黄河流域环境变化与地貌过程
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黄河流域环境变化与地貌过程

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代表性成果

团队成员发表一作和通讯作者论文统计

团队负责人:潘保田

93. Zhang Y, Geng H, Cai S, Pan B. Tan DEM-X preserves the relationship between hilltop curvature and erosion rate in

   the Qilian Shan. Journal of Geophysical Research: Earth Surface, 2023, 128(9): e2023JF007118.

92. Pan B, Li X, Hu Z, et al. Channel migration in the northeastern margin of the Tibetan Plateau and its implication 

   for fluvial response to the interaction between rapid tectonic activity, climatic fluctuation and human influence.

   Quaternary Science Reviews, 2023, 310: 108126.

91. Pan B, Guan W, Shi M, et al. Different characteristics of two surges in Weigeledangxiong Glacier, northeastern 

   Tibetan Plateau. Environmental Research Letters, 2022, 17(11): 114009.

90. Guan W, Cao B, Pan B, et al. Updated surge-type glacier inventory in the West Kunlun Mountains, Tibetan Plateau, 

   and implications for glacier change. Journal of Geophysical Research: Earth Surface, 2022, 127(1): e2021JF006369.

89. Tian L, Zhang B, Chen S, Wang X, Ma X, Pan B. LargeScale Afforestation Enhances Precipitation by Intensifying the

   Atmospheric Water Cycle Over the Chinese Loess Plateau. Journal of Geophysical Research: Atmospheres, 2022, 127

   (16): e2022JD036738.

88. Wen Z, Chen D, Guo L, Pan B, Hu X, Li Q, Ji X, Jiaming Yang. Response of terrace deposit thickness to climate 

   change and tectonic deformation: An example of the Liyuan River in the Northeast Tibetan Plateau. Terra Nova, 

   2022, 34(1): 37-46.

87. Geng, H., Cai, S., Lü, H., Pan, B. (2022). How can a youthful mountain survive in a foreland setting?-Constraining

   the uplift threshold rate by numerical simulation. Science bulletin, 67 12, 1233-1235.

86. Pan B, Guan W, Shi M, et al. Different characteristics of two surges in Weigeledangxiong Glacier, northeastern 

   Tibetan Plateau. Environmental Research Letters, 2022, 17(11): 114009.

85. Pan B, Zhao Q, Hu X, et al. Uplift and Expansion of the North Qilian Shan Recorded by Detrital Fission Tracks in 

   the Jiudong Basin, NW China. Frontiers in Earth Science, 2022, 9: 826104.

84. Dong Z, Pan B, Hu Z, et al. Evaluation of the Fluvial Response to Tectonic Uplift From Grain-Size Distribution in 

   Riverbed Gravels at the Northeastern Margin of the Tibetan Plateau. Continental Basin and Orogenic Processes: 

   Tectonic Deformation and Associated Landscape and Environmental Evolution, 2022, 10: 824368.

83. Pan B, Cai S, Geng H. Numerical simulation of landscape evolution and mountain uplift history constrain—A case 

   study from the youthful stage mountains around the central Hexi Corridor, NE Tibetan Plateau. Science China Earth

   Sciences, 2021, 64: 412-424.

82. Hu, X., Cao, X., Li, T., Mao, J., Zhang, J., He, X., Zhang, Y. n., and Pan, B., 2021, Late Quaternary Fault Slip 

   Rate Within the Qilian Orogen, Insight Into the Deformation Kinematics for the NE Tibetan Plateau: Tectonics, v. 

   40, no. 5, p. e2020TC006586.

81. Gao, P., Nie, J., Yan, Q., Zhang, X., Liu, Q., Cao, B., and Pan, B., 2021, Millennial Resolution Late Miocene 

   Northern China Precipitation Record Spanning Astronomical Analogue Interval to the Future: Geophysical Research 

   Letters, v. 48, no. 15, p. e2021GL093942.

80. Cao X, Hu X, Pan B, et al. Using fluvial terraces as distributed deformation offset markers: Implications for 

   deformation kinematics of the North Qilian Shan Fault. Geomorphology, 2021, 386: 107750.

79. Cao, B.; Guan, W.; Li, K.; Wen, Z.; Han, H.; Pan, B. Area and Mass Changes of Glaciers in the West Kunlun Mountains

   Based on the Analysis of Multi-Temporal Remote Sensing Images and DEMs from 1970 to 2018. Remote Sens. 2020, 12, 

   2632.

78. Hu X, Chen D, Pan B, et al. Sedimentary evolution of the foreland basin in the NE Tibetan Plateau and the growth of

   the Qilian Shan since 7 Ma. GSA Bulletin, 2019, 131(9-10): 1744-1760.

