阿尔泰山降水氢氧稳定同位素特征及水汽来源分析

doi:10.12118/j.issn.1000-6060.2021.480

Abstract

Abstract:

The Altay Mountains located in the middle of the Eurasian continent are one of the key areas of climate research in the mid-latitude westerlies. On the basis of the data collected from the four stations across the Altay Mountains, the intra-annual variations of stable hydrogen and oxygen isotopes in precipitation and the meteoric water lines were investigated. The temperature effect on precipitation isotopes was examined, and the water vapor sources were analyzed using backward trajectory. The following results were obtained. (1) The isotope ratios in precipitation are higher in summer and lower in winter, and the seasonal difference in the southern side is larger than that in the northern side. The deuterium excess value in precipitation is lower in summer and higher in winter at most stations, except for Novosibirsk. (2) The slope and intercept of meteoric water lines are lower than the global average at most stations, except for Novosibirsk. (3) The isotope ratios in precipitation have an obvious temperature effect, which can be seen from seasonal variations and spatial patterns. (4) The backward trajectory indicates a joint influence of the westerlies, the polar air mass, and the locally evaporated water vapor, and the northern stations may be more influenced by the polar path than other stations. These findings are useful for understanding the hydrological and climate information about stable precipitation isotopes across different parts of the Altay Mountains and provide a reference for investigating regional atmospheric water cycle and climate change.

Key words: precipitation isotope, backward trajectory, water vapor source, Altay Mountains

DUAN Lihong,WANG Shengjie,ZHANG Mingjun,WANG Lifu. Stable hydrogen and oxygen isotopes in precipitation and water vapor source in the Altay Mountains[J].Arid Land Geography, 2022, 45(4): 1042-1049.

