Populus pruinosa decline in a riparian tugai forest on the Zarafshon River, central Uzbekistan: edaphic conditions as predisposing factors and drought as the triggering factor

Akbar Akhmedov; Nodirjon Bobokandov; Kholmurod Zhalov; Frank M. Thomas

doi:10.1007/s11676-025-01949-1

Journal of Forestry Research ›› 2026, Vol. 37 ›› Issue (1) :6 DOI: 10.1007/s11676-025-01949-1

Original Paper

research-article

Populus pruinosa decline in a riparian tugai forest on the Zarafshon River, central Uzbekistan: edaphic conditions as predisposing factors and drought as the triggering factor

Author information +

History +

PDF

Abstract

Ecological and anthropogenic changes have reduced the area of Central Asian riparian forests (tugai), involving dieback of Populus pruinosa Schrenk, one of the tugai’s principal tree species. In a tugai forest on the Zarafshon River, Central Uzbekistan, we investigated the role of environmental factors in P. pruinosa dieback by comparing one healthy and one proximate declining stand. We measured the widths of tree rings of the past 25 years (1999–2023), analyzed their carbon isotope ratios (δ¹³C; 2004–2023), determined physical and chemical soil variables, and retrieved data on groundwater depths and SPEI (Standardised Precipitation Evapotranspiration Index). Over the 25-year period, radial growth did not differ between healthy and declining trees, but tree growth of the declining stand decreased, and in the last 6 years (2018–2023), during and after 2 exceptionally dry years (2018 and 2019), radial increment was significantly smaller. Correlations between radial growth, δ¹³C and SPEI, indicative of drought stress, were only found in the declining stand’s trees. Soil of the declining stand had a higher clay content in the subsoil (30–60 cm), higher salt concentrations in the uppermost layer (10 cm) and in the subsoil, and a lower field capacity across the entire soil profile. There was no groundwater decline during the study period. For the first time, evidence is provided that a drought spell in combination with predisposing unfavorable soil conditions can cause tree dieback in Central-Asian tugai forests at a relatively short distance from the water table. Our study may also contribute to initiate further research for analyzing interrelationships between hydrological, edaphic, ecophysiological and meteorological factors in dieback processes of Central-Asian riparian forests, especially in regions that are strongly underrepresented in ecological research.

Keywords

Dendroecology / Drought / Floodplain / Riparian forest / Poplar / Salinity / Soil texture

Cite this article

Download citation ▾

Akbar Akhmedov, Nodirjon Bobokandov, Kholmurod Zhalov, Frank M. Thomas. Populus pruinosa decline in a riparian tugai forest on the Zarafshon River, central Uzbekistan: edaphic conditions as predisposing factors and drought as the triggering factor. Journal of Forestry Research, 2026, 37(1): 6 DOI:10.1007/s11676-025-01949-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]

Adams HD, Zeppel MJB, Anderegg WRL, Hartmann H, Landhäusser SM, Tissue DT, Huxman TE, Hudson PJ, Franz TE, Allen CD, Anderegg LDL, Barron-Gafford GA, Beerling DJ, Breshears DD, Brodribb TJ, Bugmann H, Cobb RC, Collins AD, Dickman LT, Duan HL, Ewers BE, Galiano L, Galvez DA, Garcia-Forner N, Gaylord ML, Germino MJ, Gessler A, Hacke UG, Hakamada R, Hector A, Jenkins MW, Kane JM, Kolb TE, Law DJ, Lewis JD, Limousin JM, Love DM, Macalady AK, Martínez-Vilalta J, Mencuccini M, Mitchell PJ, Muss JD, O’Brien MJ, O’Grady AP, Pangle RE, Pinkard EA, Piper FI, Plaut JA, Pockman WT, Quirk J, Reinhardt K, Ripullone F, Ryan MG, Sala A, Sevanto S, Sperry JS, Vargas R, Vennetier M, Way DA, Xu CG, Yepez EA, McDowell NG. A multi-species synthesis of physiological mechanisms in drought-induced tree mortality. Nat Ecol Evol, 2017, 1(9): 1285-1291

[2]	Aishan T, Halik Ü, Cyffka B, Kuba M, Abliz A, Baidourela A. Monitoring the hydrological and ecological response to water diversion in the lower reaches of the Tarim River, Northwest China. Quat Int, 2013, 311: 155-162

