Wu,GX et al,2012-Sci.Thermal Controls on the Asian Summer Monsoon
汽车发动机冷却风扇智能控制系统的研究
汽车发动机冷却风扇智能控制系统的研究
杨文荣;朱鹏
【期刊名称】《微计算机信息》
【年(卷),期】2009(25)2
【摘要】在汽车电子快速发展的大背景下,为了保证发动机能够安全、自由灵活的运行,本文设计了一个自身具有故障检测功能的新型智能冷却风扇控制系统.本系统采用PIC16F716单片机作为微处理器芯片,在采集发动机工作环境温度的同时,采集此时发动机送来的工作状态信号,由微处理器综舍运算后,送出PWM输出信号,对冷却风扇进行调速,达到及时且非常可靠的控制效果.另外,本系统还专门设计了检测风扇自身的各种常见故障的硬件电路及其运行程序,以保证冷却风扇能够安全且无故障的运行,并最终为发动机的安全运行提供保障.
【总页数】3页(P245-247)
【作者】杨文荣;朱鹏
【作者单位】2110072,上海,上海大学微电子研究与开发中心;2110072,上海,上海大学微电子研究与开发中心
【正文语种】中文
【中图分类】TP368
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1.汽车发动机电动冷却风扇智能控制系统研制 [J], 彭菊生;潘法宝
2.汽车发动机电动冷却风扇控制系统的研究 [J], 郭新民;邢娟
3.基于汽车发动机电动冷却风扇智能控制的研究 [J], 董国贵;尹爱勇
4.汽车发动机电动冷却风扇控制系统的研究 [J], 郭新民;邢娟
5.汽车发动机电动冷却风扇智能控制系统设计 [J], 余海洋;曹志良;刘绍波
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细胞凋亡相关的信号通路
细胞凋亡相关的信号通路李晓婷【摘要】目前研究较多的细胞凋亡信号通路有wnt及JNK两条.Wnt信号通路有经典wnt通路,wnt/PCP通路和wnt/钙离子通路三个分支,引起细胞凋亡的机制主要有β-连环蛋白/tcf的转录调节途径,APC激活途径两种.JNK信号通路通过MKKKs-MKKs-MAPK转导.激活的JNK信号通路通过磷酸化转录因子、细胞骨架相关蛋白、酶等多种底物来调节细胞的生理过程,最终导致细胞凋亡.【期刊名称】《四川解剖学杂志》【年(卷),期】2013(021)001【总页数】3页(P25-27)【关键词】细胞凋亡;Wnt;JNK【作者】李晓婷【作者单位】四川大学基础医学与法医学院,成都610041;乐山职业技术学院,乐山614000【正文语种】中文【中图分类】R655细胞凋亡,1972年由Kerr提出,指的是细胞在一定条件下接受刺激信号并且受基因调控的一种自主性、程序性的死亡过程。
从20世纪80年代末开始,其就成为肿瘤学、病因学的研究热点,人们对其认识越来越深入,对其发生的分子机理了解的也越来越透彻。
本文就对目前研究较多的两种介导细胞凋亡的信号通路作一综述。
1 wnt信号通路1.1 wnt信号途径的组成Wnt基因从小鼠的乳腺肿瘤被发现后,最初被命名为int-1,经研究表明,它是果蝇的无翅基因(wng)在小鼠中的同源基因。
wng基因是最初在果蝇中发现的发育调控基因,后来将wng与int-1结合,提出了wnt基因的称谓[1]。
wnt 基因在胚胎细胞的发育中起着重要的作用,其所调控的信号传导系统即wnt信号途径。
同其它的细胞间信号传导途径一样,它也是由一种分泌的信号蛋白、跨膜受体蛋白以及复杂的胞内多种蛋白将信号由细胞表面传导至细胞核内[2]。
目前较公认的wnt信号通路至少有三个分支:1)经典 wnt通路,又叫 wnt/β-catenin通路,该通路被激活后将导致胞质内β-catenin的稳定和积累,随后进入细胞核内激活靶基因的表达[3]。
Wu et al.,2015-Revised Ti-in-biotite geothermometer for ilmenite- or rutile-bearing
Article Earth ScienceRevised Ti-in-biotite geothermometer for ilmenite-or rutile-bearing crustal metapelitesChun-Ming Wu •Hong-Xu ChenReceived:1July 2014/Accepted:19September 2014/Published online:19December 2014ÓScience China Press and Springer-Verlag Berlin Heidelberg 2014Abstract In the present study,the Ti-in-biotite geother-mometer was revised using more than 300natural rutile-or ilmenite-bearing metapelites collected worldwide.The formulation was empirically calibrated as ln ½T ð C Þ ¼6:313þ0:224ln ðX Ti ÞÀ0:288ln ðX Fe ÞÀ0:449ln ðX Mg Þþ0:15P ðGPa Þ,with X j ¼j =ðFe þMg þAl VI þTi Þin biotite,assuming ferric iron content of 11.6mol%of the total iron in biotite.This thermometer is consistent with the well-calibrated garnet–biotite thermometer within error of ±50°C for most of the calibrant samples and can successfully distin-guish systematic temperature changes of different meta-morphic zones in both prograde and inverted metamorphic terranes as well as thermal contact aureoles.Thus,the thermometer truthfully reflects real geologic conditions and can be applied to TiO 2-saturated metapelites metamor-phosed at the crustal level within the calibration ranges (450–840°C,0.1–1.9GPa,X Ti =0.02–0.14in biotite).Keywords Ti content ÁBiotite ÁCalibration ÁGeothermometer ÁApplication ÁError1IntroductionThe development of valid geothermobarometers has been a crucial component of petrologic research for more than80years.Metapelites,in particular,are quite sensitive to metamorphic pressure–temperature (P –T )conditions,and metapelitic mineral assemblages typically record the tectono-metamorphic evolution of metamorphic terranes.Therefore,thermobarometers applicable to metapelites are powerful tools in retrieving information about metamorphic processes.Such geothermobarometers include the valid garnet–biotite thermometer [1],the garnet–Al 2SiO 5–plagioclase–quartz (GASP)barometer [2],the garnet–biotite–plagioclase–quartz (GBPQ)barometer [3],the garnet–muscovite–plagioclase–quartz (GMPQ)thermobarometers [4],and the garnet–bio-tite–muscovite–Al 2SiO 5–quartz (GBMAQ)barometer [5].In fact,constructing concise and easily used monomi-neralogic thermobarometers is a priority for petrologists,which has led to development of the hornblende thermoba-rometer [6,7],the Si-in-phengite geobarometer [8,9],and the Ti-in-biotite geothermometer [10,11].The Ti-in-biotite geothermometer is extremely useful in deciphering the metamorphic temperatures of metapelites,especially when garnet is absent in TiO 2-saturated rocks.However,further work is required for this thermometer,particularly owing to the limited ranges of calibration P –T conditions and chem-ical compositions of biotites.In the present study,the Ti-in-biotite thermometer was revised based on abundant me-tapelitic samples collected worldwide;then,the applicability of the thermometer was tested by applying it to prograde and inverted metamorphic terranes and thermal contact aureoles.2Calibration of the Ti-in-biotite geothermometer 2.1Calibration data setIn total,334rutile-and/or ilmenite-bearing natural me-tapelitic samples collected worldwide were collated basedElectronic supplementary material The online version of this article (doi:10.1007/s11434-014-0674-y )contains supplementary material,which is available to authorized users.C.-M.Wu (&)ÁH.-X.ChenCollege of Earth Science,University of Chinese Academy of Sciences,Beijing 100049,China e-mail:wucm@Sci.Bull.(2015)60(1):116– DOI 10.1007/s11434-014-0674-y /scpon the existing literature.Of these,24samples (7%of the total data)were discarded owing to possible disequilib-rium;the remaining 310samples were used in the cali-bration.These data are given in Table S1.For graphite-or ilmenite-bearing metapelites,the ferric contents of garnet and biotite were estimated to be 3%and 11.6%,respec-tively,of the total iron [1].These rocks were metamor-phosed under P –T conditions of 450–840°C and 0.1–1.9GPa,respectively,determined simultaneously by applying the garnet–biotite geothermometer [1]and the GASP geobarometer [2],as suggested by Wu and Cheng [12].The chemical ranges are X Fe =0.19–0.55,X Mg =0.23–0.67,and X Ti =0.02–0.14for biotites,on the basis of 11oxygen per formula unit,in which X j ¼j =ðFe þMg þAl VI þTi Þin biotite.It should be stated that such compositional ranges cover more than 98%of the natural biotites in rutile-or ilmenite-bearing metapelites.2.2Calibration of the thermometerHenry and Guidotti [10]and Henry et al.