不同产区杉木人工林初植密度对优势高生长的影响

doi:10.11707/j.1001-7488.LYKX20210836

摘要/Abstract

摘要：

目的: 探讨初植密度对不同产区杉木人工林优势高生长全过程的影响规律和发生程度，揭示杉木人工林优势高生长的初植密度效应及其对立地质量指示性的有效范围，为杉木人工林优势高生长评价及密度有效调控提供科学依据。方法: 以杉木中带东区（江西分宜）和中带中区（四川纳溪）共30块长期定位观测的杉木密度试验林样地（林龄范围为2~30年生）为研究对象，分析杉木人工林在不同产区和不同林分生长发育阶段下优势高对初植密度的响应规律。结果: 林分优势高与初植密度呈负相关关系，即初植密度越小，优势高越大。在林分生长发育前期，不同初植密度林分优势高生长轨迹几乎重合，初植密度影响较小，随林龄增长，不同初植密度间林分优势高生长差异呈增大趋势，至成熟龄期，林分优势高受初植密度的影响因产区而异，在中带东区影响仍很明显，在中带中区影响逐渐减弱。优势高年均生长量和连年生长量与初植密度呈负相关关系，且初植密度越大，其峰值越小，峰值出现时间越早。同一林龄下，与中带中区相比，立地条件整体更优的中带东区林分优势高生长受初植密度作用产生的分化程度相对更大。中带东区试点在5年生以后，中带中区试点在10~19年生期间，在低、中初植密度范围（1 667~3 333株·hm^?2）或高初植密度范围（6 667~10 000株·hm^?2）内，林分优势高生长不受初植密度显著影响，当初植密度达到或超过5 000株·hm^?2后，其与相对低的初植密度（1 667~3 333株·hm^?2）林分相比，林分优势高生长则受初植密度的显著制约。结论: 初植密度不同，林分优势高生长过程明显不同。在一定初植密度级差范围内，初植密度对林分优势高生长没有显著影响，超过一定级差时则高、低初植密度间林分优势高生长具有显著差异。标准年龄20年生时，中带东区试点差异显著的密度组合中，优势高差值最大达2.46 m，超过一个立地指数级，此时用优势高指示立地质量缺乏一定准确性。预估立地指数时，对初植密度高于5 000株·hm^?2的林分需要修正密度的影响。

关键词: 杉木, 优势高, 初植密度, 年均生长量, 连年生长量

Abstract:

Objective: To determine the effect of initial planting density on the dominant height growth of Chinese fir plantations and its effective range for indicating site quality, as well as to provide a scientific basis for the evaluation of dominant height growth and effective density regulation of Chinese fir plantations, the impact of initial planting density on the entire growth process of dominant height of Chinese fir plantations in various production areas was explored. Method: The eastern region in the middle subtropics (Fenyi, Jiangxi) and the central region in the middle subtropics of Chinese fir (Naxi, Sichuan) were used as the research objects to analyze the response dynamics of dominant height to initial planting density of Chinese fir plantations in different production areas and different stand growth stages. A total of 30 long-term positioning observation plots of Chinese fir density test forests (ranging from 2 to 30 years old) were used. Result: Dominant height was negatively correlated with the initial planting density, the lower the initial planting density was, the higher the dominant height became. In the early stage of stand, the growth trajectory of dominant height with different initial planting densities almost overlapped, and the difference among the densities was small. With the increase of stand age, the difference of dominant height growth among initial planting densities increased. At the mature stage, the effects of initial planting densities on dominant height varied with distribution areas, which was still obvious in eastern region in the middle subtropics, but gradually weakened in central region in the middle subtropics. The mean annual increment and current annual increment of dominant height were negatively correlated with the initial planting density, and the higher the initial planting density was, the smaller the peak reached and the earlier the peak appeared. Under the same stand age, compared with the central region in the middle subtropics, the eastern region in the middle subtropics with the overall better site condition had a higher differentiation degree of dominant height by the effect of initial planting density. Initial planting density had no significant effect on the dominant height growth in the range of low and middle initial planting densities (1 667–3 333 trees·hm^?2) or high initial planting densities (6 667–10 000 trees·hm^?2) after 5 years in eastern region in the middle subtropics and during 10–19 years in central region in the middle subtropics. When the initial planting density reached or exceeded 5 000 trees·hm^?2, the initial planting density had a significant restriction effect on the dominant height growth, compared with the relatively low initial planting densities (1 667–3 333 trees·hm^?2). Conclusion: With various initial planting densities, the growth process of dominant height in stands varies dramatically. The initial planting density has no significant impact on the dominant height growth of the forest within a specific range of initial planting density variations. When the initial planting density exceeds a certain range, there is a significant difference between high density and low density. At the standard age of 20 years, the maximum difference value of dominant height is 2.46 m among the density combinations with significant differences in eastern region in the middle subtropics, which exceeds one site index class. At this time, it is not accurate to use dominant height to indicate site quality. The influence of density should be corrected for the site index prediction of the stand with initial planting density higher than 5 000 trees·hm^?2.