[3]	Aishan T, Halik Ü, Betz F, Tiyip T, Ding JL, Nuermaimaiti Y. Stand structure and height-diameter relationship of a degraded Populus euphratica forest in the lower reaches of the Tarim River, Northwest China. J Arid Land, 2015, 7(4): 544-554

[4]	Arkin A, Yusup A, Halik Ü, Abliz A, Ainiwaer A, Tian AL, Mijiti M. Unveiling population structure dynamics of Populus euphratica riparian forests along the Tarim River using terrestrial LiDAR. Forests, 2025, 16(2 368

[5]	Arndt SK, Foetzki A, Adams MA. Runge M, Zhang X. Carbon and oxygen stable isotopes of leaf organic matter of perennial species in the hyperarid Taklimakan Desert. Ecophysiology and habitat requirements of perennial plant species in the Taklimakan Desert, 2004, Shaker, Aachen, Germany91107

[6]	Bazilevich NI, Pankova EI. Classification of soils according to their chemistry and degree of salinization. Agrokem Talajtan, 1969, 18: 219-226

[7]	Beguería S, Vicente-Serrano SM, Angulo-Martínez M. A multiscalar global drought dataset: the SPEIbase: a new gridded product for the analysis of drought variability and impacts. Bull Amer Meteorol Soc, 2010, 91(10): 1351-1356

[8]	Biondi F, Qeadan F. A theory-driven approach to tree-ring standardization: defining the biological trend from expected basal area increment. Tree-Ring Res, 2008, 64(2): 81-96

[9]	Blume HP, Brümmer GW, Fleige H, Horn R, Kandeler E, Kögel-Knabner I, Kretzschmar R, Stahr K, Wilke BM. Scheffer/Schachtschabel - Soil science. Springer, 2016

[10]	Breckle SW (2021) Ökologie der Erde Band 3: Spezielle Ökologie der Gemäßigten und Arktischen Zonen Euro-Nordasiens, 3. Aufl. Stuttgart, Germany: Schweizerbart'sche Verlagsbuchhandlung. (in German)

[11]	Chen YN, Ye ZX, Shen YJ. Desiccation of the Tarim River, Xinjiang, China, and mitigation strategy. Quat Int, 2011, 244(2): 264-271

[12]	Cohen H. Statistical power analysis for behavioral sciences, 1988, Mahwah, NJ, USA, Lawrence Erlbaum Associates

[13]	Dluzniewska P, Gessler A, Dietrich H, Schnitzler JP, Teuber M, Rennenberg H. Nitrogen uptake and metabolism in Populus × canescens as affected by salinity. New Phytol, 2007, 173(2): 279-293

[14]	Duan XY, Liu Y, Song HM, Ren M, Cai QF, Sun CF, Li Q, Ling HB, Zhang TW, Ye M, Liu NJ. Human-induced water-environment changes recorded in tree rings in the lower Tarim River. J Hydrol, 2025, 661 133665

[15]

Dukenov Z, Utebekova A, Kopabayeva A, Shynybekov M, Akhmetov R, Rakymbekov Z, Bekturganov A, Dosmanbetov D. Influence of climatic changes on the dendrochronological features of Tugai forests along the Syr Darya and Ili Rivers in the territory of Kazakhstan. Int J des Nat Ecodyn, 2023, 18(4): 975-982

[16]	Esper J, Cook E, Krusic P, Peters K, Schweingruber F. Tests of the RCS method for preserving low-frequency variability in long tree-ring chronologies. Tree-Ring Res, 2003, 59(2): 81-98

[17]	Fan Z. Hoppe T, Kleinschmit B, Roberts B, Thevs N, Halik Ü. Determining ideal groundwater depths for ecological purposes in the Tarim River Valley. Watershed and floodplain management along the Tarim River in China’s arid northwest, 2006, Shaker, Aachen, Germany213220

[18]	Farquhar GD, Ehleringer JR, Hubick KT. Carbon isotope discrimination and photosynthesis. Annu Rev Plant Physiol Plant Mol Biol, 1989, 40: 503-537

[19]	Faul F, Erdfelder E, Lang AG, Buchner A. G*power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods, 2007, 39(2): 175-191

