Effects of initial planting density on growth and stem form of four Larix clones

doi:10.12302/j.issn.1000-2006.202009018

JOURNAL OF NANJING FORESTRY UNIVERSITY ›› 2021, Vol. 45 ›› Issue (6): 72-80.doi: 10.12302/j.issn.1000-2006.202009018

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Effects of initial planting density on growth and stem form of four Larix clones

ZHENG Ying(), FENG Jian^*(), YU Shihe, LU Aijun, WANG Qin, WANG Qianchun

Liaoning Academy of Forestry Sciences, Shenyang 110032, China

Received:2020-09-07 Accepted:2020-12-01 Online:2021-11-30 Published:2021-12-02
Contact: FENG Jian E-mail:zhengying55555@126.com;lnlkyfj@163.com

Abstract

Abstract:

【Objective】 The objective of this study was to investigate the relationships between the growth and stem form of larch clones based on the initial planting density. This findings of the study would provide a scientific basis for the rational management of larch clone plantations and will be beneficial for promoting the application of larch superior clones. 【Method】 Studies were conducted in the Dagujia Forest Farm of Qingyuan, Liaoning. Experiment forests were established in the year 2006 with four excellent larch clones and three initial planting densities (A. 2.0 m × 3.0 m; B. 2.0 m × 2.0 m; C. 2.0 m × 1.5 m). The effects of genetic factors and densities on growth traits and stem form characteristics were analyzed based on the data on tree height, diameter at breast height (DBH), crown width, stem straightness and stem fullness measured over successive years. 【Result】 The DBH, crown width and individual volume of the four clones were significantly affected by the initial planting density and increased with the decreasing density. For 13-years-old clone plantations, the DBH, individual volume and crown width in the low-density forest (A) were 16.4%, 28.8% and 19.0% higher than those in the high-density forest (C). However, the stand volume and height-diameter ratio showed an opposite trend, and the stand volume decreased by 29.3%. Tree height, stem straightness, and stem fullness were less affected by the initial planting density. Growth properties were significantly influenced by genetic factors, and showed the same orders at different densities as follows: Clone 2 > Clone 1 > Clone 3 > Clone 4. In forest stands of density A, the DBH, crown width, individual volume increased and the stand volume of Clone 2 was 24.5%, 21.2%, 47.8% and 42.8% higher than those of Clone 4, respectively. Growth traits and stem form characteristics of clones were affected differentially by densities. The differentiation of DBH, individual volume and height-diameter ratio of clones increased with the increasing initial planting density, while the differences in tree height, stem straightness and stem fullness were marginal among clones, and Clone 2 was more stable in growth and stem shape variations. The four clones had different beginning periods of tending and thinning at the three densities. The initial thinning stages of Clones 1, 2, 3 and 4 were 7, 9, 11 and 11 a, respectively, under density A, 7, 9, 9 and 11 a, respectively, under density B, and 7 a under density C. 【Conclusion】 Both genetic factors and densities had significant effects on the tree growth and stem shape, but the interaction between genetic factors and densities was not significant. Growth traits were more susceptible to genetic factors and densities than stem shape, and the genetic effect was greater than the density effect in the early stage of tree growth. The beginning time of tending and intermediate cutting of the genetically modified stand was earlier; thus, the corresponding management measures should be implemented. Clone 1 and Clone 2 were of a rapid-type, while Clone 3 and Clone 4 were of the uniform type. To cultivate the large-diameter timber, artificial forest could be established by matching Clone 1 or Clone 2 with density A. To cultivate the pulp material, artificial forests could be established by matching Clone 2 or Clone 4 with density C or by matching Clone 3 with density B. Considering the growth traits and stem shape characteristics, Clone 2 could be widely used in the mountainous area of east Liaodong because of its fast growth and stability, and would obtain the largest stand stock. This study clarified the reasonable initial planting density of different larch genotypes and revealed the matching of superior varieties with suitable methods. It is critical to improve the directional cultivation technology of larch and improve the yield and quality of larch plantations in China.

Key words: Larix (larch) clone, superior clones, afforestation density, growth, stem form

CLC Number:

ZHENG Ying, FENG Jian, YU Shihe, LU Aijun, WANG Qin, WANG Qianchun. Effects of initial planting density on growth and stem form of four Larix clones[J]. JOURNAL OF NANJING FORESTRY UNIVERSITY, 2021, 45(6): 72-80.

