Vaganov-Shashkin (VS)和VS-Lite树木年轮宽度生理过程模型研究进展

doi:10.13287/j.1001-9332.202408.005

摘要/Abstract

摘要： Vaganov-Shashkin (VS)和VS-Lite模型是当前国际上应用最广泛的树木年轮宽度生理过程模型,它们能够揭示树轮宽度变化与外界气候要素之间的内在响应机制。VS模型主要用于气候重建、木质部物候预测和形成层细胞活动的模拟,VS-Lite模型则主要用于预测生长趋势。本文收集2005—2023年发表的VS和VS-Lite模型的相关文献,综述了两个模型的基本原理、参数设置和发展历史,及其在树木年轮气候学、木质部物候学和森林生态学等领域的研究进展。最后,总结了目前模型存在的问题,提出未来研究需要进一步优化模型参数调整方法,关注多种环境因素对树木生理过程的影响,并加强与其他植被生态模型的对比研究,以提高模拟结果的可信度。

关键词: 树木年轮, Vaganov-Shashkin模型, VS-Lite模型, 径向生长

Abstract: The Vaganov-Shashkin (VS) and VS-Lite models are the most widely used physiological processes-based models of tree-ring width. Both models can reveal the intrinsic response mechanism between tree-ring width and external climate factors. The VS model is commonly applied in climate reconstruction, wood phenology prediction, and the simulation of cambial activity, while the VS-Lite model is primarily applied in forecasting growth trends of forest. We collected papers related to the VS and VS-Lite models published between 2005 and 2023, and reviewed the fundamental principles, parameter settings, and historical development of both models, as well as the their applications in research areas of dendroclimatology, xylem phenology, and forest ecology. Then, we summarized the current issues with the models and proposed future research directions. To increase confidence in the simulation results, it is essential to optimize the parameter adjustment method of the models, consider the impact of multiple environmental factors on the physiological processes of trees, and strengthen the comparative study of the VS and VS-Lite model with other vegetation ecological models.

Key words: tree-ring, Vaganov-Shashkin model, VS-Lite model, radial growth

闫绘月, 曾小敏, 薛钰, 刘晓宏. Vaganov-Shashkin (VS)和VS-Lite树木年轮宽度生理过程模型研究进展[J]. 应用生态学报, 2024, 35(8): 2256-2266.

YAN Huiyue, ZENG Xiaomin, XUE Yu, LIU Xiaohong. Research progress on physiological processes-based tree-ring width models of Vaganov-Shashkin (VS)and VS-Lite[J]. Chinese Journal of Applied Ecology, 2024, 35(8): 2256-2266.

