Page 20 - 《高原气象》2026年第2期
P. 20
高 原 气 象 45 卷
320
9045. 2019. 05. 012. Wu M W, Luo Y L, 2019. Extreme hourly vation system for natural resources on the Tibetan Plateau[J].
precipitation over China: research progress from 2010 to 2019 Pratacultural Science, 39: 2645-2658. DOI: 10. 11829/j. issn.
[J]. Torrential Rain and Disasters, 38(5): 502-514. DOI: 10. 1001-0629. 2022-0186.
3969/j. issn. 1004-9045. 2019. 05. 012. 杨晨, 董晓华, 董立俊, 等, 2023. 雅砻江流域 1961-2018 年极端气
吴小丽, 刘桂民, 李新星, 等, 2021. 青藏高原多年冻土和季节性冻 候时空演变研究[J]. 中国农村水利水电, 46-56+65. DOI: 10.
土区土壤水分变化及其与降水的关系[J]. 水文, 41(1): 73- 12396/znsd. 220706. Yang C, Dong X H, Dong L J, et al, 2023.
78, 101. Wu X L, Liu G M, Li X X, et al, 2021. Soil moisture Spatiotemporal evolution of extreme climate in Yalong River Ba‐
variation and its relationship with precipitation in permafrost and sin during 1961-2018[J]. China Rural Water and Hydropower,
seasonally frozen ground regions of the Tibetan Plateau[J]. Jour‐ 46-56+65. DOI: 10. 12396/znsd. 220706.
nal of China Hydrology, 41(1): 73-78, 101. 杨健, 马耀明, 2012. 青藏高原典型下垫面的土壤温湿特征[J]. 冰
熊安元, 冯爱霞, 高梅, 等, 2021. 青藏高原地气系统气象科学数据 川 冻 土 , 34(4): 813-820. DOI: 10. 7522/j. issn. 1000-0240.
集成和共享[J]. 高原气象, 40(4): 724-736. DOI: 10. 7522/j. 2012. 0099. Yang J, Ma Y M, 2012. Soil temperature and mois‐
issn. 1000-0534. 2020. 00079. Xiong A Y, Feng A X, Gao M, et ture characteristics under typical underlying surfaces on the Tibet‐
al, 2021. Integration and sharing of meteorological scientific data an Plateau[J]. Journal of Glaciology and Geocryology, 34(4):
in the land-atmosphere system over the Tibetan Plateau[J]. Pla‐ 813-820. DOI: 10. 7522/j. issn. 1000-0240. 2012. 0099.
teau Meteorology, 40(4): 724-736. DOI: 10. 7522/j. issn. 杨亮, 刘丽男, 孙少波, 2023. 1982-2015 年青藏高原植被变化的主
1000-0534. 2020. 00079. 导环境因子[J]. 生态学报, 43(2): 744-755. DOI: 10. 5846/
徐丽娇, 胡泽勇, 赵亚楠, 等, 2019. 1961-2010 年青藏高原气候变 stxb202110182938. Yang L, Liu L N, Sun S B, 2023. The domi‐
化特征分析[J]. 高原气象, 38(5): 911-919. DOI: 10. 7522/j. nated environmental factors of vegetation change on the Qinghai-
issn. 1000-0534. 2018. 00137. Xu L J, Hu Z Y, Zhao Y N, et Tibet Plateau from 1982 to 2015[J]. Acta Ecologica Sinica, 43
al, 2019. Climate change characteristics over the Tibetan Plateau (2): 744-755. DOI: 10. 5846/stxb202110182938.
during 1961-2010[J]. Plateau Meteorology, 38(5): 911-919. 杨楠, 范广洲, 2019. 2000-2016年青藏高原土壤温度变化特征分析
DOI: 10. 7522/j. issn. 1000-0534. 2018. 00137. [J]. 西南大学学报(自然科学版), 41(9): 40-51. Yang N, Fan
徐祥德, 董李丽, 赵阳, 等, 2019. 青藏高原"亚洲水塔"效应和大气 G Z, 2019. Variation characteristics of soil temperature over the
水分循环特征[J]. 科学通报, 64: 2830-2841. DOI: 10. 1360/ Tibetan Plateau during 2000-2016[J]. Journal of Southwest Uni‐
TB-2019-0203. Xu X D, Dong L L, Zhao Y, et al, 2019. The versity (Natural Science Edition), 41(9): 40-51.
