودانی تغییر چشمگیری ندارد اما در دهه پایانی سهم بارش های ناشی از سامانه کم فشار سودانی به نسبت دهه های گذشته افزایش داشت. افزایش فعالیت باران زایی سامانه سودانی بمعنای تغییر اقلیم مثبت درجهت افزایش سهم سامانه سودانی در بارش های جنوب و جنوب غرب ایران می باشد.
کلیدواژه‌ها

عنوان مقاله English

Synoptic analysis of the changes trend of the share of systems due to the Sudan low In the cold period of the Persian Gulf coast during 1976-2017

نویسندگان English

Hassan Lashkari
Fahimeh Mohammadi
چکیده English





Synoptic analysis of the changes trend of the share of systems due to the Sudan low

In the cold period of the Persian Gulf coast during 1976-2017





Introduction

In the Ethiopian-Sudan range forms the low pressure system without front in the cold and transition seasons that is affecting the climate of the adjacent regions by crossing the Red sea. Based on the evidence in the context of Iran, studying Sudan low was first begun by Olfat in 1968. Olfat refers to low pressures which are formed in northeastern Africa and the Red Sea and then pass Saudi Arabia and the Persian Gulf, enter Iran, and finally, cause rainfall. The most comprehensive research specifically examining Sudan low, was the work carried out by the Lashkari in 1996. While he studying the floods that occurred in southwestern of Iran, he was identified Sudan low by the most important cause of such flooding and he explained how they are formed, and how these low-pressure systems were deployed on the southwest of Iran.



Materials and methods

The study period with long-term variations was considered from 9.5 to 11 years based on solar cycles. Precipitation data for 13 synoptic stations are considered above 5 mm in south and southwestern Iran. With three criteria were determined for the days of rainfall caused by each type of atmospheric system. The visual analysis of high and low altitude cores and geopotential height at 1000 hPa pressure level (El-Fandy, 1950a; Lashkari, 1996; 2002) were considered based on the aim of the study. Accordingly, the approximate locations of activity centers, as well as the range of the formation and displacement of the Sudan system were initially identified based on the location of the formation of low and high-pressure cores. Then, the rainy days due to the Sudan system in January were separated from the precipitation of the other atmospheric system.



Results and discussion

According to the selected criteria in the forty-year statistical period, 507 precipitation systems were identified with different continuities that led to precipitation in the northern coast of the Persian Gulf. The pattern of independent Sudan low rainfall was responsible for 77% of the precipitation in the Persian Gulf. Decade frequency share of Sudan low was lower in the first decade (16%) compared to the next three decades. This system of rainfall was more activated during the second and third decades compared to the first decade. However, rainfall changes were not evident in the mid-decade. Independent Sudan low precipitation provide 25% and 27% of the cold season precipitation of the Persian Gulf during the second and third decades respectively. In accordance with the 24th solar cycle, at the end of the study period, the Sudan low was more effective on the Gulf coast than ever before. During this decade, 125 cases of Sudan low rainfall was recorded for the Persian Gulf. Thus, the frequency of Sudan low during the fourth decade was about 31%, which was higher than in the rest of the decade. Overall, the Sudan low rainfall was repeated 151 times for 2 days rainfall, during the statistical period studied. This Precipitation has increased over the last decades compared to other periods.



Conclusion

The severe variability of rainfall along the timing and location of the permanent Persian Gulf coasts can have a significant impact on the economic and agricultural behavior of the Gulf population in the three provinces of Ahwaz, Bushehr and Hormozgan.The purpose of this study was to evaluate the precipitation changes due to Sudan low in the Persian Gulf coastal region during the cold period. The results of this study showed that the role of integration patterns in influencing the precipitation of the Persian Gulf coast has decreased with the strengthening and further activation of the Sudan low system during the last two decades. That way, about 77percent of the region's rainfall is provided by independent Sudan low. At the end of the course (in accordance with 24th solar cycle activity) the Sudan low system was more active than before. Although the Sudan low activity was different at each station during the period studied, but in the historical passage incremental and decade's positive behavior of Sudan low was common to all stations. Evaluation of changes in rainfall duration shows that the pattern of precipitation with 2days duration is more frequent than the patterns of one to several days.



Keywords: Sudan low- Solar cycle- Persian Gulf.










کلیدواژه‌ها English

Solar cycle
Cold Period
Persian Gulf
Sudan low
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