Spatial distribution patterns and sampling techniques of Dasineura jujubifolia larvae on facility jujube trees

doi:10.12302/j.issn.1000-2006.202107003

JOURNAL OF NANJING FORESTRY UNIVERSITY ›› 2022, Vol. 46 ›› Issue (4): 201-208.doi: 10.12302/j.issn.1000-2006.202107003

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Spatial distribution patterns and sampling techniques of Dasineura jujubifolia larvae on facility jujube trees

YAN Xiongfei¹(), CHENG Xinhui¹, HAO Zhe², WANG Tinghao¹, QIN Fulin¹, LI Gang¹

1. College of Life Sciences, Yulin University, Yulin 719000, China
2. Yulin City Agricultural Reclamation Service Station of Shaanxi Province, Yulin 719000, China

Received:2021-07-04 Revised:2021-12-29 Online:2022-07-30 Published:2022-08-01

Abstract

Abstract:

【Objective】 Dasineura jujubifolia is an important pest on jujube trees. In recent years, this pest has caused serious economic losses at the jujube base facility in Yulin City, Shaanxi Province. Understanding the spatial distribution pattern and sampling technique of jujube gall midge larvae on protected jujube trees are of great practical significance for the monitoring, prediction and control of this pest. 【Method】 Facility jujube sample plots displaying serious damage by jujube gall midge larvae were selected from April to May 2020 in Liushuhui village, Jia County, Yulin City, Shaanxi Province. First, the damaged jujube trees were examined using methods such as five-point sampling, double diagonal sampling, checkerboard sampling, parallel line sampling and Z-shaped sampling. Then, the number of jujube gall midge larvae on each facility jujube tree was counted using the whole plant survey method, and the suitability, representativeness and variations among these five methods were