[11]found that there exists a curved Ti-saturation surface in the T –Ti–Mg#space and fitted T ,Ti atoms,and Mg#½¼Mg =ðMg þFe Þ of biotites to an exponential equation,as the Ti-in-biotite thermometer.The empirical formulations (Eqs.1and 2)of their thermometers are described as ln ðTi Þ¼À2:3353þ4:343Â10À9½T ð C Þ 3À1:6718ðMg#Þ3;ð1Þandln ðTi Þ¼À2:3594þ4:6482Â10À9½T ð C Þ 3À1:7283ðMg#Þ3;ð2Þrespectively,on the 22-O basis of biotite.These previous studies demonstrated that the precision of the thermometer is around ±25°C.However,their calibration data were metapelitic samples collected from western Maine and metamorphosed under pressure condi-tions of 0.33GPa [10]and collected from both western Maine and south-central Massachusetts [11]and meta-morphosed under pressure conditions of 0.4and 0.6GPa,respectively,at almost constant pressure conditions.We found that another type of regression model can better describe the temperature dependence of the Ti con-tents of biotites;thus,the Ti-in-biotite geothermometer (Eq.3)was empirically calibrated through multiple regression analysis as follows:ln T C ðÞ½ ¼6:313Æ0:078ðÞþ0:224Æ0:006ðÞln X Ti ðÞÀ0:288Æ0:041ðÞln X Fe ðÞÀ0:449Æ0:039ðÞÂln X Mg ÀÁþ0:15Æ0:01ðÞP GPa ðÞ;ð3Þwith a multiple correlation coefficient of R =0.906obtained when fitting the calibrant data set listed in Table S1.It should be noted that the present formulation is only empirical and lacks strict thermodynamic and crystallo-graphic bases;however,it is valid and practical in the applications described hereafter.2.3Error analysisThe present Ti-in-biotite thermometer (Eq.3)yields similar temperatures to the garnet–biotite thermometer [1]within error of ±50°C for 72%of the total 310calibrant samples (Fig.1a).In contrast,the Ti-in-biotite thermometer of Henry et al.[11]typically overestimates temperatures (Fig.1b)compared to the garnet–biotite thermometer [1].The garnet–biotite thermometer [1]is the most precise and accurate of all thermometers used in metapelites [12].Therefore,we evaluated the accuracy of the present Ti-in-biotite thermometer by comparing the temperature differ-ences between these two thermometers and defined this as the random error of the Ti-in-biotite thermometer.Our results show that the random error of this thermometer is nearly independent of both temperature (Fig.1c)and pressure (Fig.1d)or the chemical compositions of biotites (Fig.1e–g),suggesting that the random error of the new Ti-in-biotite thermometer is evenly distributed,without any bias.Based on the calibrant data set (Table S1),the following statements can be made:(a)an error of ±0.2GPa of input pressure translates to a temperature error of ±14–25°C and (b)analytical error of ±2%for the Ti,Fe,and Mg contents in biotites may translate to temperature errors of ±2–4°C,±1–3°C,and ±1–5°C,respectively.Thus,the random error of this new thermometer was arbitrarily estimated to be ca.±65°C,when considering both for reproduction of calibration temperatures and for applica-tions to natural metamorphic terranes.The absolute error of the present Ti-in-biotite thermometer could not be evalu-ated owing to a shortage of experimental data.3Applications of the Ti-in-biotite geothermometer A valid thermometer should be able to accurately distin-guish systematic temperature changes of different zones in prograde or inverted metamorphic terranes and in thermal contact aureoles,as suggested by Wu and Cheng [12]when evaluating the validity of the garnet–biotite thermometers.The present Ti-in-biotite thermometer has been applied to such metamorphic regions worldwide (Table S2),and it has been demonstrated that this thermometer both reflectssystematic temperature changes and yields similar(but some slightly lower)temperature estimates(Fig.2)to the garnet–biotite geothermometer[1].It appears that the present Ti-in-biotite thermometer (Eq.3)is superior to that of Henry et al.[11];in particular, the latter cannot reflect temperature increases between some neighboring metamorphic zones(Fig.2a,c–e,h).It should be noted that these two Ti-in-biotite thermometers have erroneously indicated temperature decrease from the higher kyanite–biotite zone to the sillimanite zone of the inverted metamorphic terrane in the western metamorphic belt,Juneau,Alaska[17],and from zone7to zone8of the regional thermal contact aureoles of west-central Maine [20].However,the causes of these errors remain unknown. 4DiscussionThe temperature dependence of the Ti contents of me-tapelitic biotites has long been recognized,although the reasons for this dependence are relatively complex.Henry and Guidotti[10]and Henry et al.[11]argued that the coupled cation–cation exchanges in biotites,including 2VI R2þ¼VI TiþVI h,2VI Al¼VI TiþVI R2þ,VI R2þþ2IV Si¼VI Tiþ2IV Al,and VI R2þþ2OHÀ¼VI Tiþ2O2À, may be the mechanisms by which Ti atoms are incorpo-rated into biotite solution.However,it has been shown that no one cation exchange reaction is solely responsible for the temperature effect illustrated by Fig.8of Henry et al.[11],suggesting that the Ti-in-biotite thermometer merits further study.In their derivation,Henry et al.[11]used graphitic, aluminous,biotite-bearing metapelitic samples from wes-tern Maine and south-central Massachusetts,with input temperatures determined based on locations of isograd reactions and dehydration melting reactions calibrated against the petrogenetic grid of Spear et al.[21]at pres-sures of0.4and0.6GPa,respectively.Although Henry and Guidotti[10]and Henry et al.