基于双哑变量模型预测透光抚育强度对次生林内红松生长的影响

doi:10.13287/j.1001-9332.202406.004

摘要/Abstract

摘要： “栽针保阔”是恢复我国东北阔叶红松林的有效途径,透光抚育能促进冠下红松生长并加快演替进程,但目前有关透光抚育如何影响次生林内红松生长过程仍不清楚。以长白山“栽针保阔”红松林为对象,构建含双哑变量(透光抚育强度和林木分级)的红松胸径和树高生长模型来预测不同透光抚育强度[即对照(未透光)、轻度透光抚育(保留上层郁闭度0.6)、中度透光抚育(0.4)、强度透光抚育(0.2)和全透光(伐除全部上层阔叶树)]林分中红松三级木的生长过程,揭示透光抚育强度对林内红松胸径和树高及高径比的影响规律。结果表明: 6个基础模型中,Gompertz为红松胸径(R²=0.46)和树高(R²=0.81)最优基础模型,在基础模型中引入透光抚育强度单哑变量、双哑变量后胸径模型的R²分别提高至0.65和0.89,树高模型的R²分别提高至0.84和0.94;双哑变量模型为预测红松生长的最适模型。被压木胸径生长在整个模拟预测期间(树龄0～80年)均随透光抚育强度增大而递增(增幅为145.8%～933.3%),而平均木和优势木在中期(42年)、中后期(60年)呈此规律。在初期(20年)和中期,全透光与强度透光抚育对红松优势木(64.8%～68.5%)、平均木(100.0%～144.2%)和被压木(138.5%～183.9%)树高生长的影响程度相近,中度透光抚育和轻度透光抚育对其影响相近(24.3%～35.1%、56.0%～92.3%和84.6%～103.2%);在中后期(62年)和后期(80年),红松三级木树高生长均随透光抚育强度增大而递增。各透光抚育强度下红松优势木、平均木和被压木的高径比变化幅度依次增大,分别为0.50～0.95、0.64～1.23和0.73～4.33;仅被压木在树龄0～80年随透光抚育强度增大而递减。因此,透光抚育约40年后,其对红松的胸径生长的促进作用减弱而对树高的促进作用却增强,而且高径比提高,故此时为缓解林木竞争,对轻度透光抚育、中度透光抚育的林分应进行二次透光抚育以进一步促进红松生长,而对全透光和强度透光抚育林分应进行间伐。

关键词: 哑变量模型, 透光抚育强度, “栽针保阔”红松林, 林木分级, 生长规律

Abstract: “Planting conifer and reserving broadleaved tree” is an effective way to restore broad-leaved pine forest of temperate zone in Northeast China. Liberation cutting can promote the growth of Korean pine (Pinus koraiensis) under forest crown and accelerate the succession. However, how liberation cutting intensity affects the growth of Korean pine in secondary forest is still unclear. Taking the “Planting conifer and reserving broadleaved tree” Korean pine forest in Changbai Mountain as the object, we constructed a growth model of diameter at breast height (DBH) and tree height of Korean pine with double dummy variables (liberation cutting intensity and tree classification) to predict the growth of Korean pine plantation under different liberation cutting intensities, i.e. control (no liberation cutting), light-intensity liberation cutting (retaining upper canopy closure 0.6), medium-intensity liberation cutting (0.4), heavy-intensity liberation cutting (0.2) and clear cutting (cutting all upper broadleaf trees) stands. We analyzed the effects of liberation cutting intensities on DBH, tree height, and the ratio of tree height to DBH. The results showed that among six theoretical growth equations, the Gompertz model on the DBH (R²=0.46) and tree height (R²=0.81) was optimal basic model. The R² of the DBH model was increased to 0.65 and 0.89, respectively, after the single dummy variable and the double dummy variable were introduced into the basic model, while the R² of the tree height model was increased to 0.84 and 0.94. Therefore, the double dummy variable model was the most suitable for predicting the growth of Korean pine. The growth of DBH of pressed tree increased with the increases of liberation cutting intensity (increase by 145.8%-933.3%) during the whole simulation period (0-80 a). Average and dominant trees showed the same pattern at 42 and 60 a. In the early and middle stages of liberation cutting (20 and 42 a), clear cutting and heavy-intensity liberation cutting had similar effects on the height growth of dominant trees (64.8%-68.5%), average trees (100.0%-144.2%), and pressed trees (138.5%-183.9%). The effects of medium-intensity liberation cutting and light-intensity liberation cutting on the height growth were similar (24.3%-35.1%, 56.0%-92.3%, 84.6%-103.2%). While in the middle and late period (42 and 80 a), height growth of three grade trees increased with the increases of liberation cutting intensity. Under each liberation cutting intensity, the ratio of height to DBH of the dominant, average, and pressed trees increased successively, ranging from 0.50-0.95, 0.64-1.23, and 0.73-4.33, respectively. Only the pressed tree decreased with the increases of liberation cutting intensity at 0-80 a. Therefore, about 40 years after the implementation of liberation cutting, the promoting effect of different liberation cutting intensities on DBH growth was significantly weakened, the promoting effect on tree height growth was significantly enhanced, and the ratio of tree height to diameter began to increase. In order to alleviate forest competition, second liberation cutting should be carried out for light-intensity liberation cutting and medium-intensity liberation cutting stands to further release the growth potential of Korean pine, and thinning management should be carried out in clear cutting and heavy-intensity liberation cutting stands.