[20]	Feng Q, Liu W, Si JH, Su YH, Zhang YW, Cang ZQ, Xi HY. Environmental effects of water resource development and use in the Tarim River basin of northwestern China. Environ Geol, 2005, 48(2): 202-210

[21]	Franzen D (2007) Managing saline soils in North Dakota. North Dakota State University. SF Series - Soils & Fertilizers SF-1087 (revised): 1–11. http://hdl.handle.net/10365/5441

[22]	Fritts HC, Swetnam TW. Dendroecology: a tool for evaluating variations in past and present forest environments. Adv Ecol Res, 1989, 19: 111-188

[23]	Gagen M, McCarroll D, Robertson I, Loader NJ, Jalkanen R. Do tree ring δ¹³C series from Pinus sylvestris in northern Fennoscandia contain long-term non-climatic trends?. Chem Geol, 2008, 252(1–2): 42-51

[24]	Gai Z, Li X, Zhai J, Chen X, Li Z. Effects of river bank soil physical and chemical factors on Populus pruinosa Schrenk clonal growth. Appl Ecol Environ Res, 2020, 18(3): 4791-4806

[25]	Galle A, Esper J, Feller U, Ribas-Carbo M, Fonti P. Responses of wood anatomy and carbon isotope composition of Quercus pubescens saplings subjected to two consecutive years of summer drought. Ann for Sci, 2010, 67(8 809

[26]	Geist H. The causes and progression of desertification, 2005, Aldershot, UK, Ashgate

[27]

Geßler A, Jung K, Gasche R, Papen H, Heidenfelder A, Börner E, Metzler B, Augustin S, Hildebrand E, Rennenberg H. Climate and forest management influence nitrogen balance of European beech forests: microbial N transformations and inorganic N net uptake capacity of mycorrhizal roots. Eur J for Res, 2005, 124(2): 95-111

[28]	Grashey-Jansen S, Kuba M, Cyffka B, Halik Ü, Aishan T. Spatio-temporal variability of soil water at three seasonal floodplain sites: a case study in Tarim Basin, Northwest China. Chin Geogr Sci, 2014, 24(6): 647-657

[29]	Gries D, Zeng F, Foetzki A, Arndt SK, Bruelheide H, Thomas FM, Zhang X, Runge M. Growth and water relations of Tamarix ramosissima and Populus euphratica on Taklamakan desert dunes in relation to depth to a permanent water table. Plant Cell Environ, 2003, 26(5): 725-736

[30]	Groll M, Opp C, Kulmatov R, Ikramova M, Normatov I. Water quality, potential conflicts and solutions—an upstream–downstream analysis of the transnational Zarafshan River (Tajikistan, Uzbekistan). Environ Earth Sci, 2015, 73(2): 743-763

[31]

Halik Ü, Kurban A, Mijit M, Schulz J, Paproth F, Coenradie B. Hoppe T, Kleinschmit B, Roberts B, Thevs N, Halik Ü. The potential influence of embankment engineering and ecological water transfers on the riparian vegetation along the middle and lower reaches of the Tarim River. Watershed and floodplain management along the Tarim River in China’ arid northwest, 2006, Shaker, Aachen, Germany221236

[32]

Härdtle W, Niemeyer T, Assmann T, Aulinger A, Fichtner A, Lang A, Leuschner C, Neuwirth B, Pfister L, Quante M, Ries C, Schuldt A, von Oheimb G. Climatic responses of tree-ring width and δ ¹³ C signatures of sessile oak (Quercus petraea Liebl.) on soils with contrasting water supply. Plant Ecol, 2013, 214(9): 1147-1156

[33]

Härdtle W, Niemeyer T, Assmann T, Baiboks S, Fichtner A, Friedrich U, Lang AC, Neuwirth B, Pfister L, Ries C, Schuldt A, Simon N, von Oheimb G. Long-term trends in tree-ring width and isotope signatures (δ13C, δ15N) of Fagus sylvatica L. on soils with contrasting water supply. Ecosystems, 2013, 16(8): 1413-1428

[34]	Harris I, Jones PD, Osborn TJ, Lister DH. Updated high-resolution grids of monthly climatic observations–the CRU TS3.10 dataset. Int J Climatol, 2014, 34(3): 623-642