参考文献

[1] 李雪, 黄选瑞, 张先亮. 不同去趋势方法对树轮气候信号识别的影响. 生态学报, 2021, 41(5): 1970-1978
[2] Evans MN, Reichert BK, Kaplan A, et al. A forward modeling approach to paleoclimatic interpretation of tree-ring data. Journal of Geophysical Research: Biogeosciences, 2006, 111: G03008
[3] Zeng XM, Evans MN, Liu XH, et al. Spatial patterns of precipitation-induced moisture availability and their effects on the divergence of conifer stem growth in the western and eastern parts of China’s semi-arid region. Forest Ecology and Management, 2019, 451: 117524
[4] 贺敏慧, 杨保. 树轮生理模型研究进展. 第四纪研究, 2015, 35(5): 1261-1270
[5] Vaganov EA, Hughes MK, Shashkin AV. Growth Dynamics of Conifer Tree Rings: Images of Past and Future Environments. New York: Springer Science & Business Media, 2006: 189-243
[6] Shashkin AV, Vaganov EA. Simulation model of climatically determined variability of conifers’ annual increment: On the example of common pine in the steppe zone. Russian Journal of Ecology, 1993, 24: 275-280
[7] Tolwinski-Ward SE, Evans MN, Hughes MK, et al. An efficient forward model of the climate controls on interannual variation in tree-ring width. Climate Dynamics, 2011, 36: 2419-2439
[8] Whittaker RH. Communities and Ecosystems. New York: Macmillan, 1975: 281-333
[9] Deshmukh A, Singh R. A Whittaker biome-based framework to account for the impact of climate change on catchment behavior. Water Resources Research, 2019, 55: 11208-11224
[10] Huang J, van den Dool HM, Georgarakos KP. Analysis of model-calculated soil moisture over the United States (1931-1993) and applications to long-range temperature forecasts. Journal of Climate, 1996, 9: 1350-1362
[11] 史江峰, 刘禹, Vaganov EA, 等. 贺兰山油松生长的气候响应机制初步探讨. 第四纪研究, 2005, 25(2): 245-251
[12] 包光, 刘治野, 刘娜, 等. 呼伦贝尔沙地樟子松径向生长特征的VS模型模拟分析. 应用生态学报, 2021, 32(10): 3448-3458
[13] 赵浩唱, 刘小粉, 牛进松, 等. 基于VS模型的樟子松人工林径向生长过程及其气候响应. 陆地生态系统与保护学报, 2023, 3(2): 1-10
[14] Tolwinski-Ward SE, Anchukaitis KJ, Evans MN. Baye-sian parameter estimation and interpretation for an intermediate model of tree-ring width. Climate of the Past, 2013, 9: 1481-1493
[15] Kirdyanov AV, Krusic PJ, Shishov VV, et al. Ecological and conceptual consequences of Arctic pollution. Ecology Letters, 2020, 23: 1827-1837
[16] Evans MN, Smerdon JE, Kaplan A, et al. Climate field reconstruction uncertainty arising from multivariate and nonlinear properties of predictors. Geophysical Research Letters, 2014, 41: 9127-9134
[17] Tolwinski-Ward SE, Tingley MP, Evans MN, et al. Probabilistic reconstructions of local temperature and soil moisture from tree-ring data with potentially time-varying climatic response. Climate Dynamics, 2015, 44: 791-806
[18] Breitenmoser P, Brönnimann S, Frank D. Forward mode-lling of tree-ring width and comparison with a global network of tree-ring chronologies. Climate of the Past, 2014, 10: 437-449
[19] Acevedo W, Fallah B, Reich S, et al. Assimilation of pseudo-tree-ring-width observations into an atmospheric general circulation model. Climate of the Past, 2017, 13: 545-557
[20] Fritts HC, Vaganov EA, Sviderskaya IV, et al. Climatic variation and tree-ring structure in conifers: Empirical and mechanistic models of tree-ring width, number of cells, cell size, cell-wall thickness and wood density. Climate Research, 1991, 1: 97-116
[21] Fritts HC, Shashkin AV. Modeling tree-ring structure as related to temperature, precipitation, and day length//Lewis TE, ed. Tree Rings as Indicators of Ecosystem Health. Boca Raton, FL, USA: CRC Press, 1994: 17-57
[22] Fritts HC, Shashkin AV, Downes GM. A simulation model of conifer ring growth and cell structure//Wimmer R, Vetter RE, ed. Tree Ring Analysis: Biological, Methodological and Environmental Aspects. Wallingford, UK: CABI Publishing, 1999: 3-32
[23] Eckes-Shephard AH, Ljungqvist FC, Drew DM, et al. Wood formation modeling: A research review and future perspectives. Frontiers in Plant Science, 2022, 13: 837648
[24] Shishov VV, Tychkov II, Popkova MI, et al. VS-oscilloscope: A new tool to parameterize tree radial growth based on climate conditions. Dendrochronologia, 2016, 39: 42-50