Figures/Tables 8

Tab. 1

Fig. 1

Fig. 2

Tab. 2

Fig. 3

Fig. 4

Fig. 5

Tab. 3

References 35

[1]	Konapala G, Mishra A K, Wada Y, et al. Climate change will affect global water availability through compounding changes in seasonal precipitation and evaporation[J]. Nature Communications, 2020, 11: 3044, doi: 10.1038/s41467-020-16757-w. doi: 10.1038/s41467-020-16757-w pmid: 32576822
[2]	郭玉琳, 赵勇, 周雅蔓, 等. 新疆天山山区夏季降水日变化特征及其与海拔高度关系[J]. 干旱区地理, 2022, 45(1): 57-65.
	[ Guo Yulin, Zhao Yong, Zhou Yaman, et al. Diurnal variation of summer precipitation and its relationship with altitude in Tianshan Mountains of Xinjiang[J]. Arid Land Geography, 2022, 45(1): 57-65. ]
[3]	Bowen G J, Cai Z Y, Fiorella R P, et al. Isotopes in the water cycle: Regional- to global-scale patterns and applications[J]. Annual Review of Earth and Planetary Sciences, 2019, 47: 453-479. doi: 10.1146/annurev-earth-053018-060220
[4]	Zhang M J, Wang S J. A review of precipitation isotope studies in China: Basic pattern and hydrological process[J]. Journal of Geographical Sciences, 2016, 26(7): 921-938. doi: 10.1007/s11442-016-1307-y
[5]	Chen Y N, Li Z, Fang G H, et al. Large hydrological processes changes in the transboundary rivers of Central Asia[J]. Journal of Geophysical Research: Atmospheres, 2018, 123(10): 5059-5069. doi: 10.1029/2017JD028184
[6]	Yu Y, Pi Y Y, Yu X, et al. Climate change, water resources and sustainable development in the arid and semi-arid lands of Central Asia in the past 30 years[J]. Journal of Arid Land, 2019, 11(1): 1-14. doi: 10.1007/s40333-018-0073-3
[7]	Yao J Q, Liu X C, H W F. Stable isotope compositions of precipitation over Central Asia[J]. PeerJ, 2021, 9: e11312, doi: 10.7717/PEERJ.11312. doi: 10.7717/PEERJ.11312
[8]	Zhang M J, Wang S J. Precipitation isotopes in the Tianshan Mountains as a key to water cycle in arid Central Asia[J]. Sciences in Cold and Arid Regions, 2018, 10(1): 27-37.
[9]	Li Z X, Gui J, Wang X F, et al. Water resources in inland regions of Central Asia: Evidence from stable isotope tracing[J]. Journal of Hydrology, 2019, 570: 1-16. doi: 10.1016/j.jhydrol.2019.01.003
[10]	Wang L H, Dong Y H, Han D M, et al. Stable isotopic compositions in precipitation over wet island in Central Asia[J]. Journal of Hydrology, 2019, 573: 581-591. doi: 10.1016/j.jhydrol.2019.04.005
[11]	孙从建, 张子宇, 陈伟, 等. 亚洲中部高山降水稳定同位素空间分布特征[J]. 干旱区研究, 2019, 36(1): 19-28.
	[ Sun Congjian, Zhang Ziyu, Chen Wei, et al. Spatial distribution of precipitation stable isotopes in the alpine zones in Central Asia[J]. Arid Zone Research, 2019, 36(1): 19-28. ]
[12]	Chen H Y, Chen Y N, Li D L, et al. Effect of sub-cloud evaporation on precipitation in the Tianshan Mountains (Central Asia) under the influence of global warming[J]. Hydrological Processes, 2020, 34(26): 5557-5566. doi: 10.1002/hyp.13969
[13]	Wang S J, Jiao R, Zhang M J, et al. Changes in below-cloud evaporation affect precipitation isotopes during five decades of warming across China[J]. Journal of Geophysical Research: Atmospheres, 2021, 126(7): e2020JD033075, doi: 10.1029/2020JD033075. doi: 10.1029/2020JD033075
[14]	Liu X K, Rao Z G, Zhang X J, et al. Variations in the oxygen isotopic composition of precipitation in the Tianshan Mountains region and their significance for the westerly circulation[J]. Journal of Geographical Sciences, 2015, 25(7): 801-816. doi: 10.1007/s11442-015-1203-x
[15]	Du W T, Kang S C, Qin X, et al. Can summer monsoon moisture invade the Jade Pass in northwestern China?[J]. Climate Dynamics, 2020, 55(11): 3101-3115. doi: 10.1007/s00382-020-05423-y
[16]	Shi Y D, Wang S J, Wang L W, et al. Isotopic evidence in modern precipitation for the westerly meridional movement in Central Asia[J]. Atmospheric Research, 2021, 259: 105698, doi: 10.1016/J.ATMOSRES.2021.105698. doi: 10.1016/J.ATMOSRES.2021.105698
[17]	Wang S J, Zhang M J, Che Y J, et al. Contribution of recycled moisture to precipitation in oases of arid Central Asia: A stable isotope approach[J]. Water Resources Research, 2016, 52(4): 3246-3257. doi: 10.1002/2015WR018135
