不同林龄柚木人工林心边材生长变异特征

doi:10.11707/j.1001-7488.20200107

摘要/Abstract

摘要：

目的: 探明广西大青山林区不同林龄柚木人工林心、边材量及心材年轮数和心材高度的生长变异特征，以期为了解该区域柚木心边材发育特征、心边材量预测及高质量、大径级柚木目标树的高效培育提供基础数据和科学依据。方法: 以广西大青山10、18、31和41年生柚木人工林平均木的解析木为研究对象，对心、边材的方位变异和心、边材量的株间差异进行方差分析，并采用曲线估计法拟合心、边材量与横截面直径、总年轮数之间的回归模型，研究柚木心、边材生长变异特征。结果: 各林龄柚木树干心材半径主要为北向最大，边材宽度则主要为北向和东向最大，各林龄内，树干4个方位的心材半径、边材宽度均无显著差异（P>0.05）。各林龄柚木心材半径、心材面积和边材面积均表现为随树高增加持续减小，边材宽度在树干基部（0~1 m）明显偏大，且在树干一定区域内保持相对稳定。林分心、边材量总体表现为随林龄增加而增大，不同林龄林分间除边材宽度差异不显著外（P>0.05），心材半径、心材面积和边材面积均存在极显著差异（P < 0.01）。横截面心、边材量随横截面直径和总年轮数的增加而增加，其中与横截面直径的相关性高于总年轮数，而总年轮数对心材发育早期影响较大。各林龄内，柚木个体的心边材量、心材消失最大高度存在较大的株间变异，其中，心材面积和边材面积的变异程度相近，心材半径、边材宽度和心材消失最大高度的变异程度相近。柚木最早在4年生时开始有心材形成，不同林龄的心材年轮数均表现为随总年轮数增加而增加，总年轮数可解释心材年轮数80%以上的变化，10、18、31和41年生柚木心材年轮数年均增长速率分别为0.9轮、0.7轮、1.0轮和1.0轮。柚木心材消失最大高度、心材消失的相对高度均与林龄呈正相关关系，即随着林龄的增大，心材在树干更高处消失。结论: 柚木心材形成初始年龄最早为4年生，属心材形成较早的树种。各林龄内，方位对柚木心、边材影响较小。柚木的心材半径、心材面积、边材面积和心材消失最大高度，均表现随林龄增加而显著增加，而边材宽度无显著变化。柚木横截面直径可以更好地解释横截面心、边材量的变化，总年轮数仅能解释柚木前期（< 31年生）心材量的变化。研究认为41年生柚木心材仍有很大增长潜力，若要达到高质量、大径级的培育目标，还需要更长时间的培育。

关键词: 柚木, 林龄, 生长特征, 心材, 边材

Abstract:

Objective: The growth and variation characteristics of heartwood and sapwood,ring number of heartwood,and height of heartwood in different-aged teak (Tectona grandis) plantations in Daqing mountain of Guangxi were investigated,so as to provide scientific basis and basic data for understanding the developmental characteristics of heartwood,predicting heartwood quantity and efficiently cultivating high-quality and large-diameter teak target trees in this region. Method: Average trees from 10,18,31 and 41-year-old teak plantations in Daqing mountain of Guangxi province were selected to analyze variation of heartwood and sapwood among orientations and among individual trees using variance analysis,and the regression model between amount of heartwood and sapwood,cross-sectional diameter,and total number of annual rings were fitted by curve estimation method to study the growth variation of teak heartwood and sapwood. Result: The heartwood radius of teak trees was the largest in the north direction,while the sapwood width was the largest in the north and the east directions,and there were no significant differences in the heartwood radius and sapwood width among four stem orientations at the same age (P>0.05). The heartwood radius,heartwood area and sapwood area decreased with tree height regardless of ages. The sapwood width was relatively larger at the base of the trunk (0-1 m) and remained constant in a certain area. With the increase of forest age,the amounts of sapwood and heartwood increased in the four forests,and there was no significant difference in sapwood width (P>0.05),however there were significant differences in heartwood radius,heartwood area and sapwood area among forest ages (P < 0.01). The cross-sectional heartwood and sapwood increased with the increase of the cross-sectional diameter and the total number of annual rings,among which the influence of stem cross-sectional diameter was higher than that of the total number of rings,and the total number of annual rings had a great influence on the early development of heartwood. There was relatively large tree-to-tree difference in the amounts of sapwood and heartwood,as well as the maximum heartwood height of teak trees for the same forest age,in which the degree of variation in the areas of heartwood and sapwood was similar,and the degree of variation in the heartwood radius,the sapwood width,and the disappeared maximum height of the heartwood were also similar to each other. Teak began to form heartwood at the age of four years. The number of heartwood rings of different ages increased with the increase of the total number of annual rings. The total number of annual rings accounted for more than 80% of the variation in the number of heartwood rings. The annual growth rates of 10-,18-,31-and 41-year-old teak trees were 0.9 ring,0.7 ring,1.0 ring,and 1.0 ring,respectively. The maximum height and relative height of heartwood were positively correlated with forest age,with the increase of forest age,the heartwood disappeared at a higher position of the trunk. Conclusion: The initial age of heartwood formation of teak trees was 4 years,which was a tree species with early heartwood formation. Within each forest age,the orientation had little effect on the heartwood and sapwood of teak trees. The heartwood radius,heartwood area,sapwood area and maximum heartwood height increased significantly with the age of teak trees,while the heartwood width did not change significantly. The cross-sectional diameter could better explain the variation in the amounts of sapwood and heartwood,and the total number of rings only explain the variation in the amount of heartwood prior to 31-year-old teak trees. According to the study,41-year-old teak heartwood still has great growth potential,and longer cultivation is needed to reach the goal of high-quality and larger-diameter teak trees.

