混交林生产力研究进展

doi:10.13287/j.1001-9332.202311.027

摘要/Abstract

摘要： 依据造林树种的生物学特性,采用科学培育模式改善种间关系和生境条件以提高森林资源利用效率,是提升混交林生产力的有效途径之一。本研究评价了混交林生产力的两类估测方法,分析了种间竞争和互补效应影响混交林生产力的内在机制,并从外在因素出发,阐明了林内生长空间和生境因子如何调控混交林生产力,探讨了树种组成、林分密度、立地质量等对混交林生产力的影响过程,以及林分发育过程中生产力的整体变化规律。最后,在明晰影响混交林生产力形成的内在机制和生境要素的基础上,围绕当前混交林培育模式构建所亟需解决的关键科学问题,提出了今后混交林生产力提升的研究方向:完善生产力估算体系;建立长期的混交林样地;加强多种培育措施的综合效应研究;强化混交林的生长发育进程研究。

关键词: 混交林, 森林生产力, 种间相互作用, 互补作用, 环境因素, 培育措施

Abstract: One of the effective ways to improve the productivity of mixed forests is enhancing resource use efficiency based on the biological characteristics of afforestation tree species. Resource use efficiency is affected by tree species interactions and environmental conditions through applying appropriate cultivation patterns. In this study, we evaluated two estimating methods for the productivity of mixed forest, analyzed the internal mechanism of interspecific tree competition and complementary effects on mixed forest productivity, clarified external factors of growth space and habitat factors control over productivity of mixed forest, discussed the effects of tree species composition, stand density and site quality on productivity, and illustrated the productivity trajectory during the development of mixed forests. Finally, based on the knowledge of the internal mechanism and habitat factors affecting the formation of mixed forest productivity, we focused on the key scientific issues that urgently need to be solved in the construction of the current mixed forests cultivation patterns, and put forward future research directions, including improving the productivity estimation system, establishing long-term mixed forest observation field, enhancing the research on the comprehensive effect of various cultivation measures, and reinforcing research of the growth and development dynamics in mixed forests.

Key words: mixed forest, forest productivity, interspecific interaction, complementarity, environmental factor, cultivation measure

尹再芳, 孙洪刚, 谭梓峰, 刘威. 混交林生产力研究进展[J]. 应用生态学报, 2023, 34(11): 3135-3143.

YIN Zaifang, SUN Honggang, TAN Zifeng, LIU Wei. Research progress on productivity of mixed forest.[J]. Chinese Journal of Applied Ecology, 2023, 34(11): 3135-3143.