77. Hu, Z., Li, M., Dong, Z., Guo, L., Bridgland, D., Pan, B., Li, X., and Liu, X., 2019, Fluvial entrenchment and 

   integration of the Sanmen Gorge, the Lower Yellow River: Global and Planetary Change, v. 178, p. 129-138.

76. Cao X, Hu X, Pan B, et al. A fluvial record of fault-propagation folding along the northern Qilian Shan front, NE 

   Tibetan Plateau. Tectonophysics, 2019, 755: 35-46.

75. Cao B, Pan B, Wen Z, et al. Changes in glacier mass in the Lenglongling Mountains from 1972 to 2016 based on remote

   sensing data and modeling. Journal of Hydrology, 2019, 578: 124010.

74. Cao B, Pan B, Guan W, et al. Changes in glacier volume on Mt. Gongga, southeastern Tibetan Plateau, based on the an

   alysis of multi-temporal DEMs from 1966 to 2015. Journal of Glaciology, 2019, 65(251): 366-375.

73. Li Q, Pan B, Gao H, et al. Differential rock uplift along the northeastern margin of the Tibetan Plateau inferred 

   from bedrock channel longitudinal profiles. Journal of Asian Earth Sciences, 2019, 169: 182-198.

72. Hu Z B, Pan B T, Bridgland D, et al. The linking of the upper-middle and lower reaches of the Yellow River as a 

   result of fluvial entrenchment. Quaternary Science Reviews, 2017, 166: 324-338.

71. Gao, H., Li, Z., Liu, X., Pan, B., Wu, Y., and Liu, F., 2017, Fluvial terraces and their implications for Weihe 

   River valley evolution in the Sanyangchuan Basin: Science China Earth Sciences, v. 60, no. 3, p. 413-427.

70. Cao B, Pan B, Cai M, et al. An investigation on changes in glacier mass balance and hypsometry for a small 

   mountainous glacier in the northeastern Tibetan Plateau. Journal of Mountain Science, 2017, 14(8): 1624-1632.

69. Hu Z, Pan B, Guo L, et al. Rapid fluvial incision and headward erosion by the Yellow River along the Jinshaan gorge

   during the past 1.2 Ma as a result of tectonic extension. Quaternary Science Reviews, 2016, 133: 1-14.

68. Pan B, Pang H, Gao H, et al. Heavy-mineral analysis and provenance of Yellow River sediments around the China Loess

   Plateau. Journal of Asian Earth Sciences, 2016, 127: 1-11.

67. Pan B, Chen D, Hu X, et al. Drainage evolution of the Heihe River in western Hexi Corridor, China, derived from 

   sedimentary and magnetostratigraphic results. Quaternary Science Reviews, 2016, 150: 250-263.

66. Pan B, Pang H, Zhang D, et al. Sediment grain-size characteristics and its source implication in the Ningxia-Inner

   Mongolia sections on the upper reaches of the Yellow River. Geomorphology, 2015, 246: 255-262.

65. Pan B, Li Q, Hu X, et al. Bedrock channels response to differential rock uplift in eastern Qilian Mountain along 

   the northeastern margin of the Tibetan Plateau. Journal of Asian Earth Sciences, 2015, 100: 1-19.

64. Zhang G, Pan B, Cao B, et al. Elevation changes measured during 1966–2010 on the monsoonal temperate glaciers' 

   ablation region, Gongga Mountains, China. Quaternary International, 2015, 371: 49-57.

63. Pan B, Guan Q, Liu Z, et al. Analysis of channel evolution characteristics in the Hobq Desert reach of the Yellow 

   River (1962–2000). Global and Planetary Change, 2015, 135: 148-158.

62. Geng H, Pan B, Milledge D G, et al. Quantifying sheet wash erosion rates in a mountainous semiarid basin using 

   environmental radionuclides and a stream power model.Earth surface processes and landforms,2015,40(13):1814-18 26.61. Cao B, Pan B, Wang J, et al. Changes in the glacier extent and surface elevation along the Ningchan and Shuiguan 

   river source, eastern Qilian Mountains, China. Quaternary Research, 2014, 81(3): 531-537.

60. Pan B, Guan Q, Gao H, et al. The origin and sources of loesslike sediment in the Jinsha River Valley, SW China. 

   Boreas, 2014, 43(1): 121-131.

59. Pan B, Hu X, Gao H, et al. Late Quaternary river incision rates and rock uplift pattern of the eastern Qilian Shan

   Mountain, China. Geomorphology, 2013, 184: 84-97.

