Temporal and spatial variation characteristics of tropopause
temperature over China in recent 40 years

Abstract

Abstract: Based on NCEP/NCAR monthly reanalysis data from 1981 to 2020, the temporal and spatial variation characteristics, as well as the seasonal variations, of tropopause temperature over China in recent 40 years were studied. Linear regression, Mann-Kendall mutation test and empirical orthogonal decomposition (EOF) were used to study the interannual variation trend and spatiotemporal distribution characteristics of tropopause temperature. The results show that the tropopause temperature in China has an overall decreasing trend from 1981 to 2020, with a significant decreasing trend from 1995 to 2020 and a decreasing mutation occurred in 1993. Tropopause temperature in the period also has obvious seasonal characteristics. Both spring and winter climate trend rates are small and contribute little to the annual decreasing trend of tropopause temperature, while the climate trend rates in summer and autumn are larger, and contribute more to the decreasing trend of tropopause temperature in the whole year. The analysis of the spatial variation characteristics of tropopause temperature by EOF method shows that, the spatial distribution of the first mode reflects that the variation trend of tropopause in China is basically consistent in space, and the distribution presents a zonal structure of "+, −" from south to north,while the spatial distribution of the second mode presents a zonal structure of "+, −, +, −" from south to north, with an obvious north-south opposite distribution with 34°N as the boundary, and the spatial distribution of the third mode presents a zonal structure of "+, −, +" from south to north.

Key words: tropopause, temperature, Mann-Kendall matation test, empirical orthogonal function

CLC Number:

P421.31

TANG Chaoli , ZHU Yidong , WEI Heli , WEI Yuanyuan . Temporal and spatial variation characteristics of tropopause temperature over China in recent 40 years[J]. Journal of Atmospheric and Environmental Optics, 2023, 18(1): 25-35.