[35]	He JS, Zhang QB, Bazzaz FA. Differential drought responses between saplings and adult trees in four co-occurring species of New England. Trees, 2005, 19(4): 442-450

[36]	Ho LT, Schneider R, Thomas FM. Growth of the tropical Pinus kesiya as influenced by climate and nutrient availability along an elevational gradient. J Plant Ecol, 2020, 13(1): 97-106

[37]	Huang TM, Pang ZH. Changes in groundwater induced by water diversion in the Lower Tarim River, Xinjiang Uygur, NW China: evidence from environmental isotopes and water chemistry. J Hydrol, 2010, 387(3–4): 188-201

[38]	IPCC (2023) Climate Change 2023: Synthesis Report. Contribution of Working Groups I, II and III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Geneva, Switzerland: IPCC. pp. 169.

[39]	IUCN (2025) The IUCN Red List of Threatened Species. Version 2024–2. Accessed on February 26, 2025. https://www.iucnredlist.org/search?query=Populus%20pruinosa&searchType=species

[40]	Jansen K, Sohrt J, Kohnle U, Ensminger I, Gessler A. Tree ring isotopic composition, radial increment and height growth reveal provenance-specific reactions of Douglas-fir towards environmental parameters. Trees, 2013, 27(1): 37-52

[41]	Kachinsky NA. Soil Physics, 1965, Moscow, USSR, Publ. Higher School(in Russian)

[42]	Kew Royal Botanical Gardens (2025) Plants of the world online. Accessed on February 26, 2025. https://powo.science.kew.org

[43]	Kilroy E, McCarroll D, Young GHF, Loader NJ, Bale RJ. Absence of juvenile effects confirmed in stable carbon and oxygen isotopes of European larch trees. Acta Silvae Ligni, 2016, 111: 27-33

[44]	Kottek M, Grieser J, Beck C, Rudolf B, Rubel F. World map of the Köppen-Geiger climate classification updated. Meteorol Z, 2006, 15(3): 259-263

[45]	Kuzmina Z, Treshkin S. Soil salinization and dynamics of Tugai vegetation in the southeastern Caspian Sea region and in the Aral Sea coastal region. Eurasian Soil Sci, 1997, 30(6): 642-649

[46]	Lang P, Jeschke M, Wommelsdorf T, Backes T, Lv CY, Zhang XM, Thomas FM. Wood harvest by pollarding exerts long-term effects on Populus euphratica stands in riparian forests at the Tarim River, NW China. For Ecol Manage, 2015, 353: 87-96

[47]	Lang P, Ahlborn J, Schäfer P, Wommelsdorf T, Jeschke M, Zhang XM, Thomas FM. Growth and water use of Populus euphratica trees and stands with different water supply along the Tarim River, NW China. For Ecol Manage, 2016, 380: 139-148

[48]	Li WH, Zhou HH, Fu AH, Chen YP. Ecological response and hydrological mechanism of desert riparian forest in inland river, northwest of China. Ecohydrol, 2013, 6(6): 949-955

[49]	Li S, Lu S, Wang J, Chen ZC, Zhang Y, Duan J, Liu P, Wang XY, Guo JK. Responses of physiological, morphological and anatomical traits to abiotic stress in woody plants. Forests, 2023, 14(9 1784

[50]	Lioubimtseva E, Henebry GM. Climate and environmental change in arid Central Asia: impacts, vulnerability, and adaptations. J Arid Environ, 2009, 73(11): 963-977

[51]	Loader NJ, Robertson I, Barker AC, Switsur VR, Waterhouse JS. An improved technique for the batch processing of small wholewood samples to α-cellulose. Chem Geol, 1997, 136(3–4): 313-317

[52]	Loader NJ, McCarroll D, Gagen M, Robertson I, Jalkanen R (2007) Extracting climatic information from stable isotopes in tree rings. In: Dawson TE, Siegwolf RTW (eds.), Isotopes as indicators of ecological change. Elsevier, pp 27–48. https://doi.org/10.1016/b978-012373627-7/50005-6

[53]	Marchand W, Depardieu C, Campbell EM, Bousquet J, Girardin MP. Long-term temporal divergence in post-drought resilience decline between deciduous and evergreen tree species. Glob Change Biol, 2025, 31(7 e70330