[18]	Fu Q, Li B, Hou Y, et al. Effects of land use and climate change on ecosystem services in Central Asia’s arid regions: A case study in Altay Prefecture, China[J]. Science of the Total Environment, 2017, 607: 633-646.
[19]	张东良, 兰波, 杨运鹏. 不同时间尺度的阿尔泰山北部和南部降水对比研究[J]. 地理学报, 2017, 72(9): 1569-1579. doi: 10.11821/dlxb201709003
	[ Zhang Dongliang, Lan Bo, Yang Yunpeng. Comparison of precipitation variations at different time scales in the northern and southern Altay Mountains[J]. Acta Geographica Sinica, 2017, 72(9): 1569-1579. ] doi: 10.11821/dlxb201709003
[20]	Aizen V B, Aizen E, Fujita K, et al. Stable-isotope time series and precipitation origin from firn-core and snow samples, Altai glaciers, Siberia[J]. Journal of Glaciology, 2005, 51(175): 637-654. doi: 10.3189/172756505781829034
[21]	Sidorova O V, Siegwolf R T W, Myglan V S, et al. The application of tree-rings and stable isotopes for reconstructions of climate conditions in the Russian Altai[J]. Climatic Change, 2013, 120(1): 153-167. doi: 10.1007/s10584-013-0805-5
[22]	Tian L D, Yao T D, MacClune K, et al. Stable isotopic variations in west China: A consideration of moisture sources[J]. Journal of Geophysical Research, 2007, 112: D10112, doi: 10.1029/2006JD007718. doi: 10.1029/2006JD007718
[23]	侯浩, 侯书贵, 庞洪喜. 阿尔泰山蒙赫海尔汗冰川不同水体稳定同位素空间分布特征及水汽来源[J]. 冰川冻土, 2014, 36(5): 1271-1279.
	[ Hou Hao, Hou Shugui, Pang Hongxi. Stable isotopes in different water samples on the Monh Hayrhan Glacier, Altay Mountains: Spatial distribution features and vapor sources[J]. Journal of Glaciology and Geocryology, 2014, 36(5): 1271-1279. ]
[24]	Burnik Šturm M, Ganbaatar O, Voigt C C, et al. First field-based observations of δ²H and δ¹⁸O values of event-based precipitation, rivers and other water bodies in the Dzungarian Gobi, SW Mongolia[J]. Isotopes in Environmental and Health Studies, 2017, 53(2): 157-171. doi: 10.1080/10256016.2016.1231184
[25]	Malygina N S, Eirikh A N, Kurepina N Y, et al. Isotopic composition of precipitation in Altai foothills: Observation and interpolation data[J]. Bulletin of the Tomsk Polytechnic University, Geo Assets Engineering, 2019, 330(2): 44-54.
[26]	IAEA/WMO. Global network of isotopes in precipitation[DB/OL]. [2021-5-24]. http://www.iaea.org/water.
[27]	Bowen G J, Wilkinson B. Spatial distribution of δ¹⁸O in meteoric precipitation[J]. Geology, 2002, 30(4): 315-318. doi: 10.1130/0091-7613(2002)030<0315:SDOOIM>2.0.CO;2
[28]	Terzer S, Wassenaar L I, Araguás-Araguás L J, et al. Global isoscapes for δ¹⁸O and δ²H in precipitation: Improved prediction using regionalized climatic regression models[J]. Hydrology and Earth System Sciences, 2013, 17(11): 4713-4728. doi: 10.5194/hess-17-4713-2013
[29]	Harris I, Jones P D, Osborn T J, et al. Updated high-resolution grids of monthly climatic observations the CRU TS3.10 Dataset[J]. International Journal of Climatology, 2014, 34(3): 623-642. doi: 10.1002/joc.3711
[30]	Draxler R R, Hess G D. An overview of the HYSPLIT_4 modelling system for trajectories[J]. Australian Meteorological Magazine, 1998, 47(4): 295-308.
[31]	张亚宁, 张明军, 王圣杰, 等. 基于比湿订正拉格朗日模型的新疆短时强降水的水汽来源[J]. 干旱区研究, 2019, 36(3): 698-711.
	[ Zhang Yaning, Zhang Mingjun, Wang Shengjie, et al. Water vapor sources of short-time heavy rainfall in Xinjiang based on specific humidity-adjusted Lagrangian model[J]. Arid Zone Research, 2019, 36(3): 698-711. ]
[32]	Wang S J, Zhang M J, Che Y J, et al. Influence of below-cloud evaporation on deuterium excess in precipitation of arid Central Asia and its meteorological controls[J]. Journal of Hydrometeorology, 2016, 17(7): 1973-1984. doi: 10.1175/JHM-D-15-0203.1
[33]	Kleist D T, Parrish D F, Derber J C, et al. Introduction of the GSI into the NCEP global data assimilation system[J]. Weather and Forecasting, 2009, 24(6): 1691-1705. doi: 10.1175/2009WAF2222201.1
[34]	Dansgaard W. Stable isotopes in precipitation[J]. Tellus, 1964, 16(4): 436-468. doi: 10.3402/tellusa.v16i4.8993
[35]	Craig H. Isotopic variations in meteoric waters[J]. Science, 1961, 133(3465): 1702-1703. pmid: 17814749