Key words: Chinese fir, dominant height, initial planting density, mean annual increment, current annual increment

中图分类号:

S750

李晓燕,段爱国,张建国. 不同产区杉木人工林初植密度对优势高生长的影响[J]. 林业科学, 2023, 59(8): 22-29.

Xiaoyan Li,Aiguo Duan,Jianguo Zhang. Effects of Initial Planting Density on Dominant Height Growth of Chinese Fir (Cunninghamia lanceolata) Plantation in Different Distribution Areas[J]. Scientia Silvae Sinicae, 2023, 59(8): 22-29.

图/表 6

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参考文献 0

	谌红辉, 方升佐, 丁贵杰, 等. 马尾松间伐的密度效应. 林业科学, 2010, 46 (5): 84- 91.
	Chen H H, Fang S Z, Ding G J, et al. Thinning density effects on Masson pine plantation. Scientia Silvae Sinicae, 2010, 46 (5): 84- 91.
	段爱国, 张建国. 杉木人工林优势高生长模拟及多形地位指数方程. 林业科学, 2004, 40 (6): 13- 19. doi: 10.11707/j.1001-7488.20040603
	Duan A G, Zhang J G. Modeling of dominant height growth and building of polymorphic site index equations of Chinese fir plantation. Scientia Silvae Sinicae, 2004, 40 (6): 13- 19. doi: 10.11707/j.1001-7488.20040603
	洪玲霞. 初植密度、间伐对杉木林分优势高生长过程的影响. 林业科学研究, 1997, 10 (4): 448- 452.
	Hong L X. Effect of planting density and thinning on dominant height growth curve in Chinese fir plantation. Rorest Research, 1997, 10 (4): 448- 452.
	李春明, 张会儒. 利用非线性混合模型模拟杉木林优势木平均高. 林业科学, 2010, 46 (3): 89- 95.
	Li C M, Zhang H R. Modeling dominant height for Chinese fir plantation using a nonlinear mixed-effects modeling approach. Scientia Silvae Sinicae, 2010, 46 (3): 89- 95.
	林开敏, 俞新妥, 邱尔发, 等. 杉木造林密度生长效应规律的研究. 福建林学院学报, 1996, 16 (1): 53- 56.
	Lin K M, Yu X T, Qiu E F, et al. Effects of densities on growth of Chinese fir plantation. Journal of Fujian College of Forestry, 1996, 16 (1): 53- 56.
	唐继新, 贾宏炎, 王　科, 等. 密度调控对米老排中龄人工林生长的影响. 南京林业大学学报(自然科学版), 2019, 43 (1): 45- 53.
	Tang J X, Jia H Y, Wang K, et al. Effect of density regulation on growth of Mytilaria laosensis plantation with middle age . Journal of Nanjing Forestry University (Natural Sciences Edition), 2019, 43 (1): 45- 53.
	童书振, 刘景芳. 2019. 杉木林经营数表与优化密度控制. 北京: 中国林业出版社, 1−2.
	Tong S Z, Liu J F. 2019. Study on management statistics and tables and optimal density control of Cunninghamia lanceolata forest. Beijing: China Forestry Publishing House, 1−2.［in Chinese］
	童书振, 盛炜彤, 张建国. 杉木林分密度效应研究. 林业科学研究, 2002, 15 (1): 66- 75.
	Tong S Z, Sheng W T, Zhang J G. Studies on the density effects of Chinese fir stands. Forest Research, 2002, 15 (1): 66- 75.
	余克胜, 张时林, 鄢武先, 等. 密度调控对杉木人工林中优势木生长过程的影响. 四川林业科技, 2019, 40 (6): 43- 47,64.
	Yu K S, Zhang S L, Yan W X, et al. Effects of density control on the growth process of dominant trees of Cunninghamia lanceolata plantation . Journal of Sichuan Forestry Science and Technology, 2019, 40 (6): 43- 47,64.
	相聪伟, 张建国, 段爱国, 等. 杉木人工林材种结构的立地及密度效应研究. 林业科学研究, 2015, 28 (5): 654- 659.
	Xiang C W, Zhang J G, Duan A G, et al. Effects of site quality and planting density on wood assortment rate in Chinese fir plantation. Forest Research, 2015, 28 (5): 654- 659.
	Antón-Fernández C, Burkhart H E, Strub M, et al. Effects of initial spacing on height development of loblolly pine. Forest Science, 2011, 57 (3): 201- 211.
	Cieszewski C J, Bella I E. Modeling density-related lodgepole pine height growth, using Czarnowski’s stand dynamics theory. Canadian Journal of Forest Research, 1993, 23 (12): 2499- 2506. doi: 10.1139/x93-311
	Harrington T B, Harrington C A, DeBell D S. Effects of planting spacing and site quality on 25-year growth and mortality relationships of Douglas-fir (Pseudotsuga menziesii var. menziesii) . Forest Ecology and Management, 2009, 258 (1): 18- 25. doi: 10.1016/j.foreco.2009.03.039
