电子邮件: fanzexin@xtbg.org.cn
通信地址: 云南省西双版纳州勐腊县勐仑镇
邮政编码: 666303
研究领域
全球变化生态学
树木年轮与气候变化
教育背景
工作经历
2017.11-至今 云南哀牢山森林生态系统国家野外科学观测研究站 站长
2017.01-至今 中国科学院西双版纳热带植物园 研究员
2012.06-至今 中国科学院西双版纳热带植物园 树木年轮与环境演变组组长
2012.1-2016.12 中国科学院西双版纳热带植物园 副研究员
2009.12-2011.12 中国科学院西双版纳热带植物园 助理研究员
社会兼职
2016-01-01-今,Plant Diversity编委, 编委
2015-12-23-今,云南省生态学会, 秘书长
2015-08-01-今,Frontiers in Plant Science编委, 编委
指导学生
已指导学生
白雪 硕士研究生 085238-生物工程
胡丽凤 硕士研究生 071012-生态学
蒋玉梅 硕士研究生 071300-生态学
闫玉梅 博士研究生 071300-生态学
周博 硕士研究生 071300-生态学
现指导学生
杨绕琼 博士研究生 071300-生态学
张慧 硕士研究生 071300-生态学
彭新华 硕士研究生 071300-生态学
张依雪 硕士研究生 071300-生态学
徐同良 博士研究生 071300-生态学
张菊梅 硕士研究生 071300-生态学
韦小练 硕士研究生 071300-生态学
发表论文
[1] Gaire NP, Zaw Z, Bräuning A, Sharma B, Dhakal YR, Timilsena R, Shah SK, Bhuju DR, Fan ZX*. 2022. Increasing extreme events in the central Himalaya revealed from a tree-ring based multi-century streamflow reconstruction of Karnali River Basin. Journal of Hydrology (in press).
[2] Sharma B, Fan ZX*, Panthi S, Gaire NP, Fu PL, Zaw Z. 2022. Warming induced tree-growth decline of Toona ciliata in (sub-) tropical southwestern China. Dendrochronologia 73: 125954.
[3] Kaewmano A, Fu PL*, Fan ZX*, Pumijumnong N, Zuidema PA, Bräuning A. 2022. Climate influences on intra-annual stem radial variations and xylem formation of Toona ciliata at two Asian tropical forest sites with contrasting soil water availability. Agricultural and Forest Meteorology. 318: 108906.
[4] Yang RQ, Fu PL, Fan ZX*, Panthi S, Gao J, Niu Y, Li ZS, Bräuning A. 2022. Growth-climate sensitivity of two pine species shows species-specific changes along temperature and moisture gradients in southwestern China. Agricultural and Forest Meteorology 318: 108907.
[5] Yang RQ, Zhao F, Fan ZX*, Panthi S, Fu PL, Bräuning A. 2022. Long-term growth trends of Abies delavayi and its physiological responses to a warming climate in the Cangshan Mountains, southwestern China. Forest Ecology and Management 505: 119943.
[6] Zhang W, Zhang SB, Fan ZX*. 2021. Quantifying the nitrogen allocation and resorption for an orchid pseudobulb in relation to nitrogen supply. Scientia Horticulturae 291: 110580.
[7] Zaw Z, Fan ZX*, Bräuning A, Liu WJ, Gaire NP, Than KZ, Panthi S. 2021. Monsoon precipitation variations in Myanmar since AD 1770: linkage to tropical ocean-atmospheric circulations. Climate Dynamics 56: 3337-3352.
[8] Panthi S, Fan ZX*, Bräuning A. 2020. Ring widths of Rhododendron shrubs reveals a persistent winter warming in the central Himalaya. Dendrochronologia 65: 125799.
[9] Qi JH, Fan ZX*, Fu PL, Zhang YJ, Sterck F. 2020. Differential determinants of growth rates in subtropical evergreen and deciduous juvenile trees: Carbon gain, hydraulics and nutrient use efficiencies. Tree Physiology 41: 12-23.
[10] Yan YM, Fan ZX*, Chen H, Lin LX. 2020. Size dependent associations between tree diameter growth rates and functional traits in an Asian tropical seasonal rainforest. Functional Plant Biology Doi: 10.1071/FP20226.
[11] Zaw Z, Fan ZX*, Bräuning A, Xu CX, Liu WJ, Gaire NP, Panthi S, Than KZ. 2020. Drought reconstruction over the past two centuries in southern Myanmar using teak tree-rings: linkages to the Pacific and Indian Oceans. Geophysical Research Letters 47: e2020GL087627.