[54]	Massonnet C, Chuste PA, Zeller B, Tillard P, Gerard B, Cheraft L, Breda N, Maillard P. Does long-term drought or repeated defoliation affect seasonal leaf N cycling in young beech trees?. Tree Physiol, 2024, 44(6 tpae054

[55]	McCarroll D, Loader NJ. Stable isotopes in tree rings. Quat Sci Rev, 2004, 23(7–8): 771-801

[56]	McCarroll D, Duffy JE, Loader NJ, Young GH, Davies D, Miles D, Bronk Ramsey C. Are there enormous age-trends in stable carbon isotope ratios of oak tree rings?. Holocene, 2020, 30(11): 1637-1642

[57]	Metz J, Annighöfer P, Schall P, Zimmermann J, Kahl T, Schulze ED, Ammer C. Site-adapted admixed tree species reduce drought susceptibility of mature European beech. Glob Change Biol, 2016, 22(2): 903-920

[58]	Nagavciuc V, Kern Z, Ionita M, Hartl C, Konter O, Esper J, Popa I. Climate signals in carbon and oxygen isotope ratios of Pinus cembra tree-ring cellulose from the Călimani Mountains, Romania. Int J Climatol, 2020, 40(5): 2539-2556

[59]	Olsson O, Manig N (2011) Index-based assessment of the river water quality and quantity status at the lower Zerafshan River. Paper presented at the IWA 1st Central Asian Regional Young and Senior Water Professionals, Almaty, Kasachstan. https://doi.org/10.13140/2.1.1088.0802

[60]	Peng Y, He GJ, Wang GZ. Spatial-temporal analysis of the changes in Populus euphratica distribution in the Tarim National Nature Reserve over the past 60 years. Int J Appl Earth Obs Geoinf, 2022, 113 103000

[61]	Pfadenhauer JS, Klötzli FA. Vegetation der Erde: Grundlagen, Ökologie, Verbreitung, 2014, Berlin, Germany, Springer-Spektrum in German)

[62]	Pohlert T (2023) Trend: non-parametric trend tests and change-point detection. R package version 1.1.5. (Accessed on 19.02.2025). https://CRAN.R-project.org/package=trend

[63]	Rakhimzhanov AN, Ivashchenko AA, Yu Kirillov V, Aleka VP, Stikhareva TN. Assessment of the current status of the Turanga forests in the south-east of Kazakhstan. Eurasian J Ecol, 2021, 67(2): 85-96

[64]	Red Book of the Republic of Uzbekistan. Plants and Fungi, 2019, Tashkent, Uzbekistan, Chinor ENK Publishing House256

[65]	Rennenberg H, Wildhagen H, Ehlting B. Nitrogen nutrition of poplar trees. Plant Biol, 2010, 12(2): 275-291

[66]	Sadovski A, Ivanova M. Transformation of soil texture schemes and determination of water-physical properties of soils. Eurasian J Soil Sci, 2020, 9(4): 306-313

[67]	Schaetzl RJ, Anderson S. Soils: genesis and geomorphology, 2005, Cambridge, UK, Cambridge University Press

[68]	Scheidegger Y, Saurer M, Bahn M, Siegwolf R. Linking stable oxygen and carbon isotopes with stomatal conductance and photosynthetic capacity: a conceptual model. Oecologia, 2000, 125(3): 350-357

[69]	Sorg A, Mosello B, Shalpykova G, Allan A, Hill Clarvis M, Stoffel M. Coping with changing water resources: the case of the Syr Darya river basin in Central Asia. Environ Sci Policy, 2014, 43: 68-77

[70]	Speer JH (2010) Fundamentals of tree-ring research. Tucson, AZ, USA: University of Arizona Press, 368 pp. ISBN: 978–0–8165–2684–0

[71]	Stella JC, Hayden MK, Battles JJ, Piégay H, Dufour S, Fremier AK. The role of abandoned channels as refugia for sustaining pioneer riparian forest ecosystems. Ecosystems, 2011, 14(5): 776-790

[72]	Stromberg JC, Tluczek MGF, Hazelton AF, Ajami H. A century of riparian forest expansion following extreme disturbance: spatio-temporal change in Populus/Salix/Tamarix forests along the Upper San Pedro River, Arizona, USA. For Ecol Manage, 2010, 259(6): 1181-1189