站点	纬度/°N	经度/°E	海拔/m	气温/℃	降水量/mm
Takhin Tal^[24]	45.5	93.7	1760	-1.7	138.8
阿勒泰^[22]	47.7	88.1	735	5.8	168.1
Zonalnoe^[25]	52.3	85.1	270	3.3	524.5
Novosibirsk^[26]	55.1	82.9	162	1.8	525.5

站点	模拟产品	R²		MAE/‰		MBE/‰		RMSE/‰
站点	模拟产品	δ¹⁸O	d	δ¹⁸O	d	δ¹⁸O	d	δ¹⁸O	d
Takhin Tal	OIPC	0.86	0.23	3.58	31.19	-1.66	-29.74	3.59	30.69
Takhin Tal	RCWIP	0.79	0.52	3.44	19.58	-2.94	-19.58	4.81	19.98
阿勒泰	OIPC	0.89	0.29	1.65	4.21	-0.41	-0.24	2.16	4.77
阿勒泰	RCWIP	0.93	0.06	1.54	4.98	1.13	3.59	2.04	6.49
Zonalnoe	OIPC	0.71	0.45	2.17	8.61	0.96	-8.61	3.02	9.08
Zonalnoe	RCWIP	0.77	0.41	2.28	3.04	-0.54	-1.62	2.65	3.32
Novosibirsk	OIPC	0.81	0.02	2.05	6.20	0.78	-1.73	2.39	8.44
Novosibirsk	RCWIP	0.85	0.08	2.39	11.36	-1.45	7.13	3.08	12.53

月份	Takhin Tal		阿勒泰		Zonalnoe		Novosibirsk
月份	水汽来源	贡献率/%	水汽来源	贡献率/%	水汽来源	贡献率/%	水汽来源	贡献率/%
1	西风水汽	54	西风水汽	42	西风水汽	49	西风水汽	69
1	近源水汽	46	近源水汽	58	极地水汽	51	极地水汽	31
4	西风水汽	59	西风水汽	41	西风水汽	69	西风水汽	33
4	近源水汽	41	近源水汽	59	极地水汽	31	极地水汽	67
7	西风水汽	34	西风水汽	29	西风水汽	35	西风水汽	60
7	近源水汽	66	近源水汽	71	近源水汽	65	极地水汽	40
10	西风水汽	55	西风水汽	46	西风水汽	60	西风水汽	52
10	近源水汽	45	近源水汽	54	极地水汽	40	极地水汽	48

Stable hydrogen and oxygen isotopes in precipitation and water vapor source in the Altay Mountains

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 35

Related Articles 5

Metrics

Comments

Recommended 0

[1]	LI Haihua,MIN Yue,LI Anbei,LI Ruqi. Comparative analysis of on water vapor characteristics of two extreme rainstorms in the north slope of Kunlun Mountains [J]. Arid Land Geography, 2022, 45(3): 715-724.
[2]	GAO Yang,HAN Lei,HAN Yonggui,HUANG Xiaoyu,PENG Ling,LIU Lili. Time scale effect of hydrogen and oxygen stable isotopes in precipitation and source of water vapor in Yinchuan Plain [J]. Arid Land Geography, 2022, 45(1): 91-102.
[3]	MENG Hong-fei, ZHANG Ming-jun, WANG Sheng-jie, QIU Xue, DU Ming-xia, ZHANG Ya-ning, YU Xiu-xiu, ZHOU Su. Isotopic characteristics of water vapor and its sources during day and night along the Heihe River in summer [J]. Arid Land Geography, 2020, 43(2): 360-370.
[4]	ZHANG Ya-ru, CHEN Yong-jin, LIU Yong-fang, LIU Zhi-yuan, LIU Yong-chang, SUN Tong. Formation and dissipation processes of a severe atmospheric pollution in north China under the influence of dust [J]. 干旱区地理, 2018, 41(6): 1241-1250.
[5]	HUANG Li-ping, GAO Ya-qi, LI Yun, ZHANG Tong-wen, HU Dong-yu, WANG Lei. Growth of Siberia Larch in the middle east of Altay Mountains and its response to climate change [J]. , 2015, 38(6): 1169-1178.