[25] Anchukaitis KJ, Evans MN, Hughes MK, et al. An interpreted language implementation of the Vaganov-Shashkin tree-ring proxy system model. Dendrochronologia, 2020, 60: 125677
[26] Mina M, Martin-Benito D, Bugmann H, et al. Forward modeling of tree-ring width improves simulation of forest growth responses to drought. Agricultural and Forest Meteorology, 2016, 221: 13-33
[27] Tipton J, Hooten M, Pederson N, et al. Reconstruction of late Holocene climate based on tree growth and mecha-nistic hierarchical models. Environmetrics, 2016, 27: 42-54
[28] Allen ST, Keim RF. Wetland-tree growth responses to hydrologic variability derived from development and optimization of a non-linear radial growth model. Ecological Modelling, 2017, 354: 49-61
[29] Campelo F, Ribas M, Gutiérrez E. Plastic bimodal growth in a Mediterranean mixed-forest of Quercus ilex and Pinus halepensis. Dendrochronologia, 2021, 67: 125836
[30] Touchan R, Shishov VV, Meko DM, et al. Process based model sheds light on climate signal of Mediterranean tree rings. Biogeosciences, 2012, 9: 965-972
[31] Zhang YX, Shao XM, Xu Y, et al. Process-based mode-ling analyses of Sabina przewalskii growth response to climate factors around the northeastern Qaidam Basin. Chinese Science Bulletin, 2011, 56: 1518-1525
[32] 王延芳, 张永香, 勾晓华, 等. 祁连山中部低海拔地区青海云杉径向生长的气候响应机制. 生态学报, 2020, 40(1): 161-169
[33] Jia HF, Fang OY, Lyu L. Non-linear modelling reveals a predominant moisture limit on juniper growth across the southern Tibetan Plateau. Annals of Botany, 2022, 130: 85-95
[34] Xue HH, Shi F, Gennaretti F, et al. Evidence of advancing spring xylem phenology in Chinese forests under global warming. Science China Earth Sciences, 2023, 66: 2187-2199
[35] Kašpar J, Tumajer J, Šamonil P, et al. Species-specific climate- growth interactions determine tree species dynamics in mixed Central European mountain forests. Environmental Research Letters, 2021, 16: 034039
[36] Zeng XM, Evans MN, Liu XH, et al. Process representation of conifer tree-ring growth is improved by incorporation of climate memory effects. Agricultural and Forest Meteorology, 2022, 327: 109196
[37] Sánchez-Salguero R, Camarero JJ. Greater sensitivity to hotter droughts underlies juniper dieback and mortality in Mediterranean shrublands. Science of the Total Environment, 2020, 721: 137599
[38] Matskovsky V, Venegas-González A, Garreaud R, et al. Tree growth decline as a response to projected climate change in the 21st century in Mediterranean mountain forests of Chile. Global and Planetary Change, 2021, 198: 103406
[39] Wu ML, Liu N, Bao G, et al. Climatic factors of radial growth of Pinus tabuliformis in eastern Gansu, northwest China based on Vaganov-Shashkin model. Geografiska Annaler: Series A, Physical Geography, 2020, 102: 196-208
[40] 李明明, 李刚. 贺兰山地区植被冠层物候与树干形成层物候的关系. 应用生态学报, 2021, 32(2): 495-502
[41] Steiger NJ, Smerdon JE. A pseudoproxy assessment of data assimilation for reconstructing the atmosphere-ocean dynamics of hydroclimate extremes. Climate of the Past, 2017, 13: 1435-1449
[42] Yang B, He MH, Shishov VV, et al. New perspective on spring vegetation phenology and global climate change based on Tibetan Plateau tree-ring data. Proceedings of the National Academy of Sciences of the United States of America, 2017, 114: 6966-6971
[43] He MH, Yang B, Shishov VV, et al. Projections for the changes in growing season length of tree-ring formation on the Tibetan Plateau based on CMIP5 model simulations. International Journal of Biometeorology, 2018, 62: 631-641
[44] Campelo F, Rubio-Cuadrado Á, Montes F, et al. Growth phenology adjusts to seasonal changes in water availability in coexisting evergreen and deciduous Mediterranean oaks. Forest Ecosystems, 2023, 10: 100134
[45] 陈兰, 李书恒, 侯丽, 等. 基于Vaganov-Shashkin模型的太白红杉径向生长对气候要素的响应. 应用生态学报, 2017, 28(8): 2470-2480
