تعداد نشریات | 161 |
تعداد شمارهها | 6,532 |
تعداد مقالات | 70,501 |
تعداد مشاهده مقاله | 124,098,935 |
تعداد دریافت فایل اصل مقاله | 97,206,509 |
تحلیلی بر پُرفشارهای جنب حاره آزورس و هاوایی | ||
پژوهش های جغرافیای طبیعی | ||
دوره 52، شماره 3، مهر 1399، صفحه 409-428 اصل مقاله (2.11 M) | ||
نوع مقاله: مقاله کامل | ||
شناسه دیجیتال (DOI): 10.22059/jphgr.2020.283794.1007400 | ||
نویسندگان | ||
علی اکبر گرمسیری مهوار1؛ قاسم عزیزی* 2 | ||
1دانشجوی دکتری آب وهواشناسی، دانشکدة جغرافیا، انشگاه تهران | ||
2استاد اقلیم شناسی، گروه جغرافیای طبیعی، دانشکدة جغرافیا، دانشگاه تهران | ||
چکیده | ||
مراکز پُرفشار جنب حاره ابعاد ناشناختهای دارند. در این تحقیق، نخست سیر تحول ماهانة پُرفشارهای آزورس و هاوایی با استفاده از دادههای فشار سطح دریا و مؤلفههای مداری و نصفالنهاری باد ارائه شده است. سپس، سطح مقطع قائم جریان واچرخندی، سرعت قائم، ارتفاع ژئوپتانسیل، و واگرایی افقی در موقعیت این سامانهها تحلیل شده است. دادهها با تفکیک افقی 0.25×0.25 درجه از مرکز ECMWF و نسخة ERA5 در یک بازة زمانی چهلساله (1979 تا 2018) انتخاب شدهاند. نتایج نشان داد در جولای جریان واچرخندی و فشار سطح دریا دو عامل اساسی در شکلگیری سلولهای پُرارتفاع در ترازهای زیریناند و فرونشست هوا نقشی در شکلگیری بیشینة فشار سطح دریا و سلولهای پُرارتفاع ندارد. سلولهای پُرارتفاع در ترازهای بالاتر به سمت غرب تمایل پیدا میکنند. صعود هوای گرم و گرمای نهان آزادشده نقشی اساسی در شکلگیری زبانههای پُرارتفاع در جناح غربی دارند. اگرچه در جولای جریان واچرخندی و سلولهای پُرارتفاع در ترازهای زیرین از شدت و گرادیان بیشتری برخوردارند، الگوهای استخراجشده از کمیتهای مورد مطالعه نشان میدهند پُرفشارهای جنب حاره را نمیتوان محدود به ترازهای زیرین دانست. | ||
کلیدواژهها | ||
پُرفشار آزورس؛ پُرارتفاع؛ پُرفشار جنب حاره؛ پُرفشار هاوایی؛ واچرخند | ||
عنوان مقاله [English] | ||
An Analysis of Subtropical High Pressure Systems (Azores and Hawaiian) | ||
نویسندگان [English] | ||
Aliakbar Garmsiri mahvar1؛ Ghasem Azizi2 | ||
1Department of Physical Geography, Faculty of Geography, University of Tehran | ||
2Department of Physical Geography, Faculty of Geography, University of Tehran | ||
چکیده [English] | ||
Introduction: Subtropical high pressure systems are among the atmospheric large scale centers of action in the northern hemisphere in the east of the oceans. The high pressure in the Atlantic called "Azores" or "Bermuda" and in the Pacific called "Hawaii". The clockwise flow around these systems in the south comes from easterly trade winds and in the north from the westerly belt of the mid-latitudes. Both of these currents are influential in the formation and development of this systems. Surface pressure and clockwise flow in these systems reach the maximum in the warm season, especially in July. While at this time there are thermal low pressures on most continental. For the first time Bergeron (1930) in context of air mass and frontal development argue that a surface high pressure belt exist in the subtropics around the earth. This belt has generally been attributed to the descent in the pole-ward branch of the meridionally overturning Hadley Cell. Bjerknes (1935) argued for such a belt structure from “stability considerations,” and discussed the organization of the subtropical anticyclones, including continentally anchored cols. Rodwell and Hoskins (2001) emphasize that the zonal-mean of the Hadley Cell in the summer of the northern hemisphere is much weaker than in the summer of the Southern Hemisphere, and that the circulation is not strong enough to produce the observed summer peaks of the intensity of the subtropical high pressure. Therefore, the classical Theory of the Hadley Cell Theory