Enhancing predictive precision of dominant height projection equations for eucalypts by incorporating rainfall and temperature terms

Southern Forests: a Journal of Forest Science Pub Date : 2022-12-20 DOI:10.2989/20702620.2022.2148587

B. G. Mandigora, D. Drew

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Abstract

Short-rotation forest stands are sensitive to extreme climate conditions during their growth period, which presents a challenge to managing forests and modelling forest growth in a constantly changing climate. We developed climate-sensitive dominant height models for the Eucalyptus grandis × Eucalyptus urophylla hybrid (GU) in South Africa. In addition, dominant height growth under three future climate scenarios was investigated. The Chapman– Richards and Gompertz models, modified by within-rotation and long-term climate data, were used to model dominant height. Model testing using independent permanent sample plot data showed that the Gompertz model modified by within-rotation bioclimatic data performed better than the other models. The climate-modified Gompertz model was used to project height growth for eucalypt stands under three future climate scenarios; ‘No change’, ‘RCP4.5’ and ‘RCP8.5’, for two periods: 2050 (years 2040 to 2060); and 2070 (years 2061 to 2080). Climate change might decelerate dominant height growth in the study area, therefore forest management plans need to be adapted accordingly.

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通过纳入降雨和温度项，提高桉树优势高度投影方程的预测精度

短轮伐林分在其生长期对极端气候条件很敏感，这对在不断变化的气候下管理森林和模拟森林生长提出了挑战。本文建立了南非大桉×尾叶桉杂交品种(GU)的气候敏感优势高度模型。此外，还研究了未来3种气候情景下的优势高度增长。查普曼-理查兹模式和Gompertz模式经旋转内和长期气候资料修正后，用于模拟优势高度。利用独立永久样地数据进行的模型检验表明，经轮内生物气候数据修正的Gompertz模型优于其他模型。利用气候修正的Gompertz模型预测了未来3种气候情景下桉树林分的高度增长;“不变”，“RCP4.5”和“RCP8.5”，两个时期:2050年(2040年至2060年);2070年(2061年至2080年)。气候变化可能会减缓研究区优势高度的生长，因此需要相应地调整森林管理计划。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Southern Forests: a Journal of Forest Science

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