Figures/Tables 4

Table 1

The growth situation of the 4 clones at different initial planting densities"

指标 index	无性系 clone	不同林龄无性系生长特征 growth situation of clones with different age
		5 a			7 a			9 a			11 a			13 a
		A	B	C	A	B	C	A	B	C	A	B	C	A	B	C
胸径 DBH	无性系1	2.88± 0.18 aB	2.87± 0.8 aA	3.23± 0.41aB	6.89± 0.42 aB	6.39± 1.20 aA	6.76± 0.45 aB	9.91± 0.53 aBC	9.06± 0.98 aB	8.99± 0.58 aB	12.27± 0.84 aBC	11.15± 1.09 aB	10.96± 0.91 aAB	14.2± 0.82 aBC	12.42± 0.89 aBC	12.09± 1.03 aA
	无性系2	2.83± 0.27 aB	2.55± 0.94 aA	3.31± 0.09 aB	7.11± 0.38 aB	6.38± 1.1 a7A	6.97± 0.26 aB	10.87± 0.75 aC	9.47± 0.92 aB	9.14± 0.29 aB	13.57± 1.12 bC	11.67± 0.73 aB	11.21± 0.55 aB	15.36± 1.13 bC	13.17± 0.45 aC	12.10± 0.73 aA
	无性系3	2.44± 0.46 aAB	2.05± 0.46 aA	2.78± 0.20 aB	6.00± 0.61 aAB	5.30± 0.60 aA	5.82± 0.21 aA	8.94± 0.72 aAB	7.95± 0.50 aAB	7.80± 0.37 aA	11.14± 0.85 aAB	9.91± 0.56 aAB	9.47± 0.75 aA	12.51± 0.89 bAB	11.54± 0.15 aB	10.37± 0.86 aA
	无性系4	1.84± 0.11 aA	1.68± 0.32 aA	2.04± 0.12 aA	5.29± 0.41 aA	4.55± 0.42 aA	5.40± 0.21 aA	7.73± 0.29 aA	6.98± 0.41 aA	7.42± 0.37 aA	10.13± 0.49 bA	8.91± 0.36 aA	9.33± 0.49 aA	11.60± 0.56 bA	10.17± 0.24 aA	10.37± 0.52 aA
树高 height	无性系1	3.63± 0.12 aB	3.60± 0.73 aA	3.90± 0.32 aB	6.49± 0.10 aB	6.44± 0.87 aA	6.87± 0.21 aC	9.02± 0.22 aB	8.90± 0.87 aA	9.25± 0.11 aB	11.21± 0.33 aBC	10.87± 0.73 aA	11.20± 0.33a B	13.96± 0.44 aC	13.41± 0.66 aB	13.79± 0.51 aB
	无性系2	3.66± 0.13 aB	3.45± 0.71 aB	4.07± 0.17 aB	6.44± 0.23 aB	6.10± 0.83 aA	6.76± 0.18 aBC	9.12± 0.24 aB	8.80± 0.78 aA	9.29± 0.08 aB	11.61± 0.22 aC	11.14± 0.94 aA	11.72± 0.19 aB	14.01± 0.08 aC	13.61± 0.60 aAB	13.68± 0.41 aAB
	无性系3	3.49± 0.34 aB	3.32± 0.44 aA	3.91± 0.13 aB	6.09± 0.44 aAB	5.97± 0.44 aA	6.46± 0.09 aB	8.36± 0.60 aAB	8.21± 0.38 aA	9.05± 0.23 aB	10.64± 0.49 aAB	10.43± 0.51 aA	11.31± 0.13 aB	13.10± 0.19 aB	13.16± 0.63 aAB	13.45± 0.58 aAB
	无性系4	2.81± 0.11 aA	2.74± 0.28 aA	3.10± 0.06 aA	5.61± 0.06 aA	5.29± 0.37 aA	5.93± 0.12 aA	7.93± 0.08 aA	7.75± 0.49 aA	8.47± 0.12 aA	10.19± 0.12 aA	9.73± 0.52 aA	10.52± 0.19 aA	12.35± 0.30 aA	11.98± 0.64 aA	12.62± 0.26 aA
冠幅 crown width	无性系1				2.36± 0.05 aC	2.18± 0.31 aAB	2.39± 0.06 aAB	2.63± 0.20 aB	2.45± 0.28 aB	2.43± 0.10 aB	2.96± 0.09 bB	2.58± 0.09 abB	2.21± 0.25 aA	3.46± 0.25 bAB	3.03± 0.16 abAB	2.67± 0.34 aA
	无性系2				2.55± 0.07 aD	2.39± 0.16 aB	2.44± 0.13 aB	2.69± 0.19 aB	2.47± 0.22 aB	2.42± 0.20 aB	2.93± 0.14 bB	2.60± 0.05 bB	2.06± 0.20 aA	3.54± 0.44 bB	3.12± 0.09 abB	2.63± 0.32 aA