[73]	Thevs N, Zerbe S, Peper J, Succow M. Vegetation and vegetation dynamics in the Tarim River floodplain of continental-arid Xinjiang, NW China. Phytocoenologia, 2008, 38(1–2): 65-84

[74]	Thomas FM, Hartmann G. Soil and tree water relations in mature oak stands of northern Germany differing in the degree of decline. Ann for Sci, 1996, 53(2–3): 697-720

[75]	Thomas FM, Hartmann G. Tree rooting patterns and soil water relations of healthy and damaged stands of mature oak (Quercus robur L. and Quercus petraea [Matt.] Liebl.). Plant Soil, 1998, 203(1): 145-158

[76]	Thomas FM, Lang P. Growth and water relations of riparian poplar forests under pressure in Central Asia’s Tarim River Basin. River Res Appl, 2021, 37(2): 233-240

[77]	Thomas FM, Foetzki A, Gries D, Bruelheide H, Li XY, Zeng FJ, Zhang XM. Regulation of the water status in three co-occurring phreatophytes at the southern fringe of the Taklamakan Desert. J Plant Ecol, 2008, 1(4): 227-235

[78]	Thomas FM, Jeschke M, Zhang XM, Lang P. Stand structure and productivity of Populus euphratica along a gradient of groundwater distances at the Tarim River (NW China). J Plant Ecol, 2017, 10(5): 753-764

[79]	Thomas FM, Preusser S, Backes B, Werner W. Leaf traits of Central-European beech (Fagus sylvatica) and oaks (Quercus petraea/robur): effects of severe drought and long-term dynamics. For Ecol Manage, 2024, 559 121823

[80]	Thomas FM (2013) Ecology of phreatophytes. In: Progress in botany. Springer, pp 335–375. https://doi.org/10.1007/978-3-642-38797-5_11

[81]	Timofeeva G, Treydte K, Bugmann H, Rigling A, Schaub M, Siegwolf R, Saurer M. Long-term effects of drought on tree-ring growth and carbon isotope variability in Scots pine in a dry environment. Tree Physiol, 2017, 37(8): 1028-1041

[82]	Torbenson M, Klippel L, Hartl C, Reinig F, Treydte K, Büntgen U, Trnka M, Schöne B, Schneider L, Esper J. Investigation of age trends in tree-ring stable carbon and oxygen isotopes from northern Fennoscandia over the past millennium. Quat Int, 2022, 631: 105-114

[83]	Treshkin SY (2001) The Tugai forests of floodplain of the Amudarya River: ecology, dynamics and their conservation. In: Breckle S-W, Veste M, Wucherer W (eds.), Sustainable land use in deserts. Springer, pp 95–102. https://doi.org/10.1007/978-3-642-59560-8_9

[84]	Treydte KS, Frank DC, Saurer M, Helle G, Schleser GH, Esper J. Impact of climate and CO₂ on a millennium-long tree-ring carbon isotope record. Geochim Cosmochim Acta, 2009, 73(16): 4635-4647

[85]	Tupitsa A (2010) Photogrammetric techniques for the functional assessment of tree and forest resources in Khorezm, Uzbekistan. In: Vlek PLG, Denich M, Martius C, Manschadi A, Bogardi J (eds.), Ecology and Development Series No. 71. Göttingen, Germany: Cuvillier. pp. 87–103.

[86]	Tyree MT, Sperry JS. Vulnerability of xylem to cavitation and embolism. Annu Rev Plant Physiol Plant Mol Biol, 1989, 40: 19-36

[87]	UN/ECE (2020) Environmental performance reviews: Uzbekistan, Third Review, Environmental Performance Reviews Series. Geneva, Switzerland: United Nations. pp. 451.