Key words: Tectona grandis, forest age, growth, heartwood, sapwood

中图分类号:

S758.5⁺2

杨保国, 贾宏炎, 郝建, 李运兴, 庞圣江, 刘士玲, 张培, 牛长海, 蔡道雄. 不同林龄柚木人工林心边材生长变异特征[J]. 林业科学, 2020, 56(1): 65-73.

Baoguo Yang, Hongyan Jia, Jian Hao, Yunxing Li, Shengjiang Pang, Shiling Liu, Pei Zhang, Changhai Niu, Daoxiong Cai. Growth Variation of Heartwood and Sapwood of Teak (Tectona grandis) Plantations at Different Ages[J]. Scientia Silvae Sinicae, 2020, 56(1): 65-73.

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参考文献 0

	艾娟娟, 厚凌宇, 邵国栋, 等. 林业废弃物基质配方特性及其对柚木生长的影响. 浙江农林大学学报, 2018. 35 (6): 1027- 1037.
	Ai J J , Hou L Y , Shao G D , et al. Matrix formula with forest waste and their effects on Tectona grandis growth. Journal of Zhejiang A&F University, 2018. 35 (6): 1027- 1037.
	白灵海, 莫慧华, 梁坤南, 等. 柚木组培瓶苗移植育苗基质筛选试验与分析. 种子, 2013. 32 (9): 10- 12.
	Bai L H , Mo H H , Liang K N , et al. Selection experiment and analysis of nursery substrate in transplanting the tissue culture seedlings of Tectona grandis. Seed, 2013. 32 (9): 10- 12.
	常建国, 李新平, 刘世荣, 等. 油松心边材量及年轮数的变异特征. 林业科学, 2009. 45 (11): 76- 82.
	Chang J G , Li X P , Liu S R , et al. Variations in amount and ring number of sapwood and heartwood of Pinus tabulaeformis. Scientia Silvae Sinicae, 2009. 45 (11): 76- 82.
	杜健, 梁坤南, 周树平, 等. 不同地区柚木人工林生长及土壤理化性质的研究. 林业科学研究, 2016a. 29 (6): 854- 860.
	Du J , Liang K N , Zhou S P , et al. Research on the growth of teak (Tectona grandis) plantation and soil physicochemical properties in different regions. Forest Research, 2016a. 29 (6): 854- 860.
	杜健, 梁坤南, 周再知, 等. 云南西双版纳柚木人工林立地类型划分及评价. 林业科学, 2016b. 52 (9): 1- 10.
	Du J , Liang K N , Zhou Z Z , et al. Site classification and evaluation of teak plantation in Xishuangbanna, Yunnan Province, China. Scientia Silvae Sinicae, 2016b. 52 (9): 1- 10.
	黄桂华, 梁坤南, 林明平, 等. 柚木种子园促花结实技术的初步研究. 种子, 2015. 34 (8): 98- 101.
	Huang G H , Liang K N , Lin M P , et al. Study of early flowering and fruiting technology of teak (Tectona grandis) seed orchards. Seed, 2015. 34 (8): 98- 101.
	黄桂华, 梁坤南, 周再知, 等. 柚木无性系生长性状的遗传变异与选择效应. 华南农业大学学报, 2019. 40 (1): 1- 6.
	Huang G H , Liang K N , Zhou Z Z , et al. Genetic variation and selective effect of growth traits of teak clones. Journal of South China Agricultural University, 2019. 40 (1): 1- 6.
	黄桂华, 梁坤南, 周再知, 等. 柚木无性系苗期抗旱生理评价与选择的研究. 中南林业科技大学学报, 2018. 38 (5): 11- 17.
	Huang G H , Liang K N , Zhou Z Z , et al. Drought stress physiological estimate and early selection of Tectona grandis clones at seedling stage. Journal of Central South University of Forestry & Technology, 2018. 38 (5): 11- 17.
	贾炜玮, 朱飞燕, 李凤日. 长白落叶松人工林心材变化规律. 应用生态学报, 2018. 29 (7): 2277- 2285.
	Jia W W , Zhu F Y , Li F R . Change pattern of heartwood of Larix olgensis plantation. Chinese Journal of Applied Ecology, 2018. 29 (7): 2277- 2285.
	刘家霖, 王传宽, 张全智. 不同分化等级兴安落叶松树干心材和边材的空间变异. 林业科学, 2014. 50 (12): 114- 121.
	Liu J L , Wang C K , Zhang Q Z . Spatial variations in stem heartwood and sapwood for Larix gmelinii trees with various differentiation classes. Scientia Silvae Sinicae, 2014. 50 (12): 114- 121.
	马华明, 梁坤南, 周再知. 我国柚木的研究与发展. 林业科学研究, 2003. 16 (6): 768- 773.
	Ma H M , Liang K N , Zhou Z Z . Research and development of teak in China. Forest Research, 2003. 16 (6): 768- 773.
	汪矛, 张志农. 边材与心材. 生物学通报, 1998. 33 (9): 13- 14.
	Wang M , Zhang Z N . Sapwood and heartwood. Bulletin of Biology, 1998. 33 (9): 13- 14.
	王兴昌, 王传宽, 张全智, 等. 东北主要树种心材与边材的生长特征. 林业科学, 2008. 44 (5): 102- 108.
	Wang X C , Wang C K , Zhang Q Z , et al. Growth characteristics of heartwood and sapwood of the major tree species in northeastern China. Scientia Silvae Sinicae, 2008. 44 (5): 102- 108.