	无性系3				2.20± 0.02 aB	2.11± 0.07 aAB	2.23± 0.12 aAB	2.23± 0.13 aA	2.13± 0.07 aAB	2.16± 0.10 aAB	2.52± 0.19 bA	2.32± 0.06 aA	1.93± 0.24 aA	2.93± 0.19 aAB	2.73± 0.18 aAB	2.35± 0.30 aA
	无性系4				1.92± 0.03 aA	1.88± 0.13 aA	2.16± 0.11 bA	2.09± 0.10 aA	1.97± 0.11 aA	2.06± 0.13 aA	2.49± 0.16 aA	2.28± 0.17 aA	2.14± 0.07 aA	2.79± 0.15 aA	2.57± 0.29 aA	2.63± 0.13 aA
单株材积 individual volume	无性系1	0.001 5± 0.000 2 aB	0.001 7± 0.000 9 aA	0.002 2± 0.000 4 aC	0.013 6± 0.001 8 aB	0.012 6± 0.005 1 aA	0.014 0± 0.002 1 aB	0.037 1± 0.004 6 aC	0.031 7± 0.008 5 aAB	0.031 8± 0.004 2 aB	0.068 7± 0.011 0 aBC	0.056 3± 0.010 0 aB	0.056 6± 0.000 0 aBC	0.111 5± 0.015 0 aBC	0.084 0± 0.020 0 aBC	0.082 2± 0.020 0 aA
	无性系2	0.001 5± 0.000 3 aB	0.001 4± 0.000 9 aA	0.002 1± 0.000 1 aBC	0.014 4± 0.001 8 aB	0.011 8± 0.004 8 aA	0.014 5± 0.001 3 aB	0.044 6± 0.005 8 aBC	0.033 9± 0.008 3 aB	0.032 7± 0.001 9 aB	0.085 7± 0.014 aC	0.062 3± 0.010 0 aB	0.060 4± 0.010 0 aC	0.129 6± 0.019 0 aC	0.094 5± 0.010 0 aC	0.081 2± 0.010 0 aA
	无性系3	0.001 1± 0.000 4 aAB	0.000 8± 0.000 4 aA	0.001 5± 0.000 2 aB	0.010 1± 0.002 4 aAB	0.007 9± 0.002 2 aA	0.009 9± 0.000 6 aA	0.028 6± 0.005 5 aAB	0.022 5± 0.003 6 aAB	0.023 7± 0.001 5 aA	0.054 4± 0.008 0 aAB	0.042 9± 0.010 0 aAB	0.042 7± 0.010 0 aAB	0.082 7± 0.011 0 aAB	0.071 3± 0.010 0 aAB	0.060 3± 0.010 0 aA
	无性系4	0.000 5± 0.000 1 aA	0.000 4± 0.000 2 aA	0.000 7± 0.000 1 aA	0.007 2± 0.001 1 aA	0.005 2± 0.001 3 aA	0.007 9± 0.000 5 bA	0.020 5± 0.001 4 aA	0.016 7± 0.002 5 aA	0.020 3± 0.001 7 aA	0.043 5± 0.004 0 bA	0.032 7± 0.003 6 aA	0.038 5± 0.003 1 abA	0.067 6± 0.006 0 bA	0.051 4± 0.004 4 aA	0.056± 0.004 8 bA
蓄积量 stand volume	无性系1	1.650± 0.11 aB	1.95± 1.13 aA	6.28± 1.18 bC	14.72± 0.24 aBC	14.79± 6.15 aAB	37.46± 5.26 bB	39.71± 0.98 aB	38.32± 9.60 aAB	79.81± 8.17 bB	71.41± 1.22 aB	64.52± 7.62 aA	136.88± 18.80 bA	112.68± 2.42 aC	99.60± 6.53 bA	178.75± 20.20 bA
	无性系2	1.82± 0.24 aB	2.08± 1.42 aA	6.94± 0.08 bC	18.37± 1.41 aC	19.77± 9.22 aB	47.27± 3.91 bC	56.59± 2.32 aC	59.05± 18.40 aB	98.45± 0.22 bC	104.11± 2.37 aC	108.78± 26.1 aB	183.13± 16.90 bB	157.16± 0.71 aD	166.15± 28.9 aB	237.94± 26.2 bB
	无性系3	1.28± 0.54 aAB	0.61± 0.08 aA	4.46± 0.55 bB	12.03± 3.22 aAB	8.14± 2.01 aAB	28.54± 0.13 bA	34.22± 7.45 aAB	26.71± 8.42 aA	67.32± 1.15 bA	63.18± 9.21 aAB	52.98± 19.00 aA	112.27± 5.26 bA	93.82± 8.20 aB	86.86± 28.90 aA	146.63± 8.83 bA
	无性系4	0.65± 0.02 bA	0.37± 0.04 aA	1.94± 0.16 cA	9.71± 0.80 bA	5.28± 0.03 aA	24.49± 1.69 cA	25.91± 0.20 bA	18.22± 0.02 aA	60.29± 3.93 cA	53.64± 2.28 aA	37.05± 0.35 bA	113.92± 6.11 cA	78. 9± 4.33 aA	58.02± 1.34 bA	165.59± 10.70 cA