References 20

[1]	Yang S Y, Zhou S W. Review of researches on tropopause in recent 30 years [J]. Meteorological Science and Technology,
20	10, 38(2): 145-151.
	杨双艳, 周顺武. 对流层顶研究回顾 [J]. 气象科技, 2010, 38(2): 145-151.
[2]	Liu Z Y, Sun Y Q, Bai W H, et al. Comparison of RO tropopause height based on different tropopause determination
	methods [J]. Advances in Space Research, 2021, 67(2): 845-857.
[3]	Holton J R, Haynes P H, Mclntyre M E, et al. Stratosphere-troposphere exchange [J]. Reviews of Geophysics, 1995, 33(4):
40	3-439.
[4]	IPCC. Climate Change 2013-The Physical Science Basis: Working Group I Contribution to the Fifth Assessment Report of the
	Intergovernmental Panel on Climate Change [M]. Cambridge: Cambridge University Press, 2014.
[5]	Wu J, Yang Q, Fu C B, et al. Climatological characteristics of East Asia tropopause height under global warming background
[J]	Journal of Tropical Meteorology, 2007, 23(6): 595-600.
	吴涧, 杨茜, 符淙斌, 等. 全球变暖背景下东亚对流层顶高度演变特征的研究 [J]. 热带气象学报, 2007, 23(6): 595-600.
[6]	Yuan W , Xu J Y, Ma R P. Variation characteristics of tropopause temperature and height from COSMIC [J]. Chinese Journal
	of Space Science, 2009, 29(3): 311-318.
	袁韡, 徐寄遥, 马瑞平. 利用COSMIC 数据分析全球对流层顶温度和高度的变化特性 [J]. 空间科学学报, 2009, 29(3):
31	1-318.
[7]	Wang L, Xie C B, Han Y, et al. Comparison of retrieval methods of planetary boundary layer height from lidar data [J].
	Journal of Atmospheric and Environmental Optics, 2012, 7(4): 241-247.
	王琳, 谢晨波, 韩永, 等. 测量大气边界层高度的激光雷达数据反演方法研究 [J]. 大气与环境光学学报, 2012, 7(4):
24	1-247.
[8]	Qu X C, An J C, Liu G. Analysis of Antarctic tropopause with COSMIC occultation data [J]. Geomatics and Information
	Science of Wuhan University, 2014, 39(5): 605-610.
	屈小川, 安家春, 刘根. 利用 COSMIC 掩星资料分析南极地区对流层顶变化 [J]. 武汉大学学报·信息科学版, 2014, 39
(5)	: 605-610.
[9]	Wang X H, Xu Y Z, Zhang C X, et al. Spatial-temporal variation of tropospheric NO2 concentration in Pearl River Delta
	based on EMI observations [J]. Journal of Atmospheric and Environmental Optics, 2021, 16(3): 197-206.
	王肖汉, 徐翼洲, 张成歆, 等. 基于EMI观测的珠三角地区对流层 NO2 柱浓度时空变化特征分析 [J]. 大气与环境光学学
	报, 2021, 16(3): 197-206.
[10]	Seidel D J, Ross R J, Angell J K, et al. Climatological characteristics of the tropical tropopause as revealed by radiosondes
[J]	Journal of Geophysical Research: Atmospheres, 2001, 106(D8): 7857-7878.
[11]	Liu H, Wei Z G, Wei H, et al. Characteristic of tropopause height over China in recent 51 years [J]. Plateau Meteorology,
20	12, 31(2): 351-358.
	刘慧, 韦志刚, 魏红, 等. 近51年我国对流层顶高度的变化特征 [J]. 高原气象, 2012, 31(2): 351-358.
[12]	Guo J B, Jin S G. Variations of tropopause parameters over China from FY-3C GNSS Radio occultation observations [J].
	Journal of Geodesy and Geodynamics, 2021, 41(1): 21-26.
	郭佳宾, 金双根. 利用FY-3C卫星GNSS掩星数据分析中国区域对流层顶参数变化 [J]. 大地测量与地球动力学, 2021, 41
(1)	: 21-26.
[13]	Zhou S W, Zheng D, Qin Y L, et al. Comparison on variation features of tropical tropopause pressure over the Tibetan
	Plateau and the other regions in the same latitudes [J]. Transactions of Atmospheric Sciences, 2019, 42(5): 660-671.
	周顺武, 郑丹, 秦亚兰, 等. 青藏高原与同纬度其他地区热带对流层顶气压变化特征的比较 [J]. 大气科学学报, 2019, 42
(5)	: 660-671.
[14]	Fu Z J, Dong B J, Zhang C W. Correlation analysis between greenhouse effects and tropopause over China [J]. Journal of
	Arid Meteorology, 2011, 29(2): 182-188.
	付志嘉, 董保举, 张成稳. 我国气候变暖特征及其与对流层顶的关系 [J]. 干旱气象, 2011, 29(2): 182-188.
[15]	World Meteorological Organization. Meteorology—A three-dimensional science: Second session of the commission for
	aerology [J]. WMO Bull, 1957, 4(4): 134-138.
[16]	Li J, Cai F, Ming H Q, et al. Climatic characteristics of the first tropopause height over Liaoning Province [J]. Journal of
	Meteorology and Environment, 2009, 25(2): 9-15.
	李辑, 蔡福, 明惠青, 等. 辽宁地区第一对流层顶高度变化特征分析 [J]. 气象与环境学报, 2009, 25(2): 9-15.
[17]	Huang J Y. Statistical Analysis and Forecast Method of Meteorology (3rd Edition) [M]. Beijing: China Meteorological Press,
	2004.
	黄嘉佑.气象统计分析与预报方法 (第3 版) [M]. 北京: 气象出版社, 2004.
[18]	Xie R H, Wang A H, Hua W. Temporal and spatial distribution characteristics and influencing factors of pan evaporation in
	China from 1961 to 2013 [J]. Climatic and Environmental Research, 2020, 25(5): 483-498.
	谢睿恒, 王爱慧, 华维. 1961～2013 年中国蒸发皿蒸发量时空分布特征及其影响因素 [J]. 气候与环境研究, 2020, 25(5):
48	3-498.
[19]	Yu J, Zhang J Q, Zhang M. Study on meso-βscale torrential rain with EOF [J]. Chinese Journal of Atmospheric Sciences,
20	14, 38(4): 795-803.
	于杰, 张继权, 张铭. EOF分析用于β 中尺度暴雨系统的探索 [J]. 大气科学, 2014, 38(4): 795-803.
[20]	Yan X Y, Zhang Q, Zhang W B, et al. Analysis of climate characteristics in the Pan-Central-Asia arid region [J]. Arid Zone
	Research, 2021, 38(1): 1-11.
	闫昕旸, 张强, 张文波, 等. 泛中亚干旱区气候变化特征分析 [J]. 干旱区研究, 2021, 38(1): 1-11.
[21]	Bian L G, Lin Z, Zheng X D, et al. Trend of Antarctic ozone hole and its influencing factors [J]. Climate Change Research,
20	11, 7(2): 90-96.
	卞林根, 林忠, 郑向东, 等. 南极臭氧洞的影响因子和变化趋势 [J]. 气候变化研究进展, 2011, 7(2): 90-96.