58. Pan B, Qingyang L, Xiaofei H, et al. Cretaceous and Cenozoic cooling history of the eastern Qilian Shan, 

   north-eastern margin of the Tibetan Plateau: evidence from apatite fissiontrack analysis. Terra Nova, 2013, 

   25(6): 431-438.

57. Guan Q, Pan B, Yang J, et al. The processes and mechanisms of severe sandstorm development in the eastern Hexi 

   Corridor China, during the Last Glacial period. Journal of Asian Earth Sciences, 2013, 62: 769-775.

56. Pan B, Hu Z, Wang J, et al. The approximate age of the planation surface and the incision of the Yellow River. 

   Palaeogeography, Palaeoclimatology, Palaeoecology, 2012, 356: 54-61.

55. Pan B, Cao B, Wang J, et al. Glacier variations in response to climate change from 1972 to 2007 in the western 

   Lenglongling mountains, northeastern Tibetan Plateau. Journal of Glaciology, 2012, 58(211): 879-888.

54. Pan B, Zhang G L, Wang J, et al. Glacier changes from 1966–2009 in the Gongga Mountains, on the south-eastern 

   margin of the Qinghai-Tibetan Plateau and their climatic forcing. The Cryosphere, 2012, 6(5): 1087-1101.

53. Pan B, Hu Z, Wang J, et al. A magnetostratigraphic record of landscape development in the eastern Ordos Plateau, 

   China:Transition from Late Miocene and Early Pliocene stacked sedimentation to Late Pliocene and Quaternary uplift

   and incision by the Yellow River. Geomorphology, 2011, 125(1): 225-238.

52. Qingyu G, Pan B, Na L, et al. Timing and significance of the initiation of present day deserts in the northeastern

   Hexi Corridor, China. Palaeogeography, Palaeoclimatology, Palaeoecology, 2011, 306(1-2): 70-74.

51. Qingyu G, Pan B, Na L, et al. A warming interval during the MIS 5a/4 transition in two high-resolution loess 

   sections from China. Journal of Asian Earth Sciences, 2010, 38(6): 255-261.

50. Yu G Q, Pan B, Na L, et al. Pattern of abrupt climatic fluctuation in the East Asian Monsoon during the Last

   Glacial: Evidence from Chinese loess records. Comptes Rendus Geoscience, 2010, 342(3): 189-196.

49. Pan B, Geng H, Hu X, et al. The topographic controls on the decadal-scale erosion rates in Qilian Shan Mountains, 

   NW China. Earth and Planetary Science Letters, 2010, 292(1-2): 148-157.

48. 高阳,蔡顺,潘保田,熊巨华.地貌学领域自然科学基金项目申请资助、研究范式与启示.科学通报

47. 洪洋,耿豪鹏,潘保田.寒冻风化控制的祁连山风化碎屑的空间分布.冰川冻土,2022,44(04):1347-1356.

46. 潘保田,郭明宙,乔振峰.创新高等理科教育 提高人才培养能力.高等理科教育,2021(05):1-7.

45. 潘保田,曹泊,管伟瑾.20102020年祁连山东段冷龙岭宁缠河1号冰川变化综合观测研究.冰川冻土,2021,43(03):864-873.

44. 秦大河,姚檀栋,周尚哲,陈发虎,潘保田,康世昌.李吉均先生纪念专刊·编者按.冰川冻土,2021,43(03):681-682.

43. 潘保田,胡振波.黄河中游响应气候变化和地表相对抬升发育阶地研究.冰川冻土,2021,43(03):853-863.

42. 樊云龙,潘保田,胡振波,任大银,陈起伟,刘芬良,李宗盟.云贵高原北盘江流域构造地貌特征分析.地球科学进展,2018,33(07):751-76

   1.

41. 高红山,李宗盟,刘小丰,潘保田,吴雅婕,刘芬良.三阳川盆地渭河阶地发育与河谷地貌演化.中国科学:地球科学,2017,47(02):191-20

   4.

40. 潘保田.完善治理结构 加快现代大学制度建设步伐.世界教育信息,2014,27(01):69-70.

39. 吉亚鹏,高红山,潘保田,李宗盟,管东升,杜功元.渭河上游流域河长坡降指标SL参数与Hack剖面的新构造意义.兰州大学学报(自然科

   学版),2011,47(04):1-6.

38. 曹泊,潘保田,高红山,姜少飞,温煜华,上官冬辉.1972-2007年祁连山东段冷龙岭现代冰川变化研究.冰川冻土,2010,32(02):242-248.