	周树平, 梁坤南, 杜健, 等. 不同密度柚木人工林林下植被及土壤理化性质的研究. 植物研究, 2017. 37 (2): 200- 210.
	Zhou S P , Liang K N , Du J , et al. Research on understory vegetation and soil physical-chemical properties of teak plantation with different stand densities. Bulletin of Botanical Research, 2017. 37 (2): 200- 210.
	周再知. 2009.酸性土壤柚木钙素营养研究.北京:中国林业科学研究院博士学位论文.
	Zhou Z Z. 2009. Calcium nutrition of teak in acidic soils. Beijing: PhD thesis of Chinese Academy of Forestry.[in Chinese]
	Berthier S , Kokutse A D , Stokes A , et al. Irregular heartwood formation in maritime pine (Pinus pinaster Ait):consequences for biomechanical and hydraulic tree functioning. Annals of Botany, 2001. 87 (1): 19- 25.
	Bjorklund L . Identifying heartwood rich stands or stems of Pinus sylvestris by using inventory data. Silva Fennica, 1999. 33 (2): 119- 129.
	Climent J , Chambel E P , Pérez E , et al. Relationship between heartwood radius and early radial growth, tree age, and climate in Pinus canariensis. Canadian Journal of Forest Research, 2002. 32 (1): 103- 111.
	Fernández-Sólis D , Berrocal A , Moya R . Heartwood formation and prediction of heartwood parameters in Tectona grandis L. f. trees growing in forest plantations in Costa Rica. Bois et Forets des Tropiques, 2018. 335 (1): 25- 37.
	Gominho J , Figueira J , Rodríguez J C , et al. Within-tree variation of heartwood, extractives and wood density in the eucalypt hybrid urograndis (Eucalyptus grandis×E. urophylla). Wood and Fiber Science, 2001. 33 (1): 3- 8.
	Gominho J , Pereira H . Variability of heartwood content in plantation-grown Eucalyptus globulus Labill. Wood and Fiber Science, 2000. 32 (2): 189- 195.
	Knapic S , Oliveira V , Makkonen M , et al. Circumferential variation of heartwood and stem quality in maritime pine stems. Eur J Forest Res, 2014. 133 (6): 1007- 1014.
	Knapic S , Pereira H . Within-tree variation of heartwood and ring width in maritime pine (Pinus pinaster Ait). Forest Ecology and Management, 2005. 210 (1/3): 81- 89.
	Knapic S , Tavares F , Pereira H . Heartwood and sapwood variation in Acacia melanoxylon R. Br. trees in Portugal. Forestry, 2006. 79 (4): 371- 380.
	Longuetaud F , Mothe F , Leban J M , et al. Picea abies sapwood width:variations within and between trees. Scandinavian Journal of Forest Research, 2006. 21 (1): 41- 53.
	McDowell N , Barnard H , Bond B , et al. The relationship between tree height and leaf area:sapwood area ratio. Oecologia, 2002. 132 (1): 12- 20.
	Minn Y , Prinz K , Finkeldey R . Genetic variation of teak (Tectona grandis) in Myanmar revealed by microsatellites. Tree Genetics and Genomes, 2014. 10 (5): 1435- 1449.
	Morais M C , Pereira H . Heartwood and sapwood variation in Eucalyptus globulus Labill. trees at the end of rotation for pulp wood production. Annals of Forestry of Science, 2007. 64 (6): 665- 671.
	Ogle K , Pacala S W . A modeling framework for inferring tree growth and allocation from physiological, morphological and allometric traits. Tree Physiology, 2009. 29 (4): 587- 605.
	Pérez-Cordero L D , Kanninen M . Heartwood, sapwood and bark content and wood dry density of young and mature teak (Tectona grandis) trees grown in Costa Rica. Silva Fennica, 2003. 37 (1): 45- 54.
	Stokes A , Berthier S . Irregular heartwood formation in Pinus pinaster Ait. is related to eccentric, radial, stem growth. Forest Ecology and Management, 2000. 135 (3): 115- 121.
	Wang X Q , Jiang Z H , Ren H Q . Distribution of wet heartwood in stems of Populus xiaohei from a spacing trial. Scandinavian Journal of Forest Research, 2008. 23 (1): 38- 45.