[11]acknowledged that Ti contents of biotites are negatively related to pressure,their formulations contained no pressure item owing to the narrow pressure range of their calibrant samples.On the contrary,we found that the Ti contents of biotites are positively related to pressure,and pressure is included in the present formulation.Another possible reason for the superiority of the new Ti-in-biotite thermometer is the splitting of the Mg#½=Mg/(MgþFe)]item into two items,i.e.,X Fe and X Mg,in our regression analysis.However,a strict theoretical basis for the superiority remains elusive at present.Accordingly, it should be noted that the new formulation is merely an empirical equation,although it deserves further calibration in the future and can be applied already in certain situations.5ConclusionsThe calibration P–T ranges(450–840°C,0.1–1.9GPa)of the Ti-in-biotite geothermometer were broadened tofit greenschist to granulite facies,TiO2-saturated,rutile-and/ or ilmenite-bearing metapelites.This thermometer not only yields similar temperature estimates to the well-calibrated garnet–biotite thermometer,but also clearly distinguishes systematic temperature changes in different zones of pro-grade or inverted metamorphic regions and thermal contact aureoles.The random error of this thermometer has been shown to be no more than approximately±65°C. Acknowledgements This work was supported by the National Natural Science Foundation of China(41225007).Conflict of interest The authors declare that they have no conflict of interest.References1.Holdaway MJ(2000)Application of new experimental and garnetMargules data to the garnet-biotite geothermometer.Am Mineral 85:881–8922.Holdaway MJ(2001)Recalibration of the GASP geobarometer inlight of recent garnet and plagioclase activity models and ver-sions of the garnet-biotite geothermometer.Am Mineral 86:1117–11293.Wu CM,Zhang J,Ren LD(2004)Empirical garnet-biotite-pla-gioclase-quartz(GBPQ)geobarometry in medium-to high-grade metapelites.J Petrol45:1907–19214.Wu CM,Zhao GC(2006)Recalibration of the garnet-muscovite(GM)geothermometer and the garnet-muscovite-plagioclase-quartz(GMPQ)geobarometer for metapelitic assemblages.J Petrol47:2357–23685.Wu CM,Zhao GC(2007)The metapelitic garnet-biotite-mus-covite-aluminosilicate-quartz(GBMAQ)geobarometer.Lithos 97:365–3726.Gerya TV,Perchuk LL,Triboulet C et al(1997)Petrology of theTumanshet zonal metamorphic complex,eastern Sayan.Petrol 5:503–5337.Zenk M,Schulz B(2004)Zoned Ca-amphiboles and related P-T evolution in metabasites from the classical Barrovian meta-morphic zones in Scotland.Mineral Mag68:769–7868.Massonne H-J,Schreyer W(1987)Phengite geobarometry basedon the limiting assemblage with K-feldspar,phlogopite,and quartz.Contrib Mineral Petrol96:212–2249.Massonne H-J,Schreyer W(1989)Stabilityfield of the high-pressure assemblage talc?phengite and two new phengite barometers.Eur J Mineral1:391–41010.Henry DJ,Guidotti CV(2002)Titanium in biotite from me-tapelitic rocks:temperature effects,crystal-chemical controls, and petrologic applications.Am Mineral87:375–38211.Henry DJ,Guidotti CV,Thomson JA(2005)The Ti-saturationsurface for low-to-medium pressure metapelitic biotites:impli-cations for geothermometry and Ti-substitution mechanisms.Am Mineral90:316–32812.Wu CM,Cheng BH(2006)Valid garnet-biotite(GB)geother-mometry and garnet-aluminum silicate-plagioclase-quartz (GASP)geobarometry in metapelitic rocks.Lithos89:1–23 13.Huang MH,Buick IS,Hou LW(2003)Tectonometamorphicevolution of the eastern Tibet Plateau:evidence from the central Songpan-Garzeˆorogenic belt,western China.J Petrol44: 255–27814.Weller OM,St-Onge MR,Waters DJ et al(2013)QuantifyingBarrovian metamorphism in the Danba structural culmination of eastern Tibet.J Meta Geol31:909–93515.Rı´os C,Garcı´a C,Takasu A(2003)Tectono-metamorphic evo-lution of the Silgara´formation metamorphic rocks in the south-western Santander Massif,Colombian Andes.J S Am Earth Sci 16:133–15416.Ferry JM(1981)Petrology of graphitic sulfide-rich schists fromsouth-central Maine:an example of desulfidation during prograde regional metamorphism.Am Mineral66:908–93017.Himmelberg GR,Brew DA,Ford AB(1991)Development ofinverted metamorphic isograds in the western metamorphic belt, Juneau,Alaska.J Meta Geol9:165–18018.Mezger JE,Chacko T,Erdmer P(2001)Metamorphism at a latemesozoic accretionary margin:a study from the Coastal Belt of the North American Cordillera.J Meta Geol19:121–13719.Novak JM,Holdaway MJ(1981)Metamorphic petrology,min-eral equilibria,and polymetamorphism in the Augusta quadran-gle,south-central Maine.Am Mineral66:51–6920.Holdaway MJ,Dutrow BL,Hinton RW(1988)Devonian andCarboniferous metamorphism in west-central maine:the musco-vite-almandine geobarometer and the staurolite problem revis-ited.Am Mineral73:20–4721.Spear FS,Kohn MJ,Cheney JT(1999)P-T paths from anatecticpelites.Contrib Mineral Petrol134:17–32。
GLP-1早期应用 多重获益
新诊断T2DM患者使用艾塞那肽 对体重和腰围有显著获益
腰围相对基线变化(cm)
体重相对基线变化(kg)
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EXE:艾塞那肽 MET:二甲双胍
一项26周、随机、二甲双胍对照、平行对照研究,纳入59例新诊断肥胖2型糖尿病 患者,随机接受艾塞那肽或二甲双胍治疗。
GAO Yan,et al.Chinese Medical Journal 2012;125(15):2677-2681
GAO Yan,et al.Chinese Medical Journal 2012;125(15):2677-2681
胰岛素生成指数变化(IGI30,IU/mol)
早期使用艾塞那肽,多重获益
• 强效控糖 – 及时纠正早期高血糖 – 改善β细胞糖毒性 • 减重、减少低血糖风险 – 对体重和腰围有获益 – 减少夜间低血糖 – 体重管理和低血糖风险控制利于减少CV风险
葡萄糖摄取 胰岛素敏感性 胃排空 白蛋白排泄
Front Endocrinol (Lausanne). 2013 Jun 18;4:73. doi: 10.3389/fendo.2013.00073. eCollection 2013.
早期使用艾塞那肽,多重获益
• 强效控糖 – 及时纠正早期高血糖 – 改善β细胞糖毒性
李光伟,宁光,周智广.中华内分泌代谢杂志.2006;22(4):309-312
新诊断T2DM患者艾塞那肽治疗6个月 显著改善胰岛分泌功能及葡萄糖敏感性
安慰剂
胰岛素分泌率 胰岛素分泌率
艾塞那肽5mcg
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艾塞那肽10mcg
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2012年最新JCR期刊影响因子及分区情况(中科院SCI期刊分区表)-农林科学类
阈值期刊数期刊数2.4532260序号12345678910111213141516171819202122232425262728293031323334353637383940414243 440167-5877PREV VET MED2PREVENTIV 0178-2762BIOL FERT SOILS2BIOLOGY A 1049-8001INT J WILDLAND FIRE2INTERNATIO 0706-652X CAN J FISH AQUAT SCI2CANADIAN 0378-1127FOREST ECOL MANAG2FOREST E 1351-0754EUR J SOIL SCI2EUROPEAN 1054-6006FISH OCEANOGR2FIS 0891-6640J VET INTERN MED2JOURNAL O 1869-215X AQUACULT ENV INTERAC2Aquacultu 1746-6148BMC VET RES2BMC Veter 1526-498X PEST MANAG SCI2PEST MA 0931-2250J AGRON CROP SCI2JOURNAL O 0191-2917PLANT DIS2PLANT 0929-1393APPL SOIL ECOL2APPLIED S 0925-5214POSTHARVEST BIOL TEC2POSTHARV 0016-7061GEODERMA2GEO 0926-6690IND CROP PROD2INDUSTRIA 0378-4290FIELD CROP RES2FIELD CRO 0304-4017VET PARASITOL2VETE 0021-8812J ANIM SCI2JOURNA 1161-0301EUR J AGRON2EUROPEAN 1380-3743MOL BREEDING2MOLECUL 0167-1987SOIL TILL RES1SOIL & 1090-0233VET J1VETERINA 0829-318X TREE PHYSIOL1TREE P 0022-0302J DAIRY SCI1JOURNA 0308-521X AGR SYST1AGRICULTU 1084-2020ILAR J1ILAR 1774-0746AGRON 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2012年最新JCR期刊影响因子及分区情况(中科院SCI期刊分区表)-医学类