"Asian water tower" effect and atmospheric water cycle character‐ 杨耀先, 胡泽勇, 路富全, 等, 2022. 青藏高原近 60 年来气候变化
istics over the Tibetan Plateau[J]. Chinese Science Bulletin, 64 及其环境影响研究进展[J]. 高原气象, 41(1): 1-10. DOI: 10.
(27): 2830-2841. DOI: 10. 1360/TB-2019-0203. 7522/j. issn. 1000-0534. 2021. 00117. Yang Y X, Hu Z Y, Lu F
许凤林, 张国庆, 2024. 青藏高原湖泊的持续扩张与其潜在影响 Q, et al, 2022. Research progress on climate change and its envi‐
[J]. 科学通报, 69(27): 3999-4001. DOI: 10. 1360/TB-2024- ronmental effects over the Tibetan Plateau in recent 60 years[J].
0600. Xu F L, Zhang G Q, 2024. Continuous expansion of lakes Plateau Meteorology, 41(1): 1-10. DOI: 10. 7522/j. issn. 1000-
on the Qinghai-Xizang Plateau and potential impacts[J]. Chinese 0534. 2021. 00117.
Science Bulletin, 69(27): 3999-4001. DOI: 10. 1360/TB- 杨昭明, 张调风, 2021. 1961-2017年青藏高原东北部雨季降水量变
2024-0600. 化及其贡献度分析[J]. 干旱区研究, 38: 22-28. DOI: 10.
许建伟, 高艳红, 彭保发, 等, 2020. 1979-2016 年青藏高原降水的 13866/j. azr. 2021. 01. 03. Yang Z M, Zhang T F, 2021. Varia‐
变化特征及成因分析[J]. 高原气象, 39(2): 234-244. DOI: tion and contribution analysis of rainy season precipitation over
10. 7522/j. issn. 1000-0534. 2019. 00029. Xu J W, Gao Y H, northeastern Tibetan Plateau during 1961-2017[J]. Arid Zone Re‐
Peng B F, et al, 2020. Variation characteristics and causes of pre‐ search, 38: 22-28. DOI: 10. 13866/j. azr. 2021. 01. 03.
cipitation over the Tibetan Plateau during 1979-2016[J]. Plateau 姚檀栋, 陈发虎, 崔鹏, 等, 2017. 从青藏高原到第三极和泛第三极
Meteorology, 39(2): 234-244. DOI: 10. 7522/j. issn. 1000- [J]. 中国科学院院刊, 32: 924-931. DOI: 10. 16418/j. issn.
0534. 2019. 00029. 1000-3045. 2017. 09. 001. Yao T D, Chen F H, Cui P, et al,
杨斌, 陈映, 潭昌海, 等, 2021. 青藏高原自然资源要素综合观测实 2017. From Tibetan Plateau to Third Pole and Pan-Third Pole[J].
施进展与展望[J]. 中国地质调查, 8: 37-46. DOI: 10. 19388/j. Bulletin of Chinese Academy of Sciences, 32: 924-931. DOI:
zgdzdc. 2021. 02. 07. Yang B, Chen Y, Tan C H, et al, 2021. 10. 16418/j. issn. 1000-3045. 2017. 09. 001.
Progress and prospect of comprehensive observation of natural re‐ 姚檀栋, 余武生, 邬光剑, 等, 2019. 青藏高原及周边地区近期冰川
sources elements on the Tibetan Plateau[J]. Geological Survey of 状态失常与灾变风险[J]. 科学通报, 64(27): 2770-2782.
China, 8: 37-46. DOI: 10. 19388/j. zgdzdc. 2021. 02. 07. DOI: 10. 1360/TB-2019-0246. Yao T D, Yu W S, Wu G J, et
杨斌, 谭昌海, 赵阳刚, 等, 2022. 青藏高原自然资源综合观测体系 al, 2019. Glacier anomalies and relevant disaster risks on the Ti‐
构 建 探 讨[J]. 草 业 科 学 , 39: 2645-2658. DOI: 10. 11829/j. betan Plateau and surroundings[J]. Chinese Science Bulletin, 64
issn. 1001-0629. 2022-0186. Yang B, Tan C H, Zhao Y G, et (27): 2770-2782. DOI: 10. 1360/TB-2019-0246.
al, 2022. Discussion on the construction of comprehensive obser‐ 姚秀萍, 马嘉理, 刘俏华, 等, 2021. 青藏高原夏季降水研究进展