not be able to describe the existence of the maximum sea level pressure at the sub-tropic of the northern hemisphere. Study of this systems that affecting the oceans and continents in the hot season requires analyzing many phenomena in the atmosphere. These include the Hadley meridional circulation, warming in the atmosphere, monsoon events on the continents, and latent heat released in the upper levels of the atmosphere and etc. The structure and mechanism of each of these phenomena are also complex. Therefore, it is not possible to address many of the above in the context of research at this level. Internal investigations do not seem to have much tangible and close relevance to subtropical high-pressure systems. These studies are based on the geopotential pattern in different levels, and most of the studies focus on seasonal variations, displacement, and the relationship of this pattern to other atmospheric phenomena. While a fundamental question arises in the mind, "how much this quantity depends on the mechanism of subtropical high pressure systems and whether the formation of geopotential patterns can be related to the subtropical high pressure systems or their origin?" This study attempts to provide a convincing answer and analysis based on the findings and foundations. Material and method: In this research, sea level pressure, wind vector, omega, geopotential height and horizontal divergence are used. Initially, the monthly mean of sea level pressure and wind vector averages at 6 levels (700, 750, 775, 800, 825, 850 hPa) in the North Atlantic and North Pacific were analyzed. Sea level pressure in has been used as a measure of the intensity, development, and displacement of subtropical high pressure systems. The mean wind in the above 6 levels is also used as a current in these systems. Due to the high resolution of the data, the wind cannot be represented in vector form and this quantity is presented as stream lines. Monthly intensities and displacements of high-pressure centers on the North Atlantic and Pacific are investigated based on the maximum monthly mean sea level pressure. In the second part, in order to identify the extent and subsidence of these systems, the pattern of the vertical cross section of the meridional wind and omega is investigated at the position of these systems. Finally, the vertical cross-section of geopotential height and horizontal velocity divergence in the position of these systems in July is analyzed. To better understand and analyze these systems, the study was conducted in hot (April to September) and cold (October to March) periods. The data were extracted from the European Center for Medium-Range Forecasts (ECMWF) and the ERA5 version with a horizontal resolution of 0.25 * 0.25 degrees. This data is a reanalysis of stationary data and outputs of numerical models. Monthly averages of quantities used over a 40 year period from 1979 to 2018. result and Discussion In July, at the sea level the center of the Anticyclone corresponds to the maximum of pressure and at higher levels corresponds to the maximum of Geopotential height. Therefore, the counter clockwise flow and sea level pressure are the two main factors in the formation of height cells in the lower levels. Another point is that the maximum sea level pressure and the height of the geopotential at the lower levels do not correspond to the maximum divergence and subsidence of the air, respectively. Therefore, on the one hand, the subsidence of air flow cannot be considered as the main factor for the formation