37. 耿豪鹏,潘保田,王超,黄波.基于GISUSLE的榆中县土壤侵蚀.兰州大学学报(自然科学版),2009,45(06):8-13.

36. 李琼, 潘保田, 程维明. 基于RSGIS1:100万数字地貌制图方法——以兰州幅(J48)为例. 兰州大学学报:自然科学版, 2009

   (5):7.

35. 管清玉,潘保田,徐树建,邬光剑,李娜,赵明,徐先英,潘俊斌.腾格里沙漠南部(河西走廊东段)沙尘暴代用指标初探.自然科学进展,

   2009,19(01):69-74.

34. 刘锋,潘保田,苏怀.兰州地区黄河第五级小沙沟阶地古地磁年代研究.中国沙漠,2008(05):821-826.

33. 胡小飞,潘保田.磷灰石(U-Th)/He热年代学方法及其在地貌演化研究中的应用.原子能科学技术,2008(07):662-664.

32. 潘保田,李万里,徐鹏彬.以科技创新提升高校科研水平——兰州大学科研实践的思考.研究与发展管理,2008(02):118-121.

31. 褚娜娜,潘保田,王均平,胡振波,苏怀,周天,胡小飞.汾渭盆地黄土剖面0.9Ma前后的粒度突变及其环境意义.中国沙漠,2008(01):50-

   56.

30. 潘保田,刘小丰,高红山,王勇,李吉均.渭河上游陇西段河流阶地的形成时代及其成因.自然科学进展,2007(08):1063-1068.

29. 刘小丰,潘保田,高红山,王勇,张慧,王均平.渭河河流沉积物对气候变化的响应分析.干旱区资源与环境,2007(05):6-9.

28. 刘小丰,潘保田,高红山,王勇,王均平,张慧,胡春生.渭河L9时期(0.87~0.94Ma)古洪水事件的特征研究.干旱区地理,2007(02):

   247-250.

27. 潘保田,苏怀,刘小丰,胡小飞,周天,胡春生,李吉均.兰州东盆地最近1.2Ma的黄河阶地序列与形成原因.第四纪研究,2007(02):

   172-180.

26. 李琼,潘保田,高红山,徐树建.腾格里沙漠南缘末次冰盛期以来沙漠演化与气候变化.中国沙漠,2006(06):875-879.

25. 潘保田,苏怀,胡春生,胡小飞,周天,李吉均.兰州地区10Ma黄河阶地的发现和08Ma阶地形成时代的重新厘定.自然科学进展,2006

   (11):1411-1418.

24. 潘保田,王均平,高红山,陈莹莹,李吉均,刘小丰.从三门峡黄河阶地的年代看黄河何时东流入海.自然科学进展,2005(06):700-705.

23. 高红山,潘保田,邬光剑,李吉均,李炳元,Douglas Burbank,业渝光.祁连山东段河流阶地的形成时代与机制探讨.地理科学,2005(02):

   197-202.

22. 高红山,潘保田,李吉均,邬光剑,李炳元,业渝光.祁连山东段金塔河流域层状地貌时代与成因探讨.山地学报,2005(02):129-135.

21. 潘保田,王均平,高红山,管清玉,王勇,苏怀,李炳元,李吉均.河南扣马黄河最高级阶地古地磁年代及其对黄河贯通时代的指示.科学通报,2005(03):255-261.

20. 潘保田, 高红山, 李炳元,. 青藏高原层状地貌与高原隆升. 第四纪研究, 2004.

19. 潘保田,高红山,李吉均.关于夷平面的科学问题——兼论青藏高原夷平面.地理科学,2002(05):520-526.

18. 潘保田,邬光剑,王义祥,刘志刚,管清玉.祁连山东段沙沟河阶地的年代与成因.科学通报,2000(24):2669-2675.

17. 潘保田,李吉均,李炳元.青藏高原地面抬升证据讨论.兰州大学学报,2000(04):100-111.

16. 潘保田.代表我国冰冻圈地貌与沉积研究跃上新台阶的一部力作──《中天山冰冻圈地貌过程与沉积特征》评介.冰川冻土,2000

   (01):96.

15. 潘保田,王建民.末次间冰期以来青藏高原东部季风演化的黄土沉积记录.第四纪研究,1999(04):330-335.

14. 潘保田,陈发虎.青藏高原东北部15万年来的多年冻土演化.冰川冻土,1997(02):30-38.

13. 潘保田,邬光剑.青藏高原东北部最近两次冰期降温幅度的初步估算.干旱区地理,1997(02):17-24.