[46] Kang J, Shishov VV, Tychkov II, et al. Response of model-based cambium phenology and climatic factors to tree growth in the Altai Mountains, Central Asia. Ecological Indicators, 2022, 143: 109393
[47] Tumajer J, Buras A, Camarero JJ, et al. Growing faster, longer or both? Modelling plastic response of Juniperus communis growth phenology to climate change. Global Ecology and Biogeography, 2021, 30: 2229-2244
[48] Tumajer J, Kašpar J, Kuželová H, et al. Forward mode-ling reveals multidecadal trends in cambial kinetics and phenology at treeline. Frontiers in Plant Science, 2021, 12: 613643
[49] Tychkov II, Sviderskaya IV, Babushkina EA, et al. How can the parameterization of a process-based model help us understand real tree-ring growth? Trees, 2019, 33: 345-357
[50] Camarero JJ, Campelo F, Colangelo M, et al. Decoupled leaf-wood phenology in two pine species from contrasting climates: Longer growing seasons do not mean more radial growth. Agricultural and Forest Meteorology, 2022, 327: 109223
[51] 王亚锋, 梁尔源, 芦晓明, 等. 气候变暖会使青藏高原树线一直上升吗? 自然杂志, 2017, 39(3): 179-183
[52] Li XX, Liang E, Gricˇar J, et al. Critical minimum temperature limits xylogenesis and maintains treelines on the southeastern Tibetan Plateau. Science Bulletin, 2017, 62: 804-812
[53] Sánchez-Salguero R, Camarero JJ, Gutiérrez E, et al. Climate warming alters age-dependent growth sensitivity to temperature in Eurasian Alpine treelines. Forests, 2018, 9: 688
[54] Sun JY, Liu N, Bao G, et al. Features of radial growth rate of trees in agro-pastoral transition zone, Northern China. Forests, 2022, 13: 1712
[55] Sánchez-Salguero R, Camarero JJ, Gutiérrez E, et al. Assessing forest vulnerability to climate warming using a process-based model of tree growth: Bad prospects for rear-edges. Global Change Biology, 2017, 23: 2705-2719
[56] McAlhaney AL, Keim RF, Allen ST. Species-specific growth capacity for floodplain forest trees inferred from sapwood efficiency and individual tree competition. Forest Ecology and Management, 2020, 476: 118427
[57] Camarero JJ, Sánchez-Salguero R, Sangüesa-Barreda G, et al. Drought, axe and goats. More variable and synchronized growth forecasts worsening dieback in Moroccan Atlas cedar forests. Science of the Total Environment, 2021, 765: 142752
[58] Buttò V, Shishov VV, Tychkov II, et al. Comparing the cell dynamics of tree-ring formation observed in microcores and as predicted by the Vaganov-Shashkin model. Frontiers in Plant Science, 2020, 11: 1268
[59] Arzac A, Babushkina EA, Fonti P, et al. Evidences of wider latewood in Pinus sylvestris from a forest-steppe of Southern Siberia. Dendrochronologia, 2018, 49: 1-8
[60] Edwards J, Anchukaitis KJ, Zambri B, et al. Intra-annual climate anomalies in northwestern North America following the 1783-1784 CE Laki eruption. Journal of Geophysical Research: Atmospheres, 2021, 126: e2020JD033544
[61] Popkova MI, Vaganov EA, Shishov VV, et al. Modeled tracheidograms disclose drought influence on Pinus sylvestris tree-rings structure from Siberian forest-steppe. Frontiers in Plant Science, 2018, 9: 1144
[62] Popkova MI, Ilyin VA, Fonti MV, et al. From modeling the kinetics of cell enlargement to building tracheidograms of Larix gmelinii Rupr. (Rupr.) in the permafrost zone in Siberia. Dendrochronologia, 2023, 79: 126089
[63] Zeng XM, Liu XH, Treydte K, et al. Climate signals in tree-ring δ¹⁸O and δ¹³C from southeastern Tibet: Insights from observations and forward modelling of intra- to interdecadal variability. New Phytologist, 2017, 216: 1104-1118
[64] Britton TG, Richards SA, Hovenden MJ. Quantifying neighbour effects on tree growth: Are common ‘competition’ indices biased? Journal of Ecology, 2023, 111: 1270-1280
[65] Fatichi S, Pappas C, Zscheischler J, et al. Modelling carbon sources and sinks in terrestrial vegetation. New Phytologist, 2019, 221: 652-668
[66] 冉依林, 陈友平, 陈峰, 等. 油松树轮指示的秦岭中部过去194年5—7月NDVI变化. 应用生态学报, 2021, 32(10): 3661-3670
[67] 李颖辉, 齐贵增, 冯荣荣, 等. 秦岭北麓油松径向生长对气候变化的响应. 应用生态学报, 2022, 33(8): 2043-2050

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