[12] Gaire NP, Fan ZX*, Shah SK, Thapa UK, Rokaya MB. 2020. Tree-ring record of winter temperature from Humla, Karnali in central Himalaya: A 229 years-long perspective for recent warming trend. Geografiska Annaler: Series A, Physical Geography 102(3): 297-316.
[13] Rakthai S, Fu PL, Fan ZX*, Gaire NP, Pumijumnong N, Eiadthong W, Tangmitcharoen S. 2020. Increased drought sensitivity results in a declining tree growth of Pinus latteri in northeastern Thailand. Forests 11: 361.
[14] Gaire NP, Fan ZX*, Bräuning A, Panthi S, Rana P, Shrestha A, Bhuju DR. 2020. Abies spectabilis shows stable growth relations to temperature, but changing response to moisture conditions along an elevation gradient in the central Himalaya. Dendrochronologia 60: 125675.
[15] Panthi S, Fan ZX*, van der Sleen P, Zuidema PA. 2020. Long-term physiological and growth responses of Himalayan fir to environmental change are mediated by mean climate. Global Change Biology 26: 1778-1794.
[16] Fan ZX, Bräuning A*, Fu PL, Yang RQ, Qi JH, Grießinger J, Gebrekirstos A. 2019. Intra-annual radial growth of Pinus kesiya var. langbianensis is mainly controlled by moisture availability in the Ailao Mountains, Southwestern China. Forests 10: 899.
[17] Zhao F, Fan ZX*, Su T, Li SF, Tang H, Spicer TEV, Zhou ZK*. 2019. Tree-ring d18O inferred spring drought variability over the past 200 years in the Hengduan Mountains, Southwest China. Palaeogeography, Palaeoclimatology, Palaeoecology 518: 22-33.
[18] Gaire NP, Dhakal YR, Shah SK, Fan ZX*, Brauning A, Thapa UK, Bhandari S, Aryal S, Bhuju DR. 2019. Drought (scPDSI) reconstruction of trans-Himalayan region of central Himalaya using Pinus wallichiana tree-rings. Palaeogeography, Palaeoclimatology, Palaeoecology 514: 251-264.
[19] Fan ZX, Axel Thomas*. 2018. Decadal changes of reference crop evapotranspiration attribution: spatial and temporal variability over China 1960-2011. Journal of Hydrology 560: 461-470.
[20] Panthi S, Bräuning A, Zhou ZK, Fan ZX*. 2018. Growth response of Abies georgei to climate increases with elevation in the central Hengduan Mountains, southwestern China. Dendrochronologia 47: 1-9.
[21] Fan ZX*, Sterck F, Zhang SB, Fu PL, Hao GY. 2017. Tradeoff between stem hydraulic efficiency and mechanical strength affects leaf-stem allometry in 28 Ficus tree species. Frontiers in Plant Science-Functional Plant Ecology doi: 10.3389/fpls.2017.01619.
[22] Panthi S, Bräuning A, Zhou ZK, Fan ZX*. 2017. Tree rings reveal recent intensified spring drought in the central Himalaya, Nepal. Global and Planetary Change 157: 26-34.
[23] Jiang YM, Li ZS, Fan ZX*. 2017. Tree-ring based February-April relative humidity reconstruction since A.D. 1695 in the Gaoligong Mountains, southeastern Tibetan Plateau. Asian Geographer 34(1): 59-70.
[24] Fan ZX*, Bräuning A. 2017. Tree-ring evidence for the historical cyclic defoliator outbreaks on Larix potaninii in the central Hengduan Mountains, SW China. Ecological Indicators 74: 160-171.
[25] Fu PL, Grießinger J, Gebrekirstos A, Fan ZX*, Bräuning A*. 2017. Earlywood and latewood stable carbon and oxygen isotope variations in two pine species in southwestern China during the recent decades. Frontiers in Plant Science doi: 10.3389/fpls.2016.02050.
[26] Fan ZX, Thomas A. 2013. Spatiotemporal variability of reference evapotranspiration and its contributing climatic factors in Yunnan Province, SW China, 1961-2004. Climatic Change 116: 309-325.
[27] Fan ZX, Zhang SB, Hao GY, Slik FJW, Cao KF. 2012. Hydraulic conductivity traits predict growth rates and adult stature of 40 Asian tropical tree species. Journal of Ecology 100: 732−741.