12. 潘保田,李吉均,曹继秀,陈发虎.化隆盆地地貌演化与黄河发育研究.山地研究,1996(03):153-158.

11. 潘保田,李吉均.青藏高原:全球气候变化的驱动机与放大器──Ⅲ.青藏高原隆起对气候变化的影响.兰州大学学报,1996(01):108-

   115.

10. 潘保田,石生仁,朱俊杰.河西经济带建设在大西北开发中的地位与作用.干旱区地理,1996(01):32-37.

9. 潘保田,李吉均,朱俊杰,曹继秀.青藏高原:全球气候变化的驱动机与放大器──Ⅱ.青藏高原隆起的基本过程.兰州大学学报,1995

   (04):160-167.

8. 潘保田,李吉均,陈发虎.青藏高原:全球气候变化的驱动机与放大器──Ⅰ 新生代气候变化的基本特征.兰州大学学报,1995(03):

   120-128.

7. 王乃昂,潘保田.我国高等地理教育的发展和问题.高等理科教育,1995(03):18-23.

6. 潘保田.贵德盆地地貌演化与黄河上游发育研究.干旱区地理,1994(03):43-50.

5. 潘保田,李吉均,曹继秀.黄河中游的地貌与地文期问题.兰州大学学报,1994(01):115-123.

4. 潘保田,李吉均,周尚哲.青藏高原倒数第二次冰期冰楔的发现及其意义.科学通报,1992(17):1599-1602.

3. 潘保田,徐叔鹰,陈发虎,曹继秀,张宇田.青海高原东部三万年来自然环境变迁的序列与幅度探讨.干旱区地理,1989(02):14-21.

2. 潘保田,徐叔鹰.青海高原东部晚第四纪自然环境演化探讨.科学通报,1989(07):534-536.

1. 潘保田.陇西黄土高原农业发展方向初探.地域研究与开发,1988(02):27-32.


团队骨干成员:聂军胜

78. Liu, X., Nie, J., Zhou, B. and Zhang, Z., 2023. East Asian summer monsoon variations across the Miocene−Pliocene

   boundary recorded by sediments from the Guide Basin, northeastern Tibetan Plateau. GSA Bulletin.

77. Li, M., Nie, J., Li, Z., Pullen, A., Abell, J.T., Zhang, H., McMechen, C.A. and Pan, B., 2023. A middle Pleistocene

   to Holocene perspective on sediment sources for the Tengger Desert, China. CATENA, 228: 107119.

76. Yang, J., Nie, J., Zhang, H., Rasmeni, S.K., Ncube, L., van Niekerk, H.J., Zhao, B. and Hu, X., 2023. Sr-Nd-Hf 

   isotopic constraints on the provenance of the modern Zambezi River sand sediments, southern Africa.Basin Research,

   35(3): 1053-1070.

75. Li, S., Nie, J., Ren, X., Xing, L., Tong, F. and Xiao, Y., 2023. Increased primary mineral dissolution control on 

   a terrestrial silicate lithium isotope record during the middle Miocene Climate Optimum.Geochimica et Cosmochimica

   Acta, 348: 41-53.

74. Peng, W., Zhang, H., Pullen, A., Li, M., Pan, B., Xiao, W. and Nie, J., 2023. Stepwise increased spatial provenance

   contrast on the Chinese Loess Plateau over late Miocene-Pleistocene. Communications Earth & Environment, 4(1): 60.

73. Nie, J., Wang, W., Heermance, R., Gao, P., Xing, L., Zhang, X., Zhang, R., Garzione, C. and Xiao, W., 2022. Late 

   Miocene Tarim desert wetting linked with eccentricity minimum and East Asian monsoon weakening. Nature 

   Communications, 13(1): 3977.

72. Wang, X., Nie, J., Stevens, T., Zhang, H. and Xiao, W., 2022. Resolving conflicting models of late Miocene East 

   Asian summer monsoon intensity recorded in Red Clay deposits on the Chinese Loess Plateau. Earth-Science Reviews:

   104200.

71. Zhang, H., Li, M., Peng, W., Zhang, Z. and Nie, J., 2022. No major temporal provenance variation on the Chinese 

   Loess Plateau since the late Miocene — insight from stable heavy mineral ratios. Geosystems and Geoenvironment, 

   1(2): 100022.

70. Guo, B., Nie, J., Li, J., Xiao, W., Pan, F. Expansion/shrinkage history of the Paratethys Sea during the Eocene:

   New insights from eolian Red Clay records in the Altyn Mountains, northern China. Frontiers in Earth Science, 10,

   2022.