	Knowe S A, Hibbs D E. Stand structure and dynamics of young red alder as affected by planting density. Forest Ecology and Management, 1996, 82 (1/2/3): 69- 85.
	Lee D, Beuker E, Viherä-Aarnio A, et al. Site index models with density effect for hybrid aspen (Populus tremula L. ×P. tremuloides Michx. ) plantations in southern Finland . Forest Ecology and Management, 2021, 480, 118669. doi: 10.1016/j.foreco.2020.118669
	Lockhart B R. Site index determination techniques for southern bottomland hardwoods. Southern Journal of Applied Forestry, 2013, 37 (1): 5- 12. doi: 10.5849/sjaf.09-027
	MacFarlane D W, Green E J, Burkhart H E. Population density influences assessment and application of site index. Canadian Journal of Forest Research, 2000, 30 (9): 1472- 1475. doi: 10.1139/x00-079
	Meredieu C, Perret S, Dreyfus P. 2002. Modelling dominant height growth: effect of stand density// Amaro A, Reed D, Soares P. Modelling forest systems. Workshop on the interface between reality, modelling and the parameter estimation processes. Portugal: Sesimbra, 111-121.
	Ochal W, Socha J, Pierzchalski M. The effect of the calculation method, plot size, and stand density on the accuracy of top height estimation in Norway spruce stands. iForest - Biogeosciences and Forestry, 2017, 10 (2): 498- 505. doi: 10.3832/ifor2108-010
	Pienaar L V, Shiver B D. The effect of planting density on dominant height in unthinned slash pine plantations. Forest Science, 1984, 30 (4): 1059- 1066.
	Ritchie M, Zhang J W, Hamilton T. Effects of stand density on top height estimation for ponderosa pine. Western Journal of Applied Forestry, 2012, 27 (1): 18- 24. doi: 10.1093/wjaf/27.1.18
	Scolforo J R S, Maestri R, Ferraz Filho A C, et al. Dominant height model for site classification of Eucalyptus grandis incorporating climatic variables . International Journal of Forestry Research, 2013, 2013, 1- 7.
	Sharma M, Burkhart H E, Amateis R L. Modeling the effect of density on the growth of loblolly pine trees. Southern Journal of Applied Forestry, 2002a, 26 (3): 124- 133. doi: 10.1093/sjaf/26.3.124
	Sharma M, Amateis R L, Burkhart H E. Top height definition and its effect on site index determination in thinned and unthinned loblolly pine plantations. Forest Ecology and Management, 2002b, 168 (1/2/3): 163- 175.
	Staebler G R. Use of dominant tree heights in determining site index for Douglas-fir. PNW Old Series Research Notes, 1948, 44, 1- 3.
	Tarmu T, Laarmann D, Kiviste A. 2020. Mean height or dominant height - what to prefer for modelling the site index of Estonian forests? Forestry Studies, 72(1): 121−138.
	Weiskittel A R, Hann D W, Hibbs D E, et al. Modeling top height growth of red alder plantations. Forest Ecology and Management, 2009, 258 (3): 323- 331. doi: 10.1016/j.foreco.2009.04.029
	Zhao D H, Kane M, Borders B E. Growth responses to planting density and management intensity in loblolly pine plantations in the southeastern USA Lower Coastal Plain. Annals of Forest Science, 2011, 68 (3): 625- 635. doi: 10.1007/s13595-011-0045-7
	Zhou M L, Lei X D, Duan G S, et al. The effect of the calculation method, plot size, and stand density on the top height estimation in natural spruce-fir-broadleaf mixed forests. Forest Ecology and Management, 2019, 453, 117574. doi: 10.1016/j.foreco.2019.117574