Temporal and spatial variation characteristics of tropopause temperature over China in recent 40 years

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References 20

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	TANG Chaoli , HAO Dewei , WEI Yuanyuan , DAI Congming , WEI Heli . Temporal and spatial characteristics and influencing factors of total ozone column in Antarctic [J]. Journal of Atmospheric and Environmental Optics, 2023, 18(3): 201-213.
[2]	ZHAO Qiang , TAN Lu , FANG Qiansheng , LIU Changyu , MA Ke , ZHU Shuguang , . Analysis of spatiotemporal evolution and influencing factors of heat island effect in Hefei based on satellite data [J]. Journal of Atmospheric and Environmental Optics, 2023, 18(2): 153-167.
[3]	LI Rui. Variation characteristics of PM2.5 and PM10 in Chengdu and their correlation with meteorological factors [J]. Journal of Atmospheric and Environmental Optics, 2023, 18(1): 47-58.
[4]	HUANG Dong , , LI Xin , ZHANG Yanna , ZHANG Yunxiang . Design and test of temperature control system for automatic sun photometer [J]. Journal of Atmospheric and Environmental Optics, 2023, 18(1): 73-81.
[5]	LIU Kaidi, WU Haibin, CHEN Xinbing, SONG Wei∗, XU Lei. Correction of infrared radiation attenuation in water mist media based on Mie scattering theory [J]. Journal of Atmospheric and Environmental Optics, 2022, 17(4): 476-484.
[6]	SONG Xiaonan, CHI Guangyuan, SHI Yue∗, FAN Qiang. Study on influencing factors of spatial heterogeneity of land surface temperature in coastal areas [J]. Journal of Atmospheric and Environmental Optics, 2022, 17(3): 317-327.
[7]	WANG Min∗, FANG Xin, WANG Maocui, FANG Haitao. Analysis on variation characteristics of surface ozone and influence of meteorological elements in Hefei [J]. Journal of Atmospheric and Environmental Optics, 2022, 17(2): 205-212.
[8]	. Non-Contact Temperature Measurement System of Molten Steel in LF Furnace and Its Application [J]. Journal of Atmospheric and Environmental Optics, 2021, 16(1): 74-80.
[9]	. Atmospheric Optical Turbulence Profile Measurement: A Review [J]. Journal of Atmospheric and Environmental Optics, 2021, 16(1): 2-17.
[10]	. Determination of Trace Elements in Three Cold Medicine Tablets by Laser-Induced Breakdown Spectroscopy [J]. Journal of Atmospheric and Environmental Optics, 2020, 15(4): 305-313.
[11]	. Progress of Retrieval of Atmospheric Temperature and Water Vapor Profiles based on Infrared Spectra [J]. Journal of Atmospheric and Environmental Optics, 2020, 15(2): 81-89.
[12]	. Effect of Sample Temperature on Radiation Characteristics of Laser-Induced Cu Plasma [J]. Journal of Atmospheric and Environmental Optics, 2020, 15(2): 110-116.
[13]	. Design of Temperature Control System for Mid-Infrared Detector\\[.2cm] Used in Gas Detection [J]. Journal of Atmospheric and Environmental Optics, 2019, 14(5): 351-358.
[14]	. Temperature Sensitivity and on-Orbit Calibration Analysis for FY-3B MERSI Shortwave Infrared Bands [J]. Journal of Atmospheric and Environmental Optics, 2019, 14(5): 374-384.
[15]	PENG Yuquan1,2, KAN Ruifeng1, XU Zhenyu1, XIA Huihui1, NIE Wei1,2, ZHANG Buqiang1,2, PEI Xiaofan1. Temperature Measurement of CH₄/Air Premixed Flat Flame Burner Based on Tunable Diode Laser Absorption Spectroscopy [J]. Journal of Atmospheric and Environmental Optics, 2019, 14(3): 228-234.