69. Guo, B., Nie, J., Stevens, T., Buylaert, J.-P., Peng, T., Xiao, W., Pan, B., Fang, X. Dominant precessional forcing

   of the East Asian summer monsoon since 260 ka. Geology, 50(12): 1372-1376, 2022.

68. Peng, F., Nie, J., Stevens, T., Pan, B. Decoupled Chinese Loess Plateau Dust Deposition and Asian Aridification at

   Millennial and Tens of Millennial Timescales. Geophysical Research Letters, 49(20): e2022GL099338, 2022.

67. Cheng, F., Garzione, C., Li, X., Salzmann, U., Schwarz, F., Haywood, A.M., Tindall, J., Nie, J., Li, L., Wang, L.,

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10. 刘芬良,高红山,胡小飞,李宗盟,潘保田,王姣姣.金沙江攀枝花至凹嘎段水系河道纵剖面形态特征及其对河谷发育的指示.兰州大学学

   报(自然科学版),2019,55(02):149-157.

9. 李富强,高红山,张连科,李宗盟,庞红丽,潘保田.基于粒度参数特征对黄河后套平原段岩芯沉积环境的分析.沉积学报,2019,37(06):12

  34-1243.

8. 高红山,李宗盟,刘小丰,潘保田,吴雅婕,刘芬良.三阳川盆地渭河阶地发育与河谷地貌演化.中国科学:地球科学,2017,47(02):191-

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7. 高红山,潘保田,李炳元,李琼.地貌学的基本范式及其在教学科研中的作用.地理科学,2015,35(12):1591-1598.

6. 李宗盟,高红山,潘保田,张忱,刘芬良,管东升.贺兰山水系流域数值地貌特征及其构造指示意义.干旱区地理,2012,35(03):422-429.

5. 高红山,潘保田,邬光剑,李吉均,李炳元,业渝光.祁连山东段冲积扇的发育时代及其成因.兰州大学学报,2005(05):6-9.

4. 高红山,潘保田,邬光剑,李吉均,李炳元,Douglas Burbank,业渝光.祁连山东段河流阶地的形成时代与机制探讨.地理科学,2005(02):

  197-202.

3. 高红山,潘保田,李吉均,邬光剑,李炳元,业渝光.祁连山东段金塔河流域层状地貌时代与成因探讨.山地学报,2005(02):129-135.

2. 高红山,潘保田,李吉均,隋玉柱.青藏高原隆升过程与环境变化.青岛大学学报(工程技术版),2004(04):40-47.

1. 高红山,潘保田,邬光剑,李吉均,管清玉,王均平,业渝光.祁连山东段剥蚀面与青藏高原隆升.冰川冻土,2004(05):540-544.


团队骨干成员:王杰

18. Chen X J, Wang J, Zou L Y,et al.Ice flux of alpine glaciers controls erosion and landscape in the Nianbaoyeze Shan,

   northeastern Tibetan Plateau. Journal of Mountain Science, 2023, 20: 1884–1899.

17. Wang J, Wang W, Cao B, et al. Millennial-scale glacier fluctuations on the southeastern Tibetan Plateau during MIS

   2. Earth and Planetary Science Letters, 2023, 601: 117903.

16. Yao P, Wang J, Harbor J M, et al. The relative efficiency and influence of glacial and fluvial erosion on Tibetan 

   Plateau landscapes. Geomorphology, 2020, 352: 106988.

15. Cui H, Wang J, Yu B, et al. Marine Isotope Stage 3 paleotemperature inferred from reconstructing the Die Shan ice 

   cap, northeastern Tibetan Plateau. Quaternary Research, 2018, 89(2): 494-504.

14. Wang J, Yao P, Yu B, et al. Controls on spatial variations of glacial erosion in the Qilian Shan, northeastern 

   Tibetan Plateau. Geomorphology, 2018, 318: 128-138.

13. Wang J, Cui H, Harbor J M, et al. MidMIS3 climate inferred from reconstructing the Dalijia Shan ice cap, north-

   eastern Tibetan Plateau. Journal of Quaternary Science, 2015, 30(6): 558-568.

12. Wang J, Kassab C, Harbor J M, et al. Cosmogenic nuclide constraints on late Quaternary glacial chronology on the 

   Dalijia Shan, northeastern Tibetan Plateau. Quaternary Research, 2013, 79(3): 439-451.

11. Wang J, Pan B T, Zhang G L, et al. Late Quaternary glacial chronology on the eastern slope of Gongga Mountain, 

   eastern Tibetan Plateau, China. Science China Earth Sciences, 2013, 56: 354-365.