[28] Fan ZX, Bräuning A, Thomas A, Li JB, Cao KF. 2011. Spatial and temporal temperature trends on the Yunnan Plateau (Southwest China) during 1961−2004. International Journal of Climatology 31: 2078−2090.
[29] Fan ZX, Bräuning A, Tian QH, Yang B, Cao KF. 2010. Tree ring recorded May-August temperature variations since A.D. 1585 in the Gaoligong Mountains, southeastern Tibetan Plateau. Palaeogeography, Palaeoclimatology, Palaeoecology 296: 94−102.
[30] Fan ZX, Bräuning A, Yang B, Cao KF. 2009. Tree ring density-based summer temperature reconstruction for the central Hengduan Mountains in southern China. Global and Planetary Change 65: 1−11.
[31] Fan ZX, Bräuning A, Cao KF, Zhu SD. 2009. Growth-climate responses of high-elevation conifers in the central Hengduan Mountains in southern China. Forest Ecology and Management 258(3): 306−313.
[32] Ze-Xin Fan, Kun-Fang Cao, Peter Becker. 2009. Axial and radial variations in xylem anatomy of angiosperm and conifer trees in Yunnan, China. IAWA Journal 30(1): 1−13.
[33] Fan ZX, Bräuning A, Cao KF. 2008. Tree-ring based drought reconstruction in the central Hengduan Mountains (China) since A.D. 1655. International Journal of Climatology 28: 1879−1887.
[34] Fan ZX, Bräuning A, Cao KF. 2008. Annual temperature reconstruction from the central Hengduan Mountains, as deduced from tree rings. Dendrochronologia. 26: 97−107.
[35] Surayothee W, Buajan S, Fu PL*, Pumijumnong N, Fan ZX, Panthi S, Finnegan PM, Zhang YJ, Chen YJ, Tor-ngern P, Chanthorn W, Nathalang A, Brockelman WY. 2021. Growth-climate relationships and long-term growth trends of the tropical forest tree Choerospondias axillaris (Anacardiaceous) in East-central Thailand. Forests 12: 1655.
[36] Ge R, He HL, Zhang L, Ren XL, Williams M, Yu GR, Smallman TL, Zhou T, Li P, Xie ZQ, Wang SL, Wang HM, Zhou GY, Zhang QB, Wang AZ, Fan ZX, Zhang YP, ShenWJ, Yin HJ, Lin LX. 2022. Climate sensitivities of carbon turnover times in soil and vegetation: understanding their effects on forest carbon sequestration. Journal of Geophysical Research: Biogeosciences doi: 10.1028/2020JG005880.
[37] Zuidema P, Babst F, Groenendijk P, Trouet V, Abiyu A, Acuna-Soto R, Adenesky-Filho E, Alfaro-Sanchez R, Aragao JRV, Assis-Pereira G, Bai X, Barbosa AC….Fan ZX…2022. Tropical tree growth driven by dry-season climate variability. Nature Geosciences in press
[38] Song L, Yang B, Liu LL, Mo YX, Liu WY, Meng XJ, Lu HZ, Li Y, Zakari S, Tan ZH, Fan ZX, Zhang YJ. 2022. Spatial-temporal differentiations in water use of coexisting trees from a subtropical evergreen broadleaved forest in Southwest China. Agricultural and Forest Meteorology 316: 108862.
[39] Nawatbhrist K, Sophie F, Zhou YY, Fan ZX, Li MR, He MJ, Zhang SB, Xu K, Lin H. 2021. Thermal safety margins of plant leaves across biomes under a heatwave. Science of the Total Environment doi: 10.1016/j.scitotenv.2021.150416.
[40] Gnanamoorthy P, Song QH, Zhao JB, Zhang YB, Liu YT, Zhou WJ, Sha LQ, Fan ZX, Deb Burman PK. 2021. Altered albedo dominates the radiative forcing changes in a subtropical forest following an extreme snow event. Global Change Biology 27: 6192-6205.
[41] Huang WP, Zong MM, Fan ZX, Feng Y, Li SY, Duan CQ, Li HX. 2021. Determining the impacts of deforestation and corn cultivation on soil quality in tropical acidic red soils using a soil quality index. Ecological Indicators 125: 107580.