Table 1

Table 2

Table 3

Fig.1

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无性系 clone	高径比height-diameter ratio			树干圆满度stem fullness			树干通直度stem straightness
无性系 clone	A	B	C	A	B	C	A	B	C
无性系1 clone 1	0.99± 0.041 aAB	1.08± 0.033 aAB	1.15± 0.054 bA	1.01± 0.012 aA	1.00± 0.003 aA	1.00± 0.006 aA	2.99± 0.014 aC	3.00± 0.000 aA	2.95± 0.045 aA
无性系2 clone 2	0.91± 0.060 aA	1.03± 0.016 bA	1.13± 0.034 cA	1.00± 0.011 aA	1.00± 0.010 aA	0.99± 0.008 aA	2.81± 0.028 aB	2.66± 0.274 aA	2.57± 0.292 aA
无性系3 clone 3	1.05± 0.073 aAB	1.14± 0.043 aB	1.3± 0.050 bB	1.02± 0.017 aA	1.01± 0.012 aA	1.00± 0.001 aA	2.84± 0.046 aB	2.81± 0.041 aA	2.59± 0.111 aA
无性系4 clone 4	1.07± 0.059 aB	1.18± 0.053 aB	1.22± 0.071 aAB	1.00± 0.002 aA	1.00± 0.010 aA	1.00± 0.005 aA	2.69± 0.062 aA	2.77± 0.078 aA	2.78± 0.078 aA

Effects of initial planting density on growth and stem form of four Larix clones

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无性系 clone	密度 density	树高 height	胸径 DBH	单株材积 individual volume	树干通直度 stem straightness	树干圆满度 stem fullness	高径比 height- diameter ratio
无性系1 clone 1	A	7.0	17.3	34.2	3.7	2.7	15.0
	B	8.6	18.5	36.8	8.4	2.7	15.1
	C	7.2	19.2	38.5	8.5	2.2	15.6
无性系2 clone 2	A	5.0	13.4	27.8	15.1	3.2	10.9
	B	7.5	16.3	34.0	22.2	3.3	13.0
	C	6.1	16.9	35.4	20.9	2.9	13.0
无性系3 clone 3	A	7.7	13.9	26.8	14.6	3.2	13.4
	B	8.7	15.6	34.6	15.3	2.9	16.3
	C	6.3	17.6	33.7	19.1	2.6	11.6
无性系4 clone 4	A	7.6	14.5	28.8	22.4	2.8	13.9
	B	8.7	17.9	36.0	20	2.7	16.2
	C	6.2	18.1	35.7	17.4	2.3	16.2

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