Page 26 - 《高原气象》2025年第5期
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                 Third Pole Environment Data Center. DOI: 10. 11888/Atmos. tp‐  徐帆, 张彦丽, 李克恭, 2024. 基于 MODIS 积雪覆盖度数据的青藏
                 dc. 300398.                                       高原两套被动微波雪深产品降尺度对比研究[J]. 冰川冻土, 46
             沈鎏澄, 2020. 海拔依赖型增暖背景下青藏高原积雪深度时空变化                    (1):  65-76. DOI:  10. 7522/j. issn. 1000-0240. 2024. 0006. Xu
                 特征及成因分析[D]. 金华: 浙江师范大学 . Shen L C. 2020.          F, Zhang Y L, Li K G, 2024. Comparison studies of two down‐
                 Spatial and temporal variation of snow depth over the Tibetan pla‐  scaled passive microwave snow depth products over the Qinghai-
                 teau  and  its  causes  under  the  background  of  altitude-dependent   Xizang  Plateau  based  on  MODIS  fractional  snow  cover  dataset
                 warming[D]. Jinhua: Zhejiang Normal University.  [J]. Journal  of  Glaciology  and  Geocryology,  46(1):  65-76.
             史飞飞, 李晓东, 肖建设, 等, 2024. 基于 MOD10A1V6产品下青海             DOI: 10. 7522/j. issn. 1000-0240. 2024. 0006.
                 省各片区积雪的分布气候特征[J]. 生态科学, 43(4): 27-38.          周秉荣, 袁佳双, 乔斌, 等, 2024. 青藏高原气候与冰冻圈变化研究
                 DOI: 10. 14108/j. cnki. 1008-8873. 2024. 04. 004. Shi F F, Li X   进展[J]. 环境科学研究, 37(9): 1885-1896. DOI: 10. 13198/j.
                 D, Xiao J S, et al, 2024. Climate characteristics of snow cover   issn. 1001-6929. 2024. 05. 02. Zhou B R, Yuan J S, Qiao B, et
                 distribution  in  ecological  function  areas  of  Qinghai  Province   al, 2024. Research Progress on Climate and Cryosphere Changes
                 based on MOD10A1 V6[J]. Ecological Science, 43(4): 27-38.  in  the  Qinghai-Tibetan  Plateau[J]. Research  of  Environmental
                 DOI: 10. 14108/j. cnki. 1008-8873. 2024. 04. 004.  Sciences,  37(9):  1885-1896. DOI:  10. 13198/j. issn. 1001-
             王建, 车涛, 李震, 等, 2018. 中国积雪特性及分布调查[J]. 地球科              6929. 2024. 05. 02.
                 学 进 展 ,  33(1):  12-26. DOI:  10. 11867/j. issn. 1001-8166.  张霞, 段建平, 马柱国, 2023. 基于日干旱指数的青藏高原 1979-
                 2018. 01. 0012. Wang J, Che T, Li Z, et al, 2018. Investigation   2020 年干湿变化特征分析[J]. 高原气象, 42(4): 870-886.
                 on  snow  characteristics  and  their  distribution  in  China[J]. Ad‐  Zhang X, Duan J P, Ma Z G, 2023. A daily drought index-based
                 vances in Earth Science, 33(1): 12-26. DOI: 10. 11867 /j. issn.  dry  and  wet  variation  analyses  over  the  Qinghai-Xizang  Plateau
                 1001-8166. 2018. 01. 0012.                        from 1979 to 2020[J]. Plateau Meteorology, 42(4): 870-886.
             王宁练, 盛煜, 金汇军, 等, 2023. 祁连山水塔变化及其影响[M].                DOI: 10. 7522/j. issn. 1000-0534. 2022. 00093.
                 北京: 科学出版社 . Wang N L, Sheng Y, Jin H J, et al, 2023.  张国庆, 2019. 青藏高原流域边界数据集(2016)[Z]. 时空三极环境
                 Changes in Qilian Mountains water tower and their impacts[M].  大数据平台 .[2024-11-28]. DOI: 10. 11888/BaseGeography.
                 Beijing: Science Press.                           tpe. 249465. file. Zhang  G  Q,  2019. A  dataset  of  watershed
             王静, 车涛, 戴礼云, 等, 2023. 被动微波遥感反演雪深与气象站观                 boundaries on the Tibetan Plateau (2016)[Z]. Third Pole Envi‐
                 测雪深时空对比[J]. 遥感学报, 27(9): 2060-2071. DOI: 10.      ronment Data Center.[2024-11-28]. DOI: 10. 11888/BaseGeog‐
                 11834/jrs. 20221653. Wang J, Che T, Dai L Y, et al, 2023. Spa‐  raphy. tpe. 249465. file.
                 tio-temporal  comparison  of  snow  depth  between  passive  micro‐  张镱锂, 2019. 青藏高原边界数据总集[Z]. 时空三极环境大数据平
                 wave remote sensing inversion data and meteorological station ob‐  台 . DOI:  10. 11888/Geogra. tpdc. 270099. Zhang  Y  L,  2019.
                 servation  data[J]. National  Remote  Sensing  Bulletin,  27(9):   Tibetan plateau boundary dataset[Z]. Third Pole Environment Da‐
                 2060-2071. DOI: 10. 11834/jrs. 20221653.          ta Center. DOI: 10. 11888/Geogra. tpdc. 270099.
             王芝兰, 张飞民, 王澄海, 等, 2022. 1980-2019 年青藏高原积雪深         张镱锂, 李炳元, 刘林山, 等, 2021. 再论青藏高原范围[J]. 地理研
                 度时空差异性分析[J]. 冰川冻土, 44(3): 810-821. DOI: 10.       究, 40(6): 1543-1553. DOI: 10. 11821/dlyj020210138. Zhang
                 7522/j. issn. 1000-0240. 2022. 0079. Wang  Z  L,  Zhang  F  M,   Y L, Li B Y, Liu L S, et al, 2021. Redetermine the region and
                 Wang C H, et al, 2022. Analysis on spatial and temporal differ‐  boundaries  of  Tibetan  Plateau[J]. Geographical  Research,  40
                 ence of snow depth over the Tibetan Plateau from 1980 to 2019  (6): 1543-1553. DOI: 10. 11821/dlyj020210138.
                [J]. Journal of Glaciology and Geocryology, 44(3): 810-821.  张群慧, 常亮, 顾小凡, 等, 2024. 1979-2020 年柴达木盆地人体舒
                 DOI: 10. 7522/j. issn. 1000-0240. 2022. 0079.     适度指数时空变化及趋势分析[J]. 干旱区研究, 41(8): 1300-
             魏莹, 2020. 1980-2018 年青藏高原气温时空变化特征及其未来预                1308. DOI: 10. 13866/j. azr. 2024. 08. 04. Zhang Q H, Chang L,
                 估[D]. 咸阳: 陕西师范大学 . Wei Y, 2020. Temporal and spa‐  Gu  X  F,  et  al,  2024. Spatial-temporal  variations  and  trends  in
                 tial  variation  characteristics  of  air  temperature  over  the  Tibetan   the human body comfort index in the Qaidam Basin, China, dur‐
                 Plateau  from  1980  to  2018  and  its  future  prediction[D]. Xian‐  ing  1979-2020[J]. Arid  Zone  Research,  41(8):  1300-1308.
                 yang: Shaanxi Normal University.                  DOI: 10. 13866/j. azr. 2024. 08. 04.
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