参考文献

[1] 盛炜彤. 关于我国人工林长期生产力的保持. 林业科学研究, 2018, 31(1): 1-14
[2] Forrester DI. The spatial and temporal dynamics of species interactions in mixed-species forests: From pattern to process. Forest Ecology and Management, 2014, 312: 282-292
[3] Pretzsch H, Forrester DI. Stand dynamics of mixed-species stands compared with monocultures// Pretzsch H, Forrester DI, Bauhus J, eds. Mixed-species Forests. Berlin: Springer, 2017
[4] 李文华. 森林生物生产量的概念及其研究的基本途径. 自然资源, 1978(1): 71-92
[5] 徐雨晴, 肖风劲, 於琍. 中国森林生态系统净初级生产力时空分布及其对气候变化的响应研究综述. 生态学报, 2020, 40(14): 4710-4723
[6] 朱文泉, 陈云浩, 徐丹, 等. 陆地植被净初级生产力计算模型研究进展. 生态学杂志, 2005, 24(3): 296-300
[7] Chen JM, Liu J, Cihlar J, et al. Daily canopy photosynthesis model through temporal and spatial scaling for remote sensing applications. Ecological Modelling, 1999, 124: 99-119
[8] Shi H, Li LH, Eamus D, et al. Assessing the ability of MODIS EVI to estimate terrestrial ecosystem gross primary production of multiple land cover types. Ecological Indicators, 2017, 72: 153-164
[9] Pretzsch H. Individual tree structure and growth in mixed compared with monospecific stands// Pretzsch H, Forrester DI, Bauhus J, eds. Mixed-species Forests. Berlin: Springer, 2017
[10] Aldea J, Ruiz-Peinado R, Rio MD, et al. Species stratification and weather conditions drive tree growth in Scots pine and Norway spruce mixed stands along Europe. Forest Ecology and Management, 2021, 481: 118697
[11] Ferrio JP, Shestakova TA, Castillo JD, et al. Oak competition dominates interspecific interactions in growth and water-use efficiency in a mixed pine-oak Mediterranean forest. Forests, 2021, 12: 1093
[12] Brunner A, Forrester DI. Tree species mixture effects on stem growth vary with stand density: An analysis based on individual tree responses. Forest Ecology and Mana-gement, 2020, 473: 118334
[13] 董雪婷, 张静, 张志东, 等. 树种相互作用、林分密度和树木大小对华北落叶松生产力的影响. 应用生态学报, 2021, 32(8): 2722-2728
[14] 桑卫国. 用动态模型研究森林群落中物种间的竞争. 生态学报, 2001, 21(11): 1802-1807
[15] Forrester DI. Ecological and physiological processes in mixed versus monospecific stands// Pretzsch H, Forrester DI, Bauhus J, eds. Mixed-species Forests. Berlin: Springer, 2017
[16] Feng YH, Schmid B, Loreau M, et al. Multispecies forest plantations outyield monocultures across a broad range of conditions. Science, 2022, 376: 865-868
[17] Riofrio J, Rio MD, Pretzsch H, et al. Changes in structural heterogeneity and stand productivity by mixing Scots pine and Maritime pine. Forest Ecology and Management, 2017, 405: 219-228
[18] Mina M, Huber MO, Forrester DI, et al. Multiple factors modulate tree growth complementarity in central European mixed forests. Journal of Ecology, 2018, 106: 1106-1119
[19] Andres EGD, Seely B, Blanco JA, et al. Increased complementarity in water-limited environments in Scots pine and European beech mixtures under climate change. Ecohydrology, 2017, 10: e1810
[20] 惠刚盈. 基于相邻木关系的林分空间结构参数应用研究. 北京林业大学学报, 2013, 35(4): 1-9
[21] 刘铭波, 韩海荣, 程小琴, 等. 山西灵空山典型天然林空间结构特征及其对生产力的影响. 西北林学院学报, 2022, 37(1): 33-40
[22] 惠刚盈, 胡艳波. 混交林树种空间隔离程度表达方式的研究. 林业科学研究, 2001, 14(1): 23-27
[23] 吕延杰, 杨华, 张青, 等. 云冷杉天然林林分空间结构对胸径生长量的影响. 北京林业大学学报, 2017, 39(9): 41-47
[24] Brullhardt M, Rotach P, Bigler C, et al. Growth and resource allocation of juvenile European beech and sycamore maple along light availability gradients in uneven-aged forests. Forest Ecology and Management, 2020, 474: 118314
[25] Song Y, Yan G, Zhang G. Light competition contributes to the death of Masson pines of coniferous-broadleaf mixed forests in Subtropical China. Forests, 2022, 13: 85
[26] 吴玉莲, 王襄平, 李巧燕, 等. 长白山阔叶红松林净初级生产力对气候变化的响应: 基于BIOME-BGC模型的分析. 北京大学学报: 自然科学版, 2014, 50(3): 577-586
[27] 张晓曦, 刘慧, 王博雅, 等. 云杉与阔叶树种新鲜凋落叶混合分解特征. 生态环境学报, 2019, 28(2): 235-244
[28] Quesada CA, Phillips OL, Schwarz M, et al. Basin-wide variations in Amazon forest structure and function are mediated by both soils and climate. Biogeosciences, 2012, 9: 2203-2246
[29] Baribault TW, Kobe RK, Rothstein DE. Soil calcium, nitrogen, and water are correlated with aboveground net primary production in northern hardwood forests. Forest Ecology and Management, 2010, 260: 723-733
[30] Makela A, Valentine HT, Helmisaari HS. Optimal co-allocation of carbon and nitrogen in a forest stand at steady state. New Phytologist, 2008, 180: 114-123
