Responses to Climate Factors in the Radial Growth of Schrenk Spruce (Picea Schrenkiana) in the Yili Region, Northwest China

• Autorzy: Liu Kexiang , Zhang Tongwen , Zhang Ruibo , Qin Li , Yu Shulong , Jiang Shengxia , Fan Yuting

Identyfikatory

DOI

10.2478/geochr-2023-0012

• Języki publikacji: EN

Abstrakty

EN

To examine the associations existing between elevation and tree growth, tree-ring width chronologies of Schrenk spruce (Picea schrenkiana) were developed from sampling sites at different elevations in the Wusun Mountain, Yili region, Xinjiang, northwest China. The radial growth of high-elevation trees was observed to be primarily influenced by meteorological factors in the non-growth season of the previous year. The radial growth of mid-elevation trees was mainly affected by temperature. The radial growth of low-elevation trees was mainly affected by both temperature and relative humidity. About climate change, the radial growth of Schrenk spruce at different elevations showed a non-uniform response to climate variables. Under the condition of intensified drought stress in the future, the forest ecosystem is likely to be greatly affected, and the radial growth of Schrenk spruce at low elevations will be especially inhibited.

Słowa kluczowe

EN

tree-ring; chronology development; climatic responses; Tianshan Mountains

• Wydawca: Politechnika Śląska
• Czasopismo: Geochronometria
• Rocznik: 2023
• Tom: Vol. 50, no. 1
• Strony: 195--205
• Opis fizyczny: Bibliogr. 55 poz., rys.

Twórcy

autor

Liu Kexiang

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

autor

Zhang Tongwen

• Xinjiang Climate Center, Urumqi, 830002, China

autor

Zhang Ruibo

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

autor

Qin Li

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

autor

Yu Shulong

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

autor

Jiang Shengxia

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

autor

Fan Yuting

• Key Laboratory of Tree-ring Physical and Chemical Research, CMA/Xinjiang Key Laboratory for Tree Ring Ecology, Institute of Desert Meteorology, China Meteorological Administration, Urumqi, 83002, China