[88]	Vesselova P, Makhmudova K, Makhmudova K, Kudabayeva G, Osmonali B, Mikhalev V. Current growth conditions of Populus diversifolia Schrenk and Populus pruinosa Schrenk in the Syr-Darya valley. OnLine J Biol Sci, 2022, 22(4): 425-438

[89]	Vicente-Serrano SM, Beguería S, López-Moreno JI. A multiscalar drought index sensitive to global warming: the standardized precipitation evapotranspiration index. J Clim, 2010, 23(7): 1696-1718

[90]	Vtorova VN, Kholopova LB, Puzachenko YG (1993) Tolerance range of Populus pruinosa on saline soils of South Tadjikistan. In: Lieth H, Al Masoom AA (eds.), Towards the rational use of high salinity tolerant plants. Springer Netherlands, 225–237. https://doi.org/10.1007/978-94-011-1860-6_29

[91]	Walter C, Pérez CA, Thomas FM. Weather or weathering? Growth of Nothofagus dombeyi on volcanic soils differing in nitrogen and phosphorus concentrations. J Plant Ecol, 2016, 9(5): 596-607

[92]	Walter H, Box EO (1983) Middle Asian deserts. In: West NE (ed.), Ecosystems of the World, Vol. 5: Temperate Deserts and Semi-Deserts. Amsterdam, The Netherlands: Elsevier. pp. 79–104.

[93]	Walter H, Breckle SW (1994) Ökologie der Erde. Band 3: Spezielle Ökologie der gemäßigten und arktischen Zonen Euro-Nordasiens, 2. Aufl. Stuttgart, Germany: G. Fischer. (in German)

[94]	Wang H, Jia X. Field observations of windblown sand and dust in the Taklimakan Desert, NW China, and insights into modern dust sources. Land Degrad Dev, 2013, 24(4): 323-333

[95]	Wang SJ, Chen BH, Li HQ. Euphrates poplar forest, 1996, Beijing, China, China Environmental Science Press

[96]	Webb RH, Leake SA. Ground-water surface-water interactions and long-term change in riverine riparian vegetation in the southwestern United States. J Hydrol, 2006, 320(3–4): 302-323

[97]	West NE. Goodall DW, Perry RA, Howes KMW. Nutrient cycling in desert ecosystems. Arid-Land Ecosystems: Structure, Functioning and Management, 1981, Cambridge, UK, Cambridge University Press3013242

[98]	Westermann J, Zerbe S, Eckstein D. Age structure and growth of degraded Populus euphratica floodplain forests in north-west China and perspectives for their recovery. J Integr Plant Biol, 2008, 50(5): 536-546

[99]	Wieland A, Greule M, Roemer P, Esper J, Keppler F. Climate signals in stable carbon and hydrogen isotopes of lignin methoxy groups from southern German beech trees. Clim past, 2022, 18(8): 1849-1866

[100]

Wilkening JV, Feng X, Dawson TE, Thompson SE. Different roads, same destination: the shared future of plant ecophysiology and ecohydrology. Plant Cell Environ, 2024, 47(9): 3447-3465

[101]

Yu Y, Chen X, Disse M, Cyffka B, Lei JQ, Zhang HY, Brieden A, Welp M, Abuduwaili J, Li YM, Zeng FJ, Gui DW, Thevs N, Ta ZJ, Gao X, Pi YY, Yu X, Sun LX, Yu RD. Climate change in Central Asia: sino-German cooperative research findings. Sci Bull, 2020, 65(9): 689-692

[102]

Zeileis A, Leisch F, Hornik K, Kleiber C, Hansen BP, Merkle EC, Umlauf N (2024) Testing, monitoring, and dating structural changes. Vienna, Austria, CRAN. https://cran.r-project.org/web/packages/strucchange/strucchange.pdf

[103]

Zhai JT, Li ZJ, Zhang SH, Han XL, Li X. Differences in the structural and functional traits of Populus euphratica and Populus pruinosa with tree height. Appl Ecol Environ Res, 2022, 20(4): 3597-3617

[104]

Zhang JL, Zhai JT, Wang J, Si JH, Li JW, Ge XK, Li ZJ. Interrelationships and environmental influences of photosynthetic capacity and hydraulic conductivity in desert species Populus pruinosa. Forests, 2024, 15(7 1094

[105]

Zhang GQ, Bréda N, Steil N, Gaertner PA, Levillain J, Ruelle J, Massonnet C. Analysing resilience of European beech tree to recurrent extreme drought events through ring growth, wood anatomy and stable isotopes. J Ecol, 2025, 113(4): 955-973

[106]

Zhou HH, Chen YN, Li WH, Ayup M. Xylem hydraulic conductivity and embolism in riparian plants and their responses to drought stress in desert of Northwest China. Ecohydrol, 2013, 6(6): 984-993