1
14.662
14.739
33
1
14.378
13.853
34
00219738
J CLIN INVEST
1
35
00278874
J NATL CANCER I
1
36 37
08966273 0959535X
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16.733
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16.373
17.391
28
1
14.979
16.269
29
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14.773
16.129
30
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13.668
31
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2012年SCI期刊中科院分区表-全学科
2
33
02787407 18711014 18115209
2
34
2
35
2
36
15252027
2
37
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2012年最新JCR期刊影响因子及分区情况(中科院SCI期刊分区表)-物理
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3.308
3.398
2.614
3.276
2.806
3.259
3.399
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3.631
3.184
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3.149
3.32
42
03770486
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57
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2.614
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Thermal Controls on the Asian Summer MonsoonGuoxiong Wu 1,Yimin Liu 1,Bian He 1,2,Qing Bao 1,Anmin Duan 1&Fei-Fei Jin 31State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics,Institute of Atmospheric Physics,Chinese Academy of Sciences,2Nanjing University of Information Science &Technology,3Department of Meteorology,University of Hawaii,Honolulu,Hawaii,USA.The Asian summer monsoon affects more than sixty percent of the world’s population;understanding its controlling factors is becoming increasingly important due to the expanding human influence on the environment and climate and the need to adapt to global climate change.Various mechanisms have been suggested;however,an overarching paradigm delineating the dominant factors for its generation and strength remains debated.Here we use observation data and numerical experiments to demonstrates that the Asian summer monsoon systems are controlled mainly by thermal forcing whereas large-scaleorographically mechanical forcing is not essential:the South Asian monsoon south of 206N by land–sea thermal contrast,its northern part by the thermal forcing of the Iranian Plateau,and the East Asianmonsoon and the eastern part of the South Asian monsoon by the thermal forcing of the Tibetan Plateau.The monsoon is generally considered an atmospheric response to seasonal changes in land–sea thermal contrast,induced by the annual cycle of the solar zenith angle 1,2.The Asian summer monsoon (ASM)is the strongest element of the global monsoon system 3–5.In addition to land–sea contrast,it is affected by large-scale mountain-ranges such as the Tibetan Plateau (TP)6–9,which serve,in winter,as a giant wall across almost the whole Eurasian continent that blocks cold outbreaks from the north and confines the winter monsoon to the eastern and southern Asia 10.The air over the TP descends in winter and ascends in summer,driving the surrounding surface air that diverges from the TP in winter and converges toward it in summer,much like a sensible-heat-driven air-pump (SHAP)11,12.Because in summer the impinging flow toward the TP is weak,TP-SHAP has been suggested to be dominant over mechanical forcing in controlling the ASM 9,12–14,including its subsystems:the South Asian summer monsoon (SASM)and the East Asian summer monsoon (EASM).Variations in the ASM and its controlling factors are known to be influenced by natural fluctuations 15–17along with anthropogenic greenhouse–gas emissions and environmental pollution 18,19.The TP surface sensible heat flux has weakened in recent decades,due mainly to global warming 20,21.The interception of solar radiation by atmospheric brown clouds leads to surface dimming 19.In summer,the greater dimming over land than over adjacent oceans suggests a weakening in land–sea contrast;the dimming trend over the northern Indian Ocean leads to a decrease in local evaporation and less moisture being fed to the monsoonal inflow 22,as well as a decrease in the meridional sea-surface-temperature gradient 22,23.These factors may contribute to the weakening of monsoonal rainfall 19.In addition,the darkening of snow and ice due to the deposition of soot reduces surface albedo and enhances solar absorption 24,25,and heating of the troposphere over the TP due to increasing amounts of dust and black carbon aerosols can lead to enhanced land–atmosphere warming,which in turn accelerates snow melt and glacier retreat 26,27.Global warming and widespread glacier-mass loss and snow-cover reduction are projected to accelerate through-out the 21st century 28.These changes are expected to have a strong influence on certain regions of the ASM in which TP thermal forcing plays an important role.Many studies have examined the separate influences of individual factors on the ASM 3,6–9,11,12;however,their relative and synthetic contributions to the ASM remain unclear,also it remains debated whether the ‘‘Himalayas wall’’can block dry air from the north and contribute to the formation of the SASM 29.In addition the impacts of another Plateau,the Iranian Plateau (IP),lower than the TP but with the same size,has never been paid attention.With the aim of resolving these issues,in the present study we performed numerical experiments to investigate the various factors that control different aspects of the ASM.ResultsInfluence of land–sea thermal contrast on the ASM .The influence of land–sea thermal contrast and plateau forcing on the ASM is investigated by employing a general circulation model (GCM),FGOALS/SAMILSUBJECT AREAS:CLIMATE CHANGE ATMOSPHERIC SCIENCEHYDROLOGYENERGYReceived26January 2012Accepted 1May 2012Published 11May 2012Correspondence and requests for materials should be addressed to Y.L.