Bibliografia

• 1. Büntgen U, Esper J, Frank DC, Nicolussi K and Schmidhalter M, 2005. A 1052-year tree-ring proxy for Alpine summer temperatures. Climate Dynamics 25(2–3): 141–153, DOI 10.1007/s00382-005-0028-1.
• 2. Chen F, Yuan YJ, Chen FH, Wei WS, Yu SL, Chen XJ, Fan ZA, Zhang RB, Zhang TW, Shang HM and Qin L, 2013. A 426-year drought history for Western Tian Shan, Central Asia, inferred from rings and linkages to the North Atlantic and Indo–West Pacific Oceans. The Holocene 23(8): 1095–1104, DOI 10.1177/0959683613483614.
• 3. Chen F, Yuan YJ, Wei WS, Yu SL, Zhang TW, Shang HM, Zhang RB, Qin L and Fan ZA, 2015. Tree-ring recorded hydroclimatic change in Tienshan mountains during the past 500 years. Quaternary International 358: 35–41, DOI 10.1016/j.quaint.2014.09.057.
• 4. Cook ER, 1985. A time series analysis approach to tree ring standardization (dendrochronology, forestry, dendroclimatology, autoregressive process). The University of Arizona, Ph.D Thesis.
• 5. Cook ER and Kairiukstis LA, 2013. Methods of Dendrochronology: Applications in the Environmental Sciences. Springer Science & Business Media, New York.
• 6. D’Arrigo R, Jacoby G, Buckley B, Sakulich J, Frank D, Wilson R, Curtis A and Anchukaitis K, 2009. Tree growth and inferred temperature variability at the North American Arctic treeline. Global and Planetary Change 65(1–2): 71–82, DOI 10.1016/j.gloplacha.2008.10.011.
• 7. Dai A, 2013. Increasing drought under global warming in observations and models. Nature Climate Change 3(1): 52–58, DOI 10.1038/nclimate1633.
• 8. Fritts H, 2012. Tree Rings and Climate. Elsevier, Amsterdam.
• 9. Gao LL, Gou XH, Deng Y, Liu WH, Yang MX and Zhao ZQ, 2013. Climate–growth analysis of Qilian juniper across an altitudinal gradient in the central Qilian Mountains, Northwest China. Trees 27: 379–388.
• 10. Gou XH, Shao XM, Wang YJ and Chen FH, 1999. The establishment of tree-ring chronology in East region of Qilian Mountains. Journal of Desert Research 4: 68–71.
• 11. Gou XH, Zhang F, Deng Y, Ettl GJ, Yang MX, Gao LL and Fang KY, 2012. Patterns and dynamics of tree-line response to climate change in the eastern Qilian Mountains, northwestern China. Dendrochronologia 30(2): 121–126, DOI 10.1016/j.dendro.2011.05.002.
• 12. Heinrich I, Touchan R, Dorado Liñán I, Vos H and Helle G, 2013. Winter-to-spring temperature dynamics in Turkey derived from tree rings since AD 1125. Climate Dynamics 41(7–8): 1685–1701, DOI 10.1007/s00382-013-1702-3.
• 13. Holmes RL, 1983. Computer assisted quality control. Tree-Ring Bull 43: 69–78.
• 14. Huo YX, Gou XH, Liu WH, Li JB, Zhang F and Fang KY, 2017. Climate–growth relationships of Schrenk spruce (Picea schrenkiana) along an altitudinal gradient in the western Tianshan mountains, northwest China. Trees 31(2): 429–439, DOI 10.1007/s00468-017-1524-8.
• 15. Ji F, Wu ZH, Huang JP and Chassignet EP, 2014. Evolution of land surface air temperature trend. Nature Climate Change 4(6): 462–466, DOI 10.1038/nclimate2223.
• 16. Jiang YM, Li ZS and Fan ZX, 2017. Tree-ring based February–April relative humidity reconstruction since AD 1695 in the Gaoligong Mountains, southeastern Tibetan Plateau. Asian Geography 34(1): 59–70.
• 17. Jiao L, Jiang Y, Wang MC, Kang XY, Zhang WT, Zhang LN and Zhao SD, 2016. Responses to climate change in radial growth of Picea schrenkiana along elevations of the eastern Tianshan Mountains, northwest China. Dendrochronologia 40: 117–127, DOI 10.1016/j.dendro.2016.09.002.
• 18. Jiao L, Jiang Y, Zhang WT, Wang MC, Zhang LN and Zhao SD, 2015. Divergent responses to climate factors in the radial growth of Larix sibirica in the eastern Tianshan Mountains, northwest China. Trees 29(6): 1673–1686, DOI 10.1007/s00468-015-1248-6.
• 19. Li CF, Zhang C, Luo GP, Chen X, Maisupova B, Madaminov AA, Han QF and Djenbaev BM, 2015. Carbon stock and its responses to climate change in Central Asia. Global Change Biology 21(5): 1951–1967, DOI 10.1111/gcb.12846.
• 20. Li JB, Gou XH, Cook ER and Chen FH, 2006. Tree-ring based drought reconstruction for the central Tien Shan area in northwest China. Geophysical Research Letters 33, L07715, DOI 10.1029/2006gl025803.
