A model of cross-sectional growth of Cunninghamia lanceolata plantation in Hunan province with climate effects

Zhantao Qi ,Guangyu Zhu ,Bingbing Yu ,Hongna Liu ,Yong Lv

doi:10.24294/sf.v5i1.1618

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A model of cross-sectional growth of Cunninghamia lanceolata plantation in Hunan province with climate effects

Zhantao Qi

Guangyu Zhu

Bingbing Yu

Hongna Liu

Yong Lv

Sustainable Forestry 2022, 5(1), 30-38; https://doi.org/10.24294/sf.v5i1.1618

Submitted：22 Feb 2022

Accepted：22 Feb 2022

Published：11 Apr 2022

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Abstract

Objective: The influence of climate on forest stands cannot be ignored, but most of the previous forest stand growth models were constructed under the presumption of invariant climate and could not estimate the stand growth under climate change. The model was constructed to provide a theoretical basis for forest operators to take reasonable management measures for fir under the influence of climate. Methods: Based on the survey data of 638 cedar plantation plots in Hunan Province, the optimal base model was selected from four biologically significant alternative stand basal area models, and the significant climate factors without serious covariance were selected by multiple stepwise regression analysis. The optimal form of random effects was determined, and then a model with climatic effects was constructed for the cross-sectional growth of fir plantations. Results: Richards formula is the optimal form of the basic model of stand basal area growth. The coefficient of adjustment was 0.8355; the average summer maximum temperature and the water vapor loss in Hargreaves climate affected the maximum and rate of fir stand stand growth respectively, and were negatively correlated with the stand growth. The adjusted coefficient of determination of the fir stand area break model with climate effects was 0.8921, the root mean square error (RMSE) was 3.0792, and the mean relative error absolute value (MARE) was 9.9011; compared with the optimal base model, improved by 6.77%, RMSE decreased by 19.04%, and MARE decreased by 15.95%. Conclusion: The construction of the stand cross-sectional area model with climate effects indicates that climate has a significant influence on stand growth, which supports the rationality of considering climate factors in the growth model, and it is important for the regional stand growth harvest and management of cedar while improving the accuracy and applicability of the model.

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References

Rodríguez F, Pemán J, Aunós A. A reduced growth model based on stand basal area: A case for hybrid poplar plantations in northeast Spain. Forest Ecology and Management 2010; 259(10): 2093–2102.

Gao D. The research of stand growth forecast models for Quercus mongolica and Pinus tabulaeformis in Beijing [MSc thesis]. Beijing: Beijing Forestry University; 2014.

Hu S. Research on basal area growth model for oak natural forest in Hunan province [MSc thesis]. Changsha: Central South University of Forestry and Technology; 2019.

Duan A, Zhang J, Sun H, et al. Research progress of growth simulation theories and technologies for stand basal area. World Forestry Research 2013; 26(2): 43–47.

Zhao Y, Wang X, Jiang T, et al. Growth model for thinned and un-thinned stand of Chinese fir reserve forest based on error measurement method. Journal of Northwest Forestry University 2019; 34(4): 185–191.

Che S. Growth modeling for Chinese fir plantation based on artificial neural network [PhD thesis]. Beijing: Chinese Academy of Forestry; 2012.

Li C. Application of mixed effect models in forest growth models [PhD thesis]. Beijing: Chinese Academy of Forestry Sciences; 2010.

Colbert JJ, Schuckers M, Fekedulegn D, et al. Individual tree basal-area growth parameter estimates for four models. Ecological Modelling 2004; 174(1–2): 115–126.

Hostin PJ, Titus SJ. Indirect site productivity models for white spruce in Alberta’s boreal mixedwood forest. The Forestry Chronicle 1996; 72(1): 73–79.

Gao D, Deng H, Jiang Y, et al. Forecast models research of stands basal area growth for Pinus tabulaeformis. Journal of Southwest Forestry University 2015; 35(1): 42–46.

Yan W, Duan G, Wang Y, et al. Construction of stand basal area and volume growth model for Quercus and Populus in Henan Province of Central China. Journal of Beijing Forestry University 2019; 41(6): 55–61.

Zang H. Regional-scale climate-sensitive stand growth models for larch plantations [PhD thesis]. Beijing: Chinese Academy of Forestry; 2016.

Liao Y, Peng J, Guo Q. Response of Hunan climate to global climate change. Transactions of Atmospheric Sciences 2014; 37(1): 75–81.

Mei G. Study on growth model and multi-functional simulation of Chinese fir plantation [PhD thesis]. Beijing: Beijing Forestry University; 2017.

Gao D, Deng H, Cheng Z, et al. Study on growth models for thinned and un-thinned stands of Quercus mongolica. Journal of Central South University of Forestry & Technology 2014; 34(2): 50–54.

Zhu G, Hu S, Fu L. Basal area growth model for oak natural forest in Hunan Province based on dummy variable. Journal of Nanjing Forestry University (Natural Sciences Edition) 2018; 42(2): 155–162.

Guo X. Crown structure and growth model for Larix olgensis plantation [PhD thesis]. Beijing: Beijing Forestry University; 2013.

Chen Z, He D, He P. Using mixed-effects modeling method to establish standing volume equations for rubber tree in Hainan Province. Journal of Central South University of Forestry & Technology 2016; 36(12): 31–36.

Pandhard X, Samson A. Extension of the SAEM algorithm for nonlinear mixed models with 2 levels of random effects. Biostatistics 2009; 10(1): 121–135.

Sharma M, Parton J. Height-diameter equations for boreal tree species in Ontario using a mixed-effects modeling approach. Forest Ecology and Management 2007; 249(3): 187–198.

Liu F, Huang R, Jiang S, et al. Study on the growth rhythm of Keteleeria fortunei var. cyclolepis plantation. Journal of Central South University of Forestry & Technology 2020; 40(3): 39–52.

Li Y, Kang X. Mixed model of forest space utilization in spruce-fir coniferous and broadleaved mixed forest of Changbai Mountains, Northeastern China. Journal of Beijing Forestry University 2020; 42(5): 71–79.

Li X, Tang S, Wang S. The establishment of variable density yield table for Chinese fir plantation in Dagangshan experiment bureau. Forest Research 1988; 1(4): 382–389.

Li C, Tang S. The basal area model of mixed stands of Larix olgensis, Abies nephrolepis and Picea jezoensis based on nonlinear mixed model. Scientia Silvae Sinicae 2010; 46(7): 106–113.

Zhu A. Response of tree ring to climate change of different provenances of Cunninghamia lanceolata [MSc thesis]. Beijing: Chinese Academy of Forestry Sciences; 2016.

Lv Z, Li W, Huang X, et al. Predicting suitable distribution area of three dominant tree species under climate change scenarios in Hebei Province. Scientia Silvae Sinicae 2019; 55(3): 13–21.

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