产区 Distribution area	试验地 Experimental field	经度 Longitude (E)	纬度 Latitude (N)	海拔 Elevation/ m	年均气温 Mean annual temperature /℃	年均降水量 Mean annual precipitation /mm	地貌 Topography	母岩 Parent rock	土壤 Soil
中带东区 Eastern region in middle subtropics	江西分宜 Fengyi, Jiangxi	114°33′	27°34′	250	16.8	1 656	低山 Low mountain	砂页岩 Sandy shale	黄棕壤 Yellow brown soil
中带中区 Central region in middle subtropics	四川纳溪 Naxi, Sichuan	105°23′	28°47′	440	17.5	1 182	高丘 High hill	页岩 Shale	红壤 Red soil

产区 Distribution area	试验地 Experimental field	初植密度 Initial planting density	造林时间 Afforestation time	苗龄 Seedling age/a	调查次数 Number of investigation	林龄 Stand age/a	同一初植密度3块重复样地的立地指数Site index of three repeated plots with the same initial planting density/m
中带东区 Eastern region in middle subtropics	江西分宜 Fengyi, Jiangxi	A	1981年春 Spring in 1981	1	18	2~28	15.77~17.40
		B					15.15~16.20
		C					14.88~15.50
		D					14.05~14.27
		E					13.38~15.62
中带中区 Central region in middle subtropics	四川纳溪 Naxi, Sichuan	A	1982年春 Spring in 1982	1	18	3~30	15.00~16.21
		B					13.84~15.30
		C					13.02~14.96
		D					13.85~15.57
		E					13.25~14.96

林龄 Stand age/a	江西 Jiangxi		四川 Sichuan
林龄 Stand age/a	P	差异显著密度组合Density combinations with significant differences	P	差异显著密度组合Density combinations with significant differences
2	0.175	N
3	0.291	N	0.665	N
4	0.527	N	0.483	N
5	0.057	A-D	0.716	N
6	0.001**	A-D、B-D、 A-E、C-D	0.535	N
7	0.012*	A-D	0.284	N
8	0.006**	A-D、A-E、B-D	0.049*	A-E
9	0.012*	A-D、B-D	0.288	N
10	0.007**	A-D、B-D	0.030*	A-E
11
12	0.010**	A-D
13			0.049*	A-E
14	0.015*	A-D	0.060	A-E
15			0.070	A-E
16	0.007**	A-D、A-E
17			0.084	A-E
18	0.002**	A-C、A-D、A-E、 B-D、B-E
19			0.093	A-E
20	0.013*	A-D、A-E
22	0.035*	A-D	0.280	N
24	0.029*	A-D	0.318	N
26	0.021*	A-D、A-E	0.447	N
28	0.063	A-D	0.777	N
30			0.812	N
36

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