• 21. Liang EY, Leuschner C, Dulamsuren C, Wagner B and Hauck M, 2016. Global warming-related tree growth decline and mortality on the north-eastern Tibetan plateau. Climatic Change 134(1–2): 163–176, DOI 10.1007/s10584-015-1531-y.
• 22. Liang EY, Shao XM, Eckstein D, Huang L and Liu XH, 2006. Topography- and species-dependent growth responses of Sabina przewalskii and Picea crassifolia to climate on the northeast Tibetan Plateau. Forest Ecology and Management 236(2–3): 268–277, DOI 10.1016/j.foreco.2006.09.016.
• 23. Liu Y, Tian H, Song HM and Liang JM, 2010. Tree ring precipitation reconstruction in the Chifeng-Weichang region, China, and East Asian summer monsoon variation since A.D. 1777. Journal of Geophysical Research 115(D6), DOI 10.1029/2009jd012330.
• 24. Lyu L, Deng X and Zhang QB, 2016. Elevation pattern in growth coherency on the southeastern Tibetan Plateau. PLoS One 11(9): e0163201.
• 25. Lyu L, Suvanto S, Nöjd P, Henttonen HM, Mäkinen H and Zhang QB, 2017. Tree growth and its climate signal along latitudinal and altitudinal gradients: Comparison of tree rings between Finland and Tibetan Plateau. Biogeosci Discuss 14: 3083–3095.
• 26. Malanson GP, Resler LM, Bader MY, Holtmeier F-K, Butler DR, Weiss DJ, Daniels LD and Fagre DB, 2011. Mountain treelines: A roadmap for research orientation. Arctic, Antarctic, and Alpine Research 43(2): 167–177, DOI 10.1657/1938-4246-43.2.167.
• 27. Opała M and Mendecki MJ, 2013. An attempt to dendroclimatic reconstruction of winter temperature based on multispecies tree-ring widths and extreme years chronologies (example of Upper Silesia, Southern Poland). Theoretical and Applied Climatology 115(1–2): 73–89, DOI 10.1007/s00704-013-0865-5.
• 28. Peng JF, Li JB, Wang T, Huo JX and Yang L, 2019. Effect of altitude on climate-growth relationships of Chinese white pine (Pinus armandii) in the northern Funiu Mountain, central China. Climatic Change 154: 273–288.
• 29. Sang WG, Wang YX, Su HX and Lu ZH, 2007. Response of tree-ring width to rainfall gradient along the Tianshan Mountains of northwestern China. Chinese Science Bulletin 52(21): 2954–2962, DOI 10.1007/s11434-007-0443-2.
• 30. Savva Y, Oleksyn J, Reich PB, Tjoelker MG, Vaganov EA and Modrzynski J, 2006. Interannual growth response of Norway spruce to climate along an altitudinal gradient in the Tatra Mountains, Poland. Trees 20(6): 735–746, DOI 10.1007/s00468-006-0088-9.
• 31. Shao XM, 2005. Reconstruction of precipitation variation from tree rings in recent 1000 years in Delingha, Qinghai. Science in China Series D 48(7): 939, DOI 10.1360/03yd0146.
• 32. Shi YF, Shen YP, Kang ES, Li DL, Ding YJ, Zhang GW and Hu RJ, 2006. Recent and future climate change in northwest China. Climatic Change 80(3–4): 379–393, DOI 10.1007/s10584-006-9121-7.
• 33. Shirenna J, Zhang TW, Yu SL, Jiang SX and Xu ZL, 2020. Picea schrenkiana response to climate change at different altitudes in Tianshan Mountains. Arid Zone Research 38(2): 327–338 (in Chinese).
• 34. Solomina O, Maximova O and Cook E, 2014. Picea schrenkiana ring width and density at the upper and lower tree limits in the tien shan mts (kyrgyz republic) as a source of paleoclimatic information. Geography, Environment, Sustainability 7(1): 66–79, DOI 10.24057/2071-9388-2014-7-1-66-79.
• 35. Solomina ON, Dolgova EA and Maximova OE, 2012. Tree-Ring Based Hydrometeorological Reconstructions in Crimea, Caucasus and Tien-Shan. Nestor-History, Moscow-Saint-Petersburg: 232pp.
• 36. Tegel W, Seim A, Hakelberg D, Hoffmann S, Panev M, Westphal T and Büntgen U, 2014. A recent growth increase of European beech (Fagus sylvatica L.) at its Mediterranean distribution limit contradicts drought stress. European Journal of Forest Research 133: 61–71.
• 37. Wang T, Ren GY, Chen F and Yuan YJ, 2015b. An analysis of precipitation variations in the west-central Tianshan Mountains over the last 300 years. Quaternary International 358: 48–57, DOI 10.1016/j.quaint.2014.10.051.
• 38. Wang ZY, Yang B, Deslauriers A and Bräuning A, 2015a. Intra-annual stem radial increment response of Qilian juniper to temperature and precipitation along an altitudinal gradient in northwestern China. Trees 29(1): 25–34, DOI 10.1007/s00468-014-1037-7.
• 39. Wigley TML, Briffa KR and Jones PD, 1984. On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. Journal of Climate and Applied Meteorology 23(2): 201–213, DOI 10.1175/1520-0450(1984)023<0201:otavoc>2.0.co;2.