样地 Plot	海拔 Altitude/m	坡度 Slope/(°)	坡位 Slope position	坡向 Slope aspect	造林年份 Planting year	调查年份 Survey year	林龄 Stand age/a	造林密度 Planting density/ (tree ·hm^-2)
QSHL1	150	5	下Down	东北Northeast	2008	2017	10	2 500
QSHL2	150	5	下Down	东北Northeast	2008	2017	10	2 500
QSHL3	150	5	下Down	东北Northeast	2008	2017	10	2 500
QSHL4	150	5	下Down	东北Northeast	2008	2017	10	2 500
QSPJ1	175	25	下Down	东East	1995	2012	18	2 500
QSPJ2	175	27	下Down	东East	1995	2012	18	2 500
BY1	232	30	下Down	东南Southeast	1982	2012	31	2 500
BY2	230	35	下Down	东南Southeast	1982	2012	31	2 500
BY3	350	40	下Down	西北Northwest	1982	2012	31	2 500
QS1	199	0	下Down	西北Northwest	1983	2013	31	2 500
QS3	153	16	下Down	北North	1983	2013	31	2 500
QS4	164	18	下Down	北North	1983	2013	31	2 500
SPXS1	199	11	下Down	东East	1973	2013	41	2 500
SPXS2	195	8	下Down	东北Northeast	1995	2012	18	2 500
SPXS3	190	10	下Down	东East	1973	2013	41	2 500

林龄 Stand age/a	样地数量 Plot number	样木数量 Sample tree number	胸径 DBH/cm	树高 Tree height/m	枝下高 Height to crown base/m	冠幅 Crown width/m
10	4	10	15.8±3.9	15.7±2.4	5.5±1.7	6.9±1.4
18	3	9	12.1±3.2	12.4±1.4	5.8±1.9	3.2±1.2
31	6	17	27.4±6.3	21.4±2.6	11.6±2.6	6.0±1.5
41	2	6	37.2±7.2	24.9±1.1	11.3±1.6	6.4±1.2

林龄 Stand age/a	变异系数Coefficient of variation (%)
林龄 Stand age/a	心材半径 Heartwood radius	心材面积 Heartwood area	边材宽度 Sapwood width	边材面积 Sapwood area	心材消失最大高度 Maximum height of heartwood disappearance
10	29.70	53.56	24.72	34.48	18.85
18	31.45	62.70	25.97	40.25	27.28
31	23.99	45.34	18.59	29.43	15.80
41	27.32	53.64	23.75	46.03	7.98

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