Key words: dummy variable model, liberation cutting intensity, Korean pine forest by planting conifer and reserving broadleaved tree, tree classification, growth law

郝鑫海, 牟长城, 崔雅如, 姬文慧, 许文, 赵海明. 基于双哑变量模型预测透光抚育强度对次生林内红松生长的影响[J]. 应用生态学报, 2024, 35(6): 1463-1473.

HAO Xinhai, MU Changcheng, CUI Yaru, JI Wenhui, XU Wen, ZHAO Haiming. Prediction of liberation cutting intensity effect on the growth of Korean pine in secondary forest based on double dummy variable model[J]. Chinese Journal of Applied Ecology, 2024, 35(6): 1463-1473.

参考文献

[1] 吴征镒. 中国植被. 北京: 科学出版社, 1980
[2] 郝占庆, 陶大立, 赵士洞. 长白山北坡阔叶红松林及其次生白桦林高等植物物种多样性比. 应用生态学报, 1994, 5(1): 16-23
[3] 王晓峰, 勒斯木初, 张明明.“两屏三带”生态系统格局变化及其影响因素.生态学杂志, 2019, 38(7): 2138-2148
[4] 郝珉辉, 代莹, 岳庆敏, 等. 阔叶红松林功能多样性与森林碳汇功能关系. 北京林业大学学报, 2022, 44(10): 68-76
[5] Luo W, Kim HS, Zhao X, et al. New forest biomass carbon stock estimates in Northeast Asia based on multisource data. Global Change Biology, 2020, 26: 7045-7066
[6] 丁壮. 东北林业大学帽儿山实验林场原始红松林的破坏与恢复的雏议. 植物研究, 2013, 33(3): 379-384
[7] 陈大珂, 周晓峰, 丁宝永, 等. 黑龙江省天然次生林研究.Ⅰ. 栽针保阔的经营途径. 东北林学院学报, 1984, 12(4): 1-12
[8] 中华人民共和国国家质量监督检验检疫总局, 中国国家标准化管理委员会. 森林抚育规程(GB/T—15781)[EB/OL]. (2015-11-02) [2023-11-08]. http://www.doc88.com/p-3415948116826.html
[9] 黄伟程, 高露双, 赵冰倩. 不同间伐强度下竞争对东北阔叶红松林主要树种生长-气候关系的影响. 北京林业大学学报, 2023, 45(1): 30-39
[10] Gavinet J, Vilagrosa A, Chirino E, et al. Hardwood seedling establishment below Aleppo pine depends on thinning intensity in two Mediterranean sites. Annals of Forest Science, 2015, 72: 999-1008
[11] Navarro-Cerrillo RM, Sánchez-salguero R, Rodriguez C, et al. Is thinning an alternative when trees could die in response to drought? The case of planted Pinus nigra and P. sylvestris stands in southern Spain. Forest and Ecology Management, 2019, 433: 313-324
[12] Juodvalkis A, Kairiukstis L, Vasiliauskas R. Effects of thinning on growth of six tree species in north-temperate forests of Lithuania. European Journal of Forest Research, 2005, 124: 187-192
[13] Ulvcrona KA, Karlsson K, Ulvcrona T. Identifying the biological effects of pre-commercial thinning on diameter growth in young Scots pine stands. Scandinavian Journal of Forest Research, 2014, 29: 427-435
[14] Ferraz Filho AC, Mola-yudego B, Gonzalez-olabarria JR, et al. Thinning regimes and initial spacing for Eucalyptus plantations in Brazil. Anais da Academia Brasileira de Ciências, 2018, 90: 255-265
[15] Missanjo E, Kamanga-Thole G. Effect of first thinning and pruning on the individual growth of Pinus patula tree species. Journal of Forestry Research, 2015,26: 827-831
[16] Ginn SE, Seiler JR, Cazell BH, et al. Physiological and growth responses of eight-year-old loblolly pine stands to thinning. Forest Science, 1991, 37: 1030-1040
[17] Harrington CA, Reukema DL. Initial shock and long-term stand development following thinning in a Douglas-fir plantation. Forest Science, 1983, 29: 33-46