of maximum sea surface pressure, and on the other hand, the idea of the effect of adiabatic heating due to subsidence in the formation of height cells is negated. At this time, the maximum height of the Geopotential at the upper levels occurs on the western flank of Anticyclone. The ascent of hot air and the latent heat released on the western flank are the main factors in formation the maximum height or ridge in this area. The extent status of Anticyclone in July exhibits prominent patterns of counter clockwise flow, sea level pressure, geopolitical height, ascent and descent of air, divergence, warm and cold advection, and other atmospheric quantities. These patterns show the effects of these systems on the wide thickness of the atmosphere. conclusion In this study, an attempt is made to display a more comprehensive analysis of the structure of Subtropical High Pressure Systems (Azores and Hawaii) using atmospheric data, which will certainly be effective in our knowledge and analysis of Anticyclone systems on continents. This study includes variability and vertical cross-section of flow, vertical velocity, divergence and geopotential height in these systems. It seems necessary to distinguish between Azores high-pressure and upper level atmospheric high systems with anticyclonic rotation. | ||
کلیدواژهها [English] | ||
"Azores High pressure", "Anticyclone", "Subtropical high pressures ", Hawaiian high pressure" | ||
مراجع | ||
حجازیزاده، ز. (1372). بررسی نوسانات فشار زیاد جنب حاره در تغییر فصل ایران، رسالة دکتری جغرافیای طبیعی، دانشگاه تربیت مدرس. زرین، آ. (1386). تحلیل پُرفشارهای جنب حارة تابستانه بر روی ایران، رسالة دکتری جغرافیای طبیعی، دانشگاه تربیت مدرس. زرین، آ. و مفیدی، ع. (1390). آیا پُرفشار جنب حارهای تابستانه بر روی ایران زبانهای از پُرفشار جنب حارهای آزور است بررسی یک نظریه، یازدهمین کنگره جغرافیدانان ایران، تهران، انجمن جغرافیایی ایران، دانشگاه شهید بهشتی. عساکره، ح.؛ قائمی، ه. و فتاحیان، م. (1395). اقلیمشناسی مرز پشتة پُرفشار جنب حاره بر روی ایران، نشریة پژوهشهای اقلیمشناسی، 7(25 و 26): 21-32. قائمی، ه.؛ زرین، آ.؛ آزادی، م. و فرجزاده اصل، م. (1388). تحلیل الگوی فضایی پُرفشار جنب حاره بر روی آسیا و افریقا، فصلنامة مدرس علوم انسانی، 13(1): 219-245. لشکری، ح. و محمدی، ز. (1394). اثر موقعیت استقرار پُرفشار جنب حارة عربستان بر سامانههای بارشی در جنوب و جنوب غرب، پژوهشهای جغرافیای طبیعی، 47(1): 73-90. Anderson, DL. and Gill, AE. (1975). Spin-up of a stratified ocean, with applications to upwelling. Deep-Sea Res. 1975 Jan 1, 22(9): 583-596. Asakereh, H.; Ghaemi, H. and Fatahian, M. )2016(. Climatology Study of Subtropical High Pressure Ridge on Iran, Journal of climatological research, 7(25-26): 21-32. Bergeron, T. (1930). Richtlinien einer dynamischen Klimatologie. Meteorologische Zeitschrift, 47(7): 246-262. Bjerknes, J. (1935). La circulation atmosphérique dans les latitudes sous-tropicales. Chan, S. C. (2008). On the summer time development of the North Pacific Sea-level Pressure Anticyclone (Doctoral dissertation). Chen, P.; Hoerling, M. P. and Dole, R. M. (2001). The origin of the subtropical anticyclones. Journal of the atmospheric sciences, 58(13): 1827-1835. Ghaemi, H.; Zarin, A.; Azadi, M. and Farajzadehasl, M. (2009). Spatial Analysis of Subtropical High Pressure over Asia and Africa. Journal of Human Sciences MODARES, 13(1): 219-245. Gyakum, J. R.; Anderson, J. R.; Grumm, R. H. and Gruner, E. L. (1989). North Pacific cold-season surface cyclone activity: 1975–1983. Monthly weather review, 117(6): 1141-1155. Hejazizadeh, Z. (1993). Investigation of Subtropical High Pressure Fluctuation in