(lym@lasg.iap.ac.cn)(Methods).The model is integrated with prescribed,seasonally varying sea surface temperature (SST)and sea ice.The controlled climate integration is referred to as the CON experiment.The modelled precipitation (Fig.1a)shows some bias compared with observations 30,31(Fig.1b),with a stronger Somali jet and enhanced rainfall over most of the ASM domain,but it captures the main features of the ASM,performing reasonably well in simulating the maximum centers over the western coast of India,the Bay of Bengal (BOB),and the southeastern slopes of the TP.Since the monsoon is traditionally considered an atmospheric response to the seasonal land–sea thermal contrast 1,2,it is reasonable to infer that the precipitation forced not by orography but by the land–sea distribution alone could be considered as a monsoonprototype.A no-mountain experiment NMT is thus designed,being the same as the CON run except that all the mountains world-wide are removed (Methods Table 1).The modelled precipitation (Fig.1c)is confined to south of 20u N,with the maximum centers (.18mm d –1)located between 10u N and 15u N,as in the control run.Remarkable changes compared with the control run are seen in the subtropical area:the SASM north of 20u N and the EASM are substantially reduced.Because our main concern is how the extensive Asian mountains of the IP and TP (IPTP)influence the ASM,in the next experiment only the IPTP is removed.The simulated precipita-tion pattern (Fig.1d)is similar to that in NMT (Fig.1c)and is considered the component of the ASM that is induced by land–sea thermal contrast alone.The experiment is thus termed the L_S experiment (See Methods Experiment Design).Influence of IPTP mechanical insulation on the ASM .The differences (DIFF )in circulation and precipitation between CON (Fig.1a)and L_S (Fig.1d),as shown in Fig.2a,are forced by mechanisms other than land–sea thermal forcing.Such mechanisms are required to (1)produce a cyclonic circulation at 850hPa over the subtropical continent between 20u N and 40u N,circumambulating the IPTP;(2)reduce precipitation over tropical oceans and the northwestern Pacific;and (3)increase precipitation mainly over the Asian continent,with maximum centers over India,the northern BOB,the southern slopes of the TP,and eastern Asia.The absence of precipitation over northern India in the L_S experiment might reflect the removal of the ‘‘IPTP insulator,’’which results in the southward advection of dry,cold air from the subtro-pics and a lack of tropical convective instability and rainfall.Were this the case,merely adding the IPTP (but not allowing its surface-sensible-heating to heat the atmosphere)into the L_S experiment,which is defined as the IPTP_M experiment (See Methods Experi-ment Design),would be sufficient to produce the monsoon rainfall in the northern South Asia.However,the results in Fig.2b indicate that this is not the case.In the IPTP_M experiment,the patterns of both precipitation and circulation at 850hPa are similar to those in the L_S experiment.Similarly,if we merely add IP and TP separately into the L_S experiment (i.e.,the IP_M and TP_M experiments,respect-ively),the resultant precipitation and circulation distributions (Fig.2c and 2d,respectively)are also similar to those in the L_S experiment.These results demonstrate that in summer,mechanical insulation of the IP and TP has a minor influence on the generation of the ASM,as it cannot produce the required compensating rainfall and precipitation patterns (Fig.2a).Influence of IPTP thermal forcing on the ASM .Three sets of experiments were designed with surface sensible heating on the IP (IP_SH),TP (TP_SH),and IPTP (IPTP_SH)(Methods Experiment Design),in order to study the influence of orographically elevated thermal forcing on the ASM.In IP_SH (Fig.3a),the IP thermal forcing generates a cyclonic circulation encircling the IP,similar to the western parts of the compensating circulation in Fig.2a.The forcing also results in reduced precipitation,mainly over the tropical Indian Ocean and the northwest Pacific,and increased precipitation over the Asian continent west of 100u E (especially over Pakistan,northern India,and the southwestern slopes of the TP),a pattern similar to that of the compensating precipitation west of 100u E,indicating the important role of the IP in generating the northern SASM.In the TP_SH experiment (Fig.3b),TP thermal forcing also gen-erates a cyclonic circulation encircling the TP.Correspondingly,reduced precipitation occurs west of 80u E;in contrast,increased precipitation occurs east of 80u E,especially over the BOB,the south-ern slopes of the TP,and East Asia.They are similar to the compens-ating precipitation and circulation patterns in the region east of 80u E (Fig.2a),indicating that TP thermal forcing plays a dominant role in the generation of the EASM and the eastern part of theSASM.Figure 1|Impacts of land–sea thermal contrast on the Asian summer monsoon,showing the summer precipitation rate (color shading,unit mm ?d –1)and 850hPa winds (vectors)for a,the control experiment CON;b,observations averaged over the period 1979–2009from Global Precipitation Climatology Project (GPCP)for precipitation and from NCEP-DEO AMIP-II Reanalysis (R-2)for winds;c,experiment NMT in which the global surface elevations are set to zero;and d,experiment L_S in which only the elevations of the Iranian Plateau (IP)and the Tibetan Plateau (TP)are set to zero.Thick contours indicate elevations higher than 1,500m and 3,000m.In the IPTP_SH experiment (Fig.3c),the elevated IPTP heating results in reduced precipitation in tropical oceans,and increased precipitation over the Asian continent to the north.The heating also generates a cyclonic circulation at 850hPa over the Asian subtrop-ical continental areas,with relatively