• 40. White PB, Soule′ P and van de Gevel S, 2014. Impacts of human disturbance on the temporal stability of climate–growth relationships in a red spruce forest, southern Appalachian Mountains, USA. Dendrochronologia 32: 71–77.
• 41. Wilson RJS and Hopfmueller M, 2001. Dendrochronological investigations of Norway spruce along an elevational transect in the Bavarian Forest, Germany. Dendrochronologia 19(1): 67–79.
• 42. Wu GJ, Liu XH, Chen T, Xu GB, Wang WZ, Zeng XM and Zhang XW, 2015. Elevation-dependent variations of tree growth and intrinsic water-use efficiency in Schrenk spruce (Picea schrenkiana) in the western Tianshan Mountains, China. Frontiers in Plant Science 6: 309–309, DOI 10.3389/fpls.2015.00309.
• 43. Xu GB, Liu XH, Qin DH, Chen T, Wang WZ, Wu GJ, Sun WZ, An WL and Zeng XM, 2013. Relative humidity reconstruction for northwestern China's Altay Mountains using tree-ring δ18O. Chinese Science Bulletin 59(2): 190–200, DOI 10.1007/s11434-013-0055-y.
• 44. Yang B, He MH, Shishov V, Tychkov I, Vaganove E, Rossi S, Ljungqvist FC, Bräuning A and Grießinger J, 2017. New perspective on spring vegetation phenology and global climate change based on Tibetan Plateau tree-ring data. Proceedings of the National Academy of Sciences U S A 114(27): 6966–6971.
• 45. Yao JQ, Chen YN and Yang Q, 2016. Spatial and temporal variability of water vapor pressure in the arid region of northwest China, during 1961–2011. Theoretical and Applied Climatology 123(3–4): 683–691, DOI 10.1007/s00704-015-1373-6.
• 46. Yuan Y, 2003. Variations of the spring precipitation day numbers reconstructed from tree rings in the Urumqi River drainage, Tianshan Mts. over the last 370 years. Chinese Science Bulletin 48(14): 1507–1510, DOI 10.1360/02wd0251.
• 47. Zhang RB, Ermenbaev B, Zhang HL, Shang HM, Zhang TW, Yu SL, Chontoev DT, Satylkanov R and Qin L, 2020. Natural discharge changes of the Naryn River over the past 265 years and their climatic drivers. Climate Dynamics 55(5–6): 1269–1281, DOI 10.1007/s00382-020-05323-1.
• 48. Zhang RB, Shang HM, Yu SL, He Q, Yuan YJ, Bolatov K and Mambetov BT, 2017a. Tree-ring-based precipitation reconstruction in southern Kazakhstan, reveals drought variability since A.D. 1770. International Journal of Climatology 37(2): 741–750, DOI 10.1002/joc.4736.
• 49. Zhang RB, Wei WS, Shang HM, Yu SL, Gou XH, Qin L, Bolatov K and Mambetov BT, 2019. A tree ring-based record of annual mass balance changes for the TS. Tuyuksuyskiy Glacier and its linkages to climate change in the Tianshan Mountains. Quaternary Science Reviews 205: 10–21, DOI 10.1016/j.quascirev.2018.11.028.
• 50. Zhang RB, Yuan YJ, Gou XH, He Q, Shang HM, Zhang TW, Chen F, Ermenbaev B, Yu SL, Qin L and Fan ZA, 2016a. Tree-ring-based moisture variability in western Tianshan Mountains since A.D. 1882 and its possible driving mechanism. Agricultural and Forest Meteorology 218–219: 267–276, DOI 10.1016/j.agrformet.2015.12.067.
• 51. Zhang RB, Yuan YJ, Gou XH, Zhang TW, Zou C, Ji CR, Fan ZA, Qin L, Shang HM and Li XJ, 2016b. Intra-annual radial growth of Schrenk spruce (Picea schrenkiana Fisch. et Mey) and its response to climate on the northern slopes of the Tianshan Mountains. Dendrochronologia 40: 36–42, DOI 10.1016/j.dendro.2016.06.002.
• 52. Zhang RB, Yuan YJ, Wei WS, Gou XH, Yu SL, Shang HM, Zhang TW, Chen F and Qin L, 2016c. Research advances of dendroclimatology in Tianshan Mountains, Desert and Oasis Meteorology 10(04): 1–9 (in Chinese).
• 53. Zhang RB, Yuan YJ, Yu SL, Chen F and Zhang TW, 2017b. Past changes of spring drought in the inner Tianshan Mountains, China, as recorded by tree rings. Boreas 46(4): 688–696, DOI 10.1111/bor.12238.
• 54. Zhang WT, Jiang Y, Dong MY, Kang MY and Yang HC, 2012. Relationship between the radial growth of Picea meyeri and climate along elevations of the Luyashan Mountain in North-Central China. Forest Ecology and Management 265: 142–149, DOI 10.1016/j.foreco.2011.10.017.
• 55. Zhang YX and Wilmking M, 2010. Divergent growth responses and increasing temperature limitation of Qinghai spruce growth along an elevation gradient at the northeast Tibet Plateau. Forest Ecology Management 260: 1076–1082.