Iran Season Change, Doctoral dissertation, Natural Geography, Tarbiat Modarres University. Hoerling, M. P.; Hurrell, J. W. and Xu, T. (2001). Tropical origins for recent North Atlantic climate change. Science, 292(5514): 90-92. Hoskins, B. J. (1996). On the existence and strength of the summer subtropical anticyclones. Bull. Amer. Meteor. Soc., 77: 1287-1292. Kapala, A.; Mächel, H. and Flohn, H. (1998). Behavior of the centers of action above the Atlantic since 1881. Part II: Associations with regional climate anomalies. International Journal of Climatology, 18(1): 23-36. Lahey, J. F.; Bryson, R. A. and Wahl, E. W. (1958). Atlas of five-day normal sea-level pressure charts for the Northern Hemisphere. University of Wisconsin Press. Liu, Y.; Wu, G. and Ren, R. (2004). Relationship between the subtropical anticyclone and diabatic heating. Journal of Climate, 17(4): 682-698. Lashkari, H. and Mohammadi, Z. (2015). The Role of Saudi Arabia Subtropical High Pressure Position on Precipitation Systems in the South and Southwest of Iran, Journal of Physical Geographical Research, 47(1): 73-90. Mächel, H.; Kapala, A. and Flohn, H. (1998). Behavior of the centers of action above the Atlantic since 1881. Part I: Characteristics of seasonal and interannual variability. International Journal of Climatology, 18(1): 1-22. Nigam, S. and Chan, S. C. (2009). On the summertime strengthening of the Northern Hemisphere Pacific sea level pressure anticyclone. Journal of Climate, 22(5): 1174-1192. Norris, J. R. (1998). Low cloud type over the ocean from surface observations. Part I: Relationship to surface meteorology and the vertical distribution of temperature and moisture. Journal of Climate, 11(3): 369-382. Oort, A. H. and Yienger, J. J. (1996). Observed interannual variability in the Hadley circulation and its connection to ENSO. Journal of Climate, 9(11): 2751-2767. Rodionov, S. N.; Overland, J. E. and Bond, N. A. (2005). A: Spatial and temporal variability of the Aleutian climate. Fisheries Oceanography, 14, 3-21. Rodionov, S. N.; Overland, J. E. and Bond, N. A. (2005). The Aleutian low and winter climatic conditions in the Bering Sea. Part I: Classification. Journal of Climate, 18(1), 160-177. Rodwell, M. J. and Hoskins, B. J. (2001). Subtropical anticyclones and summer monsoons. Journal of Climate, 14(15): 3192-3211. Rodwell, M. J. and Hoskins, B. J. (1996). Monsoons and the dynamics of deserts, QJ Roy. Meteor. Soc., 122: 1385-1404. Seager, R.; Murtugudde, R.; Naik, N.; Clement, A.; Gordon, N. and Miller, J. (2003). Air–sea interaction and the seasonal cycle of the subtropical anticyclones. Journal of climate, 16(12): 1948-1966. Serreze, M. C.; Carse, F.; Barry, R. G. and Rogers, J. C. (1997). Icelandic low cyclone activity: Climatological features, linkages with the NAO, and relationships with recent changes in the Northern Hemisphere circulation. Journal of Climate, 10(3): 453-464. Walker, G. T. Y EW Bliss, (1932). World weather V, Men. Roy. Meteor. Soc., 4: 53-84. WU, G.; LIU, Y. and LIU, P. (2004). Formation of the summertime subtropical anticyclones. InEast Asian Monsoon (pp. 499-544. Zarin, A. (2007). Analysis of Summertime Subtropical High Pressure over Iran, Doctoral dissertation, Natural Geography, Tarbiat Modarres University. Zarin, A. and Mofidi, A. (2001). Is summertime subtropical High in Iran a tongue of Azores High? a Theory Review, 11th Congress of Iranian Geographers, Tehran, Iran Geographical Association, Shahid Beheshti University. | ||
آمار تعداد مشاهده مقاله: 1,098 تعداد دریافت فایل اصل مقاله: 546 |