isolated centers over the IP and TP.The results shown in Fig.3c are basically equivalent to the linear addition of the results in Fig.3a and 3b,indicating the important but contrasting roles of IP and TP thermal forcing in different parts of the ASM.More significantly,the precipitation and circulation patterns generated by IPTP thermal forcing (Fig.3c)are close to those required to compensate the ASM (Fig.2a).This result demonstrates that in addition to land–sea thermal contrast,the thermal forcing of large mountain ranges in Asia is an important factor in producing the ASM,especially over continental areas.Influence of climbing versus deflecting orographic effects on the ASM .More than 85%of the total atmospheric water vapor,as measured by specific humidity,generally resides in a layer below 3km above sea level.In order for monsoon clouds and precipitation to form,lower-tropospheric water vapor must be lifted by vertical motions forced either internally or externally;consequently,high near-surface moist entropy and warm upper-level temperature are coupled 32.One of the internal forcing is the type of cold/warm fronts 33.This mechanism is important at middle and high latitudes,especially in winter,but is not important in the tropics in summer because the air temperature in the tropics is relatively uniform.The mechanical forcing of mountains is an important external for-cing:air flow impinging upon mountains is either deflected to produce encircling flow or lifted to produce climbing flow 34,35.Consequently,clouds and precipitation are generated around mountains.However,if a mountain is higher than several hundred meters,the conservation constraint of angular momentum and energy means that the airflow passes around the mountain rather than rising over it 36.Thermal forcing can also generate atmospheric ascent,because large-scale atmospheric potential temperature (h )increases with height.According to the steady-state thermodynamic equationV I:+h ~Q ,ð1Þwhere V Iis air velocity,in regions of heating (Q .0),air shouldpenetrate isentropic surfaces upward.There are several types of atmospheric heating.Shortwave radiation is weakly absorbeddirectly by the atmosphere.In the absence of cloud,longwave radi-ation can easily escape into space.Condensation heating normally occurs above the cloud base.Whereas surface sensible heating can increase the near-surface entropy,result in the development of con-vective instability and trigger atmospheric ascent;and is effective in generating atmospheric ascent in the lower troposphere.If surface sensible heating occurs on a mountain slope,and if the mountain is high enough,large amounts of moisture in lower layers are readily transported to the free atmosphere 12.The TP in summer is a heat source for the atmosphere 6and has a strong influence on weather and climate 9,11,12,37.When a moist and warm southwesterly approaches the TP,the air becomes heated,starts to penetrate isen-tropic surfaces,and slides upward along its sloping surface.Figure 4shows the distribution of precipitation and streamlines at the s 50.89surface,which is about 1km from the surface.In the CON experiment (Fig.4a),when the water conveyer belt originating from the Southern Hemisphere meanders eastward through the South Asian subcontinent,the effects of land–sea thermal forcing mean that severe precipitation centers are formed along 15u N.The rest of the water vapor is transported to sustain the East Asian Monsoon,although some swerves northward over northern India and the BOB.The pumping effect of TP-SHAP results in the convergence of air toward the TP.The upward streamlines are subperpendicular to the TP contours,eventually forming a cyclonic circulation at the southeastern corner of the TP.Consequently,heavy monsoon rainfall occurs over northern India and western China,with a maximum center (.18mm ?d –1)appearing over the southeastern slopes of the TP.The condensation heating of this rainfall center generates cyclonic circulation in the lower layer and further intensifies the EASM,implying a positive feedback between precipitation and circulation 38.In the IPTP_M experiment (Fig.4b),in contrast,when the water vapor flux from the main water conveyer belt approaches the TP,it is not heated and the airflow remains at the same isentropic surface (Equation (1)).Consequently,the streamlines do not climb up the TP;instead,they move around the mountains,parallel to orographic contours.Thus,no mon-soon develops over northern India and the TP,and the EASM is sub-stantially weakened.These results indicate that the thermal forcing of large-scale mountains plays a dominant role in the generation of the northern and eastern parts of the SASM and the EASM.A recent study based on numerical sensitivity experiments 29emphasized the importance of the insulation effect oftheTable 1|Experiment design for examination of the dominant control of land-sea thermal contrast,as well as orographically mechanical insulation and elevated thermal impacts on the various parts of the Asian summer monsoon.The sign (!)indicates that the corresponding element has been included in the related experimentExperiment Abbreviation Land-sea thermal contrastOrographically mechanical insulation Orographically elevated thermal controlIran Plateau (IP)Tibet Plateau (TP)Iran Plateau (IP)Tibet Plateau (TP)CON !!!!!NMT !L_S!IPTP_M!!!IP_M !!TP_M !!IPTP_SH!!IP_SH !TP_SH !HIM!!Southern slope only !!HIM_M!!Southern slope only----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------Himalayas in producing the SASM.This finding is questio-nable because the experiment design took into account both the mechanical effect and surface sensible heating of the Himalayas and adjacent mountains (Fig.4c);thus,the TP-SHAP mechanism still operates for the SASM.To demonstrate this point,we employed the current GCM and designed a sensitivity experiment (HIM )in which we followed Boos and Kuang’s approach exactly in considering the effect of the Himalayas on the SASM (Methods Experiment