10. Wang J, Zhou S Z, Zhao J D, et al. Quaternary glacial geomorphology and glaciations of Kongur Mountain, eastern 

   Pamir, China. Science China Earth Sciences, 2011, 54: 591-602.

9. Shangzhe Z, Wang J, Xu L, et al.Glacial advances in southeastern Tibet during late Quaternary and their implications

   for climatic changes. Quaternary International, 2010, 218(1-2): 58-66.

8. 王杰,雷满红,郑利敏.山地冰川冰消后(paraglacial)沉积的粒度与石英颗粒表面特征——以贡嘎山东坡为例.冰川冻土,2022,44

  (04):1150-1164.

7. 姚盼,王杰,林文旺,曾兰华,陈仁容.基于Hkr值的北天山冰川侵蚀空间分布特征及其主控因素研究.冰川冻土,2022,44(04):1260-1269.

6. 王潍诚, 王杰. 底部剪切应力影响因素及其在中国西部冰川研究中的取值. 兰州大学学报:自然科学版, 2022, 58(1):9.

5. 崔航,王杰.基于冰川平衡线高度变化的气候重建模型研究.海洋地质与第四纪地质,2013,33(04):17-24.

4. 崔航,王杰.冰川物质平衡线的估算方法.冰川冻土,2013,35(02):345-354.

3. 曹泊,王杰,潘保田,张兴余,崔航.祁连山东段宁缠河1号冰川和水管河4号冰川表面运动速度研究.冰川冻土,2013,35(06):1428-1435.

2. 王杰,潘保田,张国梁,崔航,曹泊,耿豪鹏.贡嘎山东坡中更新世晚期以来冰川作用年代学研究.中国科学:地球科学,2012,42(12):1889-

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1. 王杰,周尚哲,赵井东,郑景雄,郭向中.东帕米尔公格尔山地区第四纪冰川地貌与冰期.中国科学:地球科学,2011,41(03):350-361.


团队骨干成员:胡小飞

21. Hu X, Zhang Y, Guo J, et al. How does climate affect the topography in tectonically active orogens. Earth Surface 

   Processes and Landforms, 2023, 45(6): 1267-1280.

20. Hu X, Wu J, Wen Z, et al. Fluvial evolution in a growing thrust-fold range of the Yumu Shan, NE Tibetan Plateau. 

   Earth and Planetary Science Letters, 2022, 594: 117704.

19. Cao X, Hu X, Pan B, et al. Spatiotemporal Variation of Late Quaternary River Incision Along the Heihe River in the

   Northeastern Tibetan Plateau, Constrained by Dating Fluvial Terraces. Frontiers in Earth Science, 2022,10: 929599.

18. Cao X, Hu X, Pan B, et al. Using fluvial terraces as distributed deformation offset markers: Implications for 

   deformation kinematics of the North Qilian Shan Fault. Geomorphology, 2021, 386: 107750.

17. Hu X, Ji X, Cao X, et al. Test on the reliability of the subsurface fault geometry estimated by deformed river 

   terraces along the Bailang River, north front of the Qilian Shan (North West China). Frontiers in Earth Science, 

   2021, 9: 665047.

16. Hu X, Cao X, Li T, et al. Late Quaternary fault slip rate within the Qilian Orogen, insight into the deformation 

   kinematics for the NE Tibetan Plateau. Tectonics, 2021, 40(5): e2020TC006586.

15. Hu X, Chen D, Pan B, et al. Sedimentary evolution of the foreland basin in the NE Tibetan Plateau and the growth of

   the Qilian Shan since 7 Ma. GSA Bulletin, 2019, 131(9-10): 1744-1760.

14. Cao X, Hu X, Pan B, et al. A fluvial record of fault-propagation folding along the northern Qilian Shan front, NE 

   Tibetan Plateau. Tectonophysics, 2019, 755: 35-46.

13. Hu X, Wen Z, Pan B, et al. Constraints on deformation kinematics across the Yumu Shan, NE Tibetan Plateau, based on

   fluvial terraces. Global and Planetary Change, 2019, 182: 103023.

12. Hu X, Kirby E, Pan B, et al. Cosmogenic burial ages reveal sediment reservoir dynamics along the Yellow River, 

   China. Geology, 2011, 39(9): 839-842.

11. Hu X, Pan B T, Kirby E, et al. Spatial differences in rock uplift rates inferred from channel steepness indices 

   along the northern flank of the Qilian Mountain, northeast Tibetan Plateau. Chinese Science Bulletin, 2010, 55: 

   3205-3214.