[42] Zhao YJ, Keyimu MD, Li ZS, Chen YZ, Wei JS, Wang XC, Fan ZX. 2021. Summer mean temperature reconstruction during the past 285 years based on tree-ring in northern Gaoligong Mountains, northwestern Yunnan of China. Geografiska Annaler: Series A, Physical Geography doi: 10.1080/04353676.2020.1854012
[43] Zhang W, Feng JQ, Kong JJ, Sun L, Fan ZX, Jiang H, Zhagn SB. 2021. Vegetative anatomy and photosynthetic performance of the only known winter-green Cypripedium species: implications for divergent and convergent evolution of slipper orchids. Botanical Journal of the Linnean Society XX: 1:14.
[44] Keyimu M, Li ZS, Fu BJ, Liu GH, Zeng FJ, Chen WL, Fan ZX, Fang KY, Wu XC, Wang XC. 2021. A 406-year non-growing-season precipitation reconstruction in the southeastern Tibetan Plateau. Climate of the Past 17: 2381-2392.
[45] He HL, Ge R, Ren XL, Zhang L, Chang QQ, Xu Q, Zhou GY, Xie ZQ, Wang HM, Zhang QB, Wang AZ, Fan ZX, Zhang YP, Shen WJ, Yin HJ, Lin LX, Williams M, Yu GR. 2021. Reference carbon cycle dataset for typical Chinese forest via colocated observations and data assimilation. Scientific Data 8: 42.
[46] Keyimu M, Li ZS, Liu GH, Fu BJ, Fan ZX, Wang XC, Wu XC, Zhang YD, Halik U. 2020. Tree-ring based minimum temperature reconstruction on the southeastern Tibetan Plateau. Quaternary Science Reviews 251: 106712.
[47] Aryal S, Häusser M, Grießinger J, Fan ZX, Bräuning A. 2020. “dendRoAnalyst”: A tool for processing and analysing dendrometer data. Dendrochronologia doi: 10.1016/j.dendro.2020.125772.
[48] Bi YF, Cory W, Fan ZX, Yang JC, Wu ZK, Huang W, Li JW, Yang XF. 2020. Ring-widths of Abies at tree-line ecotone reveal three centuries of early winter season temperature changes in Yunnan, China. Climate Dynamics 55: 945-959.
[49] Keyimu M, Li ZS, Zhao YJ, Dong YJ, Fu BJ, Fan ZX, Wang XC. 2020. Reconstruction of maximum temperature on Zhegu Mountain, western Sichuan Plateau (China). Climate Research 81: 1-14.
[50] Keyimu M, Li ZS, Wu XC, Fu BJ, Liu GH, Shi SL, Fan ZX, Wang XC. 2020. Recent decline of high altitude coniferous growth due to themo-hydraulic constrains: evidence from the Miyaluo Forest Reserve, Western Sichuan Plateau of China. Dendrochronologia 63: 125751.
[51] Keyimu M, Li ZS, Zhang GS, Fan ZX, Wang XC, Fu BJ. 2020. Tree ring-based minimum temperature reconstruction in the central Hengduan Mountains, China. Theoretical and Applied Climatology Doi: 10.1007/s00704-020-03169-5.
[52] Li ZS, Keyimu M, Fan ZX, Wang XC. 2020. Climate sensitivity of conifer growth doesn’t reveals distinct low-high dipole along the elevation gradient in the Wolong National Natural Reserve, SW China. Dendrochronologia 61: 125702.
[53] Aryal S, Gaire NP, Pokhrel NR, Rana P, Sharma B, Kharal DK, Poudel BS, Dyola N, Fan ZX, Grießinger J, Bräuning A. 2020. Spring season in western Nepal Himalaya is not yet warming: A 400-year temperature reconstruction based on tree-ring widths of Himalayan hemlock (Tsuga dumosa). Atmosphere 11: 132.
[54] Shi CM, Sun C, Wu GC, Wu XC, Chen DL, Masson-Delmotte V, Li JP, Xue JQ, Li ZS, Ji DY, Zhang J, Fan ZX, Shen MG, Ciais P. 2019. Summer temperature over the Tibetan Plateau modulated by Atlantic multidecadal variability. Journal of Climate 32: 4055-4067.
[55] Guo MM, Zhang YD, Liu SR, Gu FX, Wang XC, Li ZS, Fan ZX. 2019. Divergent growth between spruce and fir at alpine treelines on the east edge of the Tibetan Plateau in response to recent climate warming. Agricultural and Forest Meteorology 276-277: 107631.