Design),as indicated by the polygon in Fig.4c.In addition to this tracking experiment,another experiment (HIM_M )was performed,whichwas the same as the HIM experiment except that the Himalayas’surface-sensible-heating was not allowed to heat the atmosphere (Fig.4d).The results show that the HIM experiment (Fig.4c)yields a similar SASM to that in the CON experiment (Fig.4A),the same consequence as in Boos and Kuang.However,in the HIM_M case (Fig.4d),the impinging tropical flow cannot climb up the TP;instead,it splits into eastern and western branches that each move around the TP,subparallel to orographic contours.The western branch forms a return flow,causing a southward shift in the Indian monsoon trough from its usual location over northeastern India to over central India.In this situation,the part of the SASM over northeastern India disappears,and the EASM is markedly wea-kened.These results demonstrate that the insulation effect of the TP is insignificant in terms of the ASM.Instead,it is the thermal forcing of the Tibetan/Iranian Plateau that plays a dominant role in the generation of the northern part of the SASM and the EASM.Structure of the SASM .A striking feature of the present experiments is the insensitivity of the southern part of the SASM to IPTP forcing:in all experiments (Figs 1and 2),the intensity and spatial distribution of precipitation south of 20u N show little change compared with the control while the configuration or thermal status of the Tibetan/Iranian Plateau shows a marked change.Figures 5a and 5b show 80u E–90u E longitudinallyaveragedFigure 2|Impacts of mountain mechanical forcing on the Asian summer monsoon,showing the summer precipitation rate (color shading,unit mm ?d –1)and 850hPa winds (vectors)for a,the difference (DIFF)between the CON and L_S experiments,indicating the compensating rainfall and circulation required to make up the total monsoon;b,experiment IPTP_M in which the IP and TP mechanical forcing exists;c,experiment IP_M in which the IP mechanical forcing exists;and d,experiment TP_M in which the TP mechanical forcing exists.Thick black contours surrounding grey-hatched regions indicate elevations higher than 1,500m and 3,000m.Figure 3|Impacts of mountain thermal forcing on the Asian summer monsoon,showing the summer precipitation rate (color shading,unit mm ?d –1)and 850hPa winds (vectors)generated due to the elevated surface sensible heating of a,the Iranian Plateau (IP_SH);b,the Tibetan Plateau (TP_SH);and c,the IP and TP (IPTP_SH).Thick red contours surrounding red-hatched regions indicate elevations higher than 1,500m and 3,000m.latitude–height cross sections from the CON and IPTP_M experiments,demonstrating that the vertical velocity is divided into a southern branch and a northern branch at about 25u N.In the CON run (Fig.5a),strong rising associated with the southern SASM is located over the northern Indian Ocean.Ascending air is also dominant above the TP,with maxima located near the surface,indicating the importance of surface sensible heating in generating orographic ascent.In the IPTP_M experiment (Fig.5b),the lack of surface heating on the TP results in two remarkable sinking centers over its slopes;thus,the northern branch of the SASM disappears over northern India.However,the intensity and location of the southern branch is largely unchanged.In fact,in all the experiments the southern SASM branch remains steady,with a center (.18310–2Pa s –1)at about 400hPa,locked to the south of the coastline.The insensitivity of the southern branch of theSASM to orographic change indicates that the land–sea thermal contrast plays a dominant role in its generation and variation.The above discussion is summarized schematically in Figure 6.The meridional circulation of the SASM can be divided into southern and northern branches.Its southern branch is located in the tropics:water vapor that originates from the Southern Hemisphere and is transported along the zonally oriented ‘‘water-vapor conveyer belt’’is lifted upward due to the land–sea thermal contrast,forming mon-soon precipitation there.The northern branch occurs along the southern margin of the IPTP in the subtropics.When the conveyer belt approaches the TP,part of its water vapor is hauled away and turned northward,then lifted upward by the IPTP-SHAP,resulting in heavy precipitation in the monsoon trough over northern India and along the foothills and slopes of the TP.The rest of the water vapor along the water conveyer belt is transported northeastward to sustain the EASM,which is controlled by the land–sea thermal con-trast and thermal forcing of the TP.These results highlight the dom-inant roles of the land–sea thermal contrast and IPTP thermal forcing in influencing the ASM.DiscussionIn nature,the influences of the IPTP orography and its surface sensible heating cannot be separated.The significance of the dominance of IPTP thermal forcing in influencing the ASM lies in the fact that,over the modern-day orography,the thermal status of the IPTP varies due to natural and anthropogenic factors,as reviewed above.By focusing on changes in the thermal status of the IPTP,the dominance of thermal controls on the ASM may provide us with a tangible way of identifying climate trends in the Asian summer monsoon in a warming world,and of improving weather forecasts,climate predic-tions,and projections in areas affected by the Asian monsoon.MethodsGeneral Circulation Model Description .The atmospheric general circulation model (GCM)employed in the present study is SAMIL (Spectral Atmospheric Model of IAP/LASG),as developed at the State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics/Institute of Atmospheric Physics (LASG/IAP),Beijing,China.SAMIL is a spectral model with rhomboidal truncation at wave-number 42.It has 26vertical layers with a top at 2.1941hPa 39.AsFigure 4|Mechanism––Relative contributions of the climbing and deflecting effects of mountains,showing the summer precipitation rate (color shading,unit mm ?d –1)and