10. 张亚男,胡小飞,潘彦菲.北祁连山和东昆仑山的地貌特征对比及其对构造抬升的指示意义.第四纪研究,2022,42(03):809-822.

9. 贺鑫,胡小飞,潘保田.黄河兰州段河谷演化研究与认识.地球科学进展,2020,35(04):404-413.

8. 陈殿宝, 陈进军, 胡小飞, 苏航, 陈颖, 张建. 祁连山北麓梨园河沉积物粒径的变化特征与分析. 第四纪研究, 2018, 38(6): 1336-

  1347.

7. 陈苗,胡小飞,王维.走廊南山河流纵剖面高海拔裂点的成因.地理学报,2018,73(09):1702-1713.

6. 温振玲, 胡小飞, 潘保田, 张建, 曹喜林. 金塔南山河流砾石特征指示的青藏高原东北缘地貌演化. 第四纪研究, 2016, 36(4): 907

  -916.

5. 胡小飞,潘保田,李琼.基岩河道水力侵蚀模型原理及其最新研究进展.兰州大学学报(自然科学版),2014,50(06):824-831.

4. 胡小飞,潘保田,高红山,胡振波,曹泊,李清洋,耿豪鹏.祁连山东段全新世河流阶地发育及其与气候变化的关系研究.第四纪研究,2013,

  33(04):723-736.

3. 胡小飞,潘保田,KIRBY Eirc,李清洋,耿豪鹏,陈吉峰.河道陡峭指数所反映的祁连山北翼抬升速率的东西差异.科学通报,2010,55(23):

  2329-2338.

2. 胡小飞,潘保田.磷灰石(U-Th)/He热年代学方法及其在地貌演化研究中的应用.原子能科学技术,2008(07):662-664.

1. 胡小飞,潘保田,苏怀,安春雷,周天.宛川河阶地的年代与下切机制.地理科学,2007(06):808-813.


团队骨干成员:胡振波

11. Pan B, Li X, Hu Z, et al. Channel migration in the northeastern margin of the Tibetan Plateau and its implication 

   for fluvial response to the interaction between rapid tectonic activity, climatic fluctuation and human influence.

   Quaternary Science Reviews, 2023, 310: 108126.

10. Dong, Z., Pan, B., Hu, Z., Mo, Q., Bridgland, D., Li, MH., Li, XH., Yang, YN.,Chen, DB. Evaluation of the Fluvial 

   Response to Tectonic Uplift From Grain Size Distribution in Riverbed Gravels at the Northeastern Margin of the 

   Tibetan Plateau. Frontiers in Earth Science, 10: 824368, 2022.

9. Bridgland D R, Westaway R, Hu Z. Basin inversion: A worldwide Late Cenozoic phenomenon. Global and Planetary Change,

   2020, 193: 103260.

8. Bridgland D R, Hu Z, Vandenberghe J, et al. Late Cenozoic fluvial history worldwide: a context for the Yellow River

   record. Global and planetary change.,2020, 193: 103274.

7. Hu Z, Li M H, Dong Z J, et al. Fluvial entrenchment and integration of the Sanmen Gorge, the Lower Yellow River. 

   Global and Planetary Change, 2019, 178: 129-138.

6. Wang J, Hu Z, Pan B, et al.Spatial distribution pattern of channel steepness index as evidence for differential rock

   uplift along the eastern Altun Shan on the northern Tibetan Plateau. Global and Planetary Change, 2019,181:102979.

5. Su H, Dong M, Hu Z. Late Miocene birth of the Middle Jinsha River revealed by the fluvial incision rate. Global and

   Planetary Change, 2019, 183: 103002.

4. Hu Z, Pan B T, Bridgland D, et al. The linking of the upper-middle and lower reaches of the Yellow River as a result

   of fluvial entrenchment. Quaternary Science Reviews, 2017, 166: 324-338.

3. Hu Z, Pan B, Guo L, et al. Rapid fluvial incision and headward erosion by the Yellow River along the Jinshaan gorge

   during the past 1.2 Ma as a result of tectonic extension. Quaternary Science Reviews, 2016, 133: 1-14.

2. Hu Z, Pan B, Wang J, et al. Fluvial terrace formation in the eastern Fenwei Basin,China, during the past 1.2 Ma as a

   combined archive of tectonics and climate change. Journal of Asian Earth Sciences, 2012, 60: 235-245.

1. 李晓花,胡振波,潘保田,李梦昊,莫钦鸿,董子娟,王军.全新世气候波动与快速构造活动作用下的酒东盆地北大河河道迁移过程研究.

  第四纪研究,2021,41(01):1-13.