[56] Fu PL, Zhu SD, Zhang JL, Finnegan PM, Jiang YJ, Lin H, Fan ZX, Cao KF. 2019. The contrasting leaf functional traits between a karst forest and a nearby non-karst forest in south-west China. Functional Plant Biology 46(10): 907-915.
[57] Ge R, He HL, Ren XL, Zhang L, Yu GR, Luke Smallman T, Zhou T, Yu SY, Luo YQ, Xie ZQ, Wang SL, Wang HM, Zhou GY, Zhang QB, Wang AZ, Fan ZX, Zhang YP, Shen WJ, Yin HJ, Lin LX. 2019. Underestimated ecosystem carbon turnover time and sequestration under the steady state assumption: a perpective from long-term data assimilation. Global Change Biology 25: 938-953.
[58] Shi CM, Shen MG, Wu XC, Cheng X, Li XY, Fan TY, Li ZS, Zhang YD, Fan ZX, Shi FZ, Wu GC. 2018. Growth response of alpine treeline forests to a warmer and drier climate on the southeastern Tibetan Plateau. Agricultural and Forest Meteorology 264: 73-79.
[59] Togashi HF, Atkin OK, Bloomfield KJ, Bradford M, Cao KF, Dong N, Evans BJ, Fan ZX, Harrison SP, Zhu H, Liddell MJ, Lloyd J, Ni J, Wang H, Weerasinghe LK, Prentice IC. 2018. Functional trait variation related to gap dynamics in tropical moist forests: A vegetation modelling perspective. Perspectives in Plant Ecology, Evolution and Systematics. 35: 52-64.
[60] Chen F, Yuan YJ, Fan ZX, Yu SL. 2018. A winter precipitation reconstruction (CE 1810-2012) in the Southeastern Tibetan Plateau and its relationship to Salween River streamflow variations. Pure and Applied Geophysics doi: 10.1007/s00024-018-1777-1.
[61] Lin H, Chen YJ, Zhang HL, Fu PL, Fan ZX. 2017. Stronger cooling effects of transpiration and morphology of the plants from a hot dry habitat than a hot wet habitat. Functional Ecology 31: 2202-2211. doi: 10.1111/1365-2435.12923.
[62] Lin H, Chen Y, Song Q, Fu P, Cleverly J, Magliulo V, Law BE, Gough CM, Hörtnagl L, Di Gennaro F, Matteucci G, Mantagnani L, Duce P, Shao C, Kato T, Bonal D, Paul-Limoges E, Beringer J, Grace J, Fan ZX. 2017. Quantifying deforestation and forest degradation with thermal response. Science of Total Environment 607-608: 1286-1292.
[63] Tiwari A, Fan ZX, Jump AS, Zhou ZK. 2017. Warming induced growth decline of Himalayan birch at its lower range edge in a semi-arid region of Trans-Himalaya, central Nepal. Plant Ecology 218: 621-633. doi: 10.1007/s11258-017-0716-z.
[64] Tiwari A, Fan ZX, Jump AS, Li SF, Zhou ZK. 2017. Gradual expansions of moisture sensitive Abies spectabilis forest in the Trans-Himalayan zone of central Nepal associated with climate change. Dendrochronologia 41: 34-43.
[65] Lin H, Fan ZX, Shi LL, Arain A, McCaughey H, Billesbach D, Siqueira M, Bracho R, Oechel W. 2016. The cooling trend of canopy temperature during the maturation, succession, and recovery of ecosystems. Ecosystems doi: 10.1007/s10021-016-0033-8.
[66] Fu PL, Liu WJ, Fan ZX, Cao KF. 2017. Is fog an important water source for woody plants in an Asian tropical karst forest during the dry season? Ecohydrology 9(6): 964-972.
[67] Chen YJ, Schnitzer SA, Zhang YJ, Fan ZX, Goldstein G, Tomlinson KW, Lin H, Zhang JL, Cao KF. 2016. Physiological regulation and efficient xylem water transport regulate diurnal water and carbon balances of tropical lianas. Functional Ecology doi: 10.1111/1365-2435.12724.
[68] Lu HZ, Song L, Liu WY, Xu XL, Hu YH, Shi XM, Li S, Ma WZ, Chang YF, Fan ZX, Lu SG, Wu Y, Yu FH. 2016. Survival and growth of epiphytic ferns depend on resource sharing. Frontiers in Plant Science doi: 10.3389/fpls.2016.004.16.
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