streamlines at the s 50.89level for a,the CON experiment;b,the IPTP_M experiment;c,the HIM experiment;and d,the HIM_M experiment.Dashed contours surround elevations higher than 1,500m and 3,000m,with red and black colors respectively indicating with and without surface sensible heating of the mountains.Dark blue open arrows denote the main atmospheric flows impinging on the TP,either climbing up the plateau (a and c )or moving around the plateau,parallel to orographic contours (b and d).Figure 5|Structure of the South Asian summer monsoon,showing 806E–906E longitudinally averaged vertical–meridional cross-sections of pressure vertical velocity (contour interval,2310–2Pa ?s –1)for experiments a,CON;and b,IPTP_M.an atmospheric component of the climate system model FGOALS-s developed at LASG/IAP,SAMIL is driven by the sixth generation of NCAR Coupler using NCAR CLM3as a land surface component 40.Its physical parameterizations include SES241,the updated radiation parametric scheme developed by Edwards and Slingo 42,diagnostic cloud parameterization,the mass flux cumulus parameterization of Tiedtke 43for deep,shallow,and mid-level convection,and a nonlocal PBLparameterization scheme 44.Observed mean monthly sea surface temperature (SST)and sea ice with a seasonal cycle,as obtained from AMIP II 45,were prescribed.All experiments were integrated for 7years,and the monsoon climate was calculated from the last five June–August periods.Experiment Design .The model was integrated with prescribed,seasonally varying SST and sea ice to form a controlled-climate integration first,which is referred to as the CON experiment.The orographic setting in each experiment was achieved by changing only the prescribed surface elevations.The no-surface-sensible-heating experiments were designed as follows:while the surface energy balance was kept unchanged,the surface sensible heat released at the elevation above 500m was not allowed to heat the atmosphere;i.e.,the vertical diffusive heating term in the atmospheric thermodyn-amic equation was set to zero.Details of the design for each experiment are given in Table 1and explained below..Influence of Land–Sea Thermal Contrast on the ASMFor experiments NMT and L_S (see Fig.1):the elevation over the whole globe is set to zero in NMT .Since the main purpose of this study is to compare the relative contributions of land–sea thermal contrast and large-scale Asianmountain ranges on different parts of the ASM,in the L_S experiment only the elevations of the Iranian Plateau and Tibetan Plateau are set to zero..Influence of IPTP Mechanical Insulation on ASMFor the mechanical forcing experiments IPTP_M ,IP_M ,and TP_M (see Fig.2),the Iranian Plateau and Tibetan Plateau together,the Iranian Plateau alone,and the Tibetan Plateau alone are retained from the CON experiment,respectively,but their surface sensible heating is not allowed to warm the atmosphere..Influence of IPTP Thermal Forcing on the ASMIn designing the thermal forcing experiments IP_SH ,TP_SH ,and IPTP_SH (see Fig.3),three no-surface-sensible-heating experiments (IP_NS ,TP_NS ,andIPTP_NS )were first designed and integrated,in which the global orographic distribution is the same as in the CON experiment while the surface sensible heating on the atmosphere over the IP,TP,and IPTP,respectively,was removed from the CON experiment.Because the only difference between the CON and IP-NS (TP_NS,IPTP_NS)experiments is whether the elevated surface sensible heating on the atmosphere occurs over the IP (TP,IPTP),their integration differences in Fig.3a (Fig.3b,3c)are qualitatively considered as the thermal impact of the IP (TP,IPTP)on the ASM,and are assigned as the IP_SH (TP_SH ,IPTP_SH )experiment.In designing the HIM and HIM_NS experiments (see Fig.4),we followed exactly the original work of Boos and Kuang 29.The HIM experiment is the same as CON except for ‘‘removing the bulk of the Tibetan Plateau while preserving a zonal elongated band of mountains to the south,east and west of the plateau,’’as denoted by the polygon in Fig.4c and 4d.The HIM_NS experiment is the same as the HIM ,except that the surface sensible heat flux on the HIM mountain surfaces is not allowed to heat the atmosphere.1.Webster,P.J.et al .Monsoons:Processes,Predictability and the prospects for prediction.J.Geophys.Res.103,14451–14510(1998).2.Meehl,G.A.Coupled ocean-atmosphere-land processes and South Asian monsoon variability.Science 265,263–267(1994).3.Flohn,rge-scale aspects of the "summer monsoon"in South and East Asia.J.Meteor.Soc.Japan 75th Ann.Vol.180–186(1957).4.Chang,C.P.et al .East Asian monsoon (World Scientific,New Jersey,2004).5.Wang,B.et al .The Asian Monsoon (Springer,Chichester,2006).6.Yeh,T.C.,Lo,S.-W.&Chu,P.-C.The wind structure and heat balance in the lower troposphere over Tibetan Plateau and its surrounding.Acta Meteor.Sinica 28,108–121(1957).7.Ye,D.Z.,&Gao,Y.X.Meteorology of the Qinghai-Xizang Plateau (Chinese Science Press,Beijing,1979).8.Yanai,M.,Li,C.F.,&Song,Z.S.Seasonal heating of the Tibetan Plateau and its effects on the evolution of the Asian Summer Monsoon.J.Meteor.Soc.Japan 70,319–351(1992).9.Yanai,M.&Wu,G.-X.Effects of the Tibetan Plateau Chapter 13,The Asian Monsoon (eds Wang,B.et al )(Springer,Chichester,2006).10.Chang,C.-P.,Wang,Z.,Hendon,H.2006:The Asian winter monsoon.Chapter 3,The Asian Monsoon (eds Wang,B.et al .)(Springer,Chichester,2006).Figure 6|Schematic diagram showing the gross structure of the South Asian summer monsoon.For the southern branch,water vapor along the conveyer belt is lifted up due mainly to land–sea (L_S)thermal contrast in the tropics;for the northern branch the water vapor is drawn away from the conveyer belt northward toward the foothills and slopes of the TP,and is uplifted to produce heavy precipitation that is controlled mainly by IPTP-SHAP;the rest of the water vapor is transported northeastward to sustain the East Asian summer monsoon,which is controlled by the land–sea thermal contrast as well as thermal forcing of the TP.。