[31] 陈永亮, 韩士杰, 周玉梅, 等. 胡桃楸、落叶松纯林及其混交林根际土壤有效磷特性的研究. 应用生态学报, 2002, 13(7): 790-794
[32] 王绍强, 于贵瑞. 生态系统碳氮磷元素的生态化学计量学特征. 生态学报, 2008, 28(8): 3937-3947
[33] Homeier J, Leuschner C. Factors controlling the productivity of tropical Andean forests: Climate and soil are more important than tree diversity. Biogeosciences, 2021, 18: 1525-1541
[34] Sun MM, Zhai BC, Chen QW, et al. Effects of soil nutrients and stand structure on aboveground net primary productivity of oak secondary forests in the forest steppe transition zone of Loess Plateau, China. Canadian Journal of Forest Research, 2021, 51: 1208-1217
[35] 张忠华, 胡刚, 祝介东, 等. 喀斯特森林土壤养分的空间异质性及其对树种分布的影响. 植物生态学报, 2011, 35(10): 1038-1049
[36] Melis R, Morillas L, Roales J, et al. Functional traits related to competition for light influence tree diameter increments in a biodiversity manipulation experiment. European Journal of Forest Research, 2023, 142: 709-722
[37] 杨承栋. 发展有群落结构混交林是维护、恢复和提高森林土壤功能实现人工林可持续经营的关键技术. 林业科学, 2022, 58(8): 26-40
[38] 李茜, 王晖, 栾军伟, 等. 树种多样性和土壤微生物多样性对人工林生产力的影响. 生态学报, 2023, 43(12): 4984-4994
[39] Lu HC, Mohren GMJ, Ouden JD, et al. Overyielding of temperate mixed forests occurs in evergreen-deciduous but not in deciduous-deciduous species mixtures over time in the Netherlands. Forest Ecology and Management, 2016, 376: 321-332
[40] Schmidt M, Veldkamp E, Corre MD. Tree species diversity effects on productivity, soil nutrient availability and nutrient response efficiency in a temperate deciduous forest. Forest Ecology and Management, 2015, 338: 114-123
[41] Lohbeck M, Poorter L, Martinez-Ramos M, et al. Biomass is the main driver of changes in ecosystem process rates during tropical forest succession. Ecology, 2015, 96: 1242-1252
[42] Yuan ZQ, Ali A, Wang SP, et al. Abiotic and biotic determinants of coarse woody productivity in temperate mixed forests. Science of the Total Environment, 2018, 630: 422-431
[43] Castagneyrol B, Jactel H, Vacher C, et al. Effects of plant phylogenetic diversity on herbivory depend on herbivore specialization. Journal of Applied Ecology, 2014, 51: 134-141
[44] Mason WL, Stokes V, Forster J. Proportions of a pine nurse influences overyielding in planted spruce forests of Atlantic Europe. Forest Ecology and Management, 2021, 482: 118836
[45] Riofrio J, Rio MD, Bravo F. Mixing effects on growth efficiency in mixed pine forests. Forestry, 2017, 90: 381-392
[46] 张雪儿, 乔雪涛, 张春雨, 等. 吉林蛟河针阔混交林生物量时间稳定性驱动机制. 生态学杂志, 2023, 42(4): 812-819
[47] 范迎新, 李传荣, 许景伟, 等. 沙质海岸人工混交林种群竞争及其生态位. 中南林业科技大学学报, 2008, 92(2): 40-44
[48] Condes S, Rio MD, Sterba H. Mixing effect on volume growth of Fagus sylvatica and Pinus sylvestris is modulated by stand density. Forest Ecology and Management, 2013, 292: 86-95
[49] Pretzsch H, Bielak K, Block J, et al. Productivity of mixed versus pure stands of oak (Quercus petraea (MATT.) LIEBL. and Quercus robur L.) and European beech (Fagus sylvatica L.) along an ecological gradient. European Journal of Forest Research, 2013, 132: 263-280
[50] Pretzsch H, Block J, Dieler J, et al. Comparison between the productivity of pure and mixed stands of Norway spruce and European beech along an ecological gradient. Annals of Forest Science, 2010, 67: 712
[51] Bourdier T, Cordonnier T, Kunstler G, et al. Tree size inequality reduces forest productivity: An analysis combining inventory data for ten European species and a light competition model. PLoS One, 2016, 11(3): e0151852
[52] Pretzsch H. Size-structure dynamics in mixed versus monospecific stands// Pretzsch H, Forrester DI, Bauhus J, eds. Mixed-species Forests. Berlin: Springer, 2017
[53] 阎恩荣, 王希华, 周武. 天童常绿阔叶林演替系列植物群落的N∶P化学计量特征. 植物生态学报, 2008, 32(1): 13-22
[54] 郑芬, 李兆佳, 邱治军, 等. 广东南岭天然常绿阔叶林林下光环境对林下幼树功能性状的影响. 生态学报, 2020, 40(13): 4516-4527
[55] Tang JW, Luyssaert S, Richardson AD, et al. Steeper declines in forest photosynthesis than respiration explain age-driven decreases in forest growth. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111: 8856-8860
[56] 李旭华, 于大炮, 代力民, 等. 长白山阔叶红松林生产力随林分发育的变化. 应用生态学报, 2020, 31(3): 706-716
[57] 黄兴召, 许崇华, 徐俊, 等. 利用结构方程解析杉木林生产力与环境因子及林分因子的关系. 生态学报, 2017, 37(7): 2274-2281
[58] 刘彦春, 张远东, 刘世荣, 等. 川西亚高山针阔混交林乔木层生物量、生产力随海拔梯度的变化. 生态学报, 2010, 30(21): 5810-5820