[18] Fedorová B, Kadavý J, Adamec Z, et al. Response of diameter and height increment to thinning in oak-hornbeam coppice in the southeastern part of the Czech Republic. Journal of Forest Science, 2016, 62: 229-235
[19] Swift DE, Knight W, Béland M, et al. Stand dynamics and tree quality response to precommercial thinning in a northern hardwood forest of the Acadian forest region: 23 years of intermediate results. Scandinavian Journal of Forest Research, 2017, 32: 45-59
[20] Deng C, Zhang S, Lu Y, et al. Thinning effects on the tree height-diameter allometry of Masson pine (Pinus massoniana Lamb). Forests, 2019, 10: 1129
[21] 韩阳瑞, 牟长城, 张晓亮. 透光抚育对“栽针保阔”红松林中红松生长过程的影响. 安徽农业科学, 2014, 42(8): 2365-2364
[22] 任瑞娟, 亢新刚, 杨华. 天然林单木生长模型研究进展. 西北林学院学报, 2008, 23(6): 203-206
[23] Burkhart HE. Suggestion for choosing an appropriate level for modelling forest stands// Reed D, Soares P, eds. Modelling Forest Systems. Wallingford: CAB International, 2003: 3-10
[24] 卢军. 长白山地区天然混交林单木生长模型的研究. 硕士论文. 哈尔滨: 东北林业大学, 2005
[25] 曹梦, 潘萍, 欧阳勋志, 等. 基于哑变量的闽楠天然次生林单木胸径和树高生长模型研究. 北京林业大学学报, 2019, 41(5): 88-96
[26] 张剑坛, 李艳朋, 张入匀, 等. 基于枝条木材密度分级的鼎湖山南亚热带常绿阔叶林树高曲线模型. 生物多样性, 2021, 29(4): 456-466
[27] Wang M, Zhao Y, Zhen Z, et al. Individual-tree diameter growth model for Korean pine plantations based on optimized interpolation of meteorological variables. Journal of Forestry Research, 2021, 32: 1535-1552
[28] 李武赫, 董利虎, 李凤日. 凉水自然保护区阔叶红松林冠下4个主要树种更新幼树树高生长模型. 东北林业大学学报, 2021, 49(3): 1-8
[29] 盖军鹏, 陈东升, 贾炜玮, 等. 基于种源和气候效应的日本落叶松树高生长模型研究. 南京林业大学学报: 自然科学版, 2023, 47(4): 51-60
[30] 玉宝, 乌吉斯古楞, 王百田, 等. 大兴安岭兴安落叶松(Larix gmelinii)天然林分级木转换特征. 生态学报, 2008, 28(11): 5750-5757
[31] 颜佳睿, 李际平, 曹小玉, 等. 基于哑变量的闽楠人工林单木树高曲线模型. 中南林业科技大学学报, 2020, 40(11): 47-54
[32] 胡焕香, 佘济云, 李俊, 等. 湖北桂花林场檫木次生林单木生长模型的研究. 中南林业科技大学学报, 2013, 33(4): 61-65
[33] 胡有全, 沈永刚, 肖明增, 等. 我国常见针阔树种干重热值的对比分析. 林业勘查设计, 2015(2): 45-47
[34] 臧润国, 徐化成, 高文韬. 红松阔叶林主要树种对林隙大小及其发育阶段更新反应规律的研究. 林业科学, 1999, 35(3): 4-11
[35] Li X, Wang Y, Yang Z, et al. Photosynthesis adaption in Korean pine to gap size and position within Populus davidiana forests in Xiaoxing’anling, China. Journal of Forestry Research, 2022, 33: 1517-1527
[36] 侯向阳, 韩进轩, 阳含熙. 长白山红松阔叶林林冠木竞争生长及林冠空隙动态研究. 生态学报, 2000, 20(1): 69-73
[37] Allen HR, Marquis AD. Effect of thinning on height and diameter growth of oak & yellow-poplar saplings. Research Papers Northeastern Forest Experiment Station, 1970: NE-173
[38] Vizcaíno-palomar N, Ibáñez I, Gonzlez-martínez SC, et al. Adaptation and plasticity in aboveground allometry variation of four pine species along environmental gradients. Ecology and Evolution, 2016, 6: 7561-7573
[39] Lu D, Zhu J, Zhang G, et al. Disentangling regeneration by vertical stratification: A 17-year gap-filling process in a temperate secondary forest. Forest and Ecology Management, 2023, 539: 120994
[40] 王亚辉, 牟长城, 杨智慧, 等. 透光抚育强度对小兴安岭“栽针保阔”红松林碳储量的影响. 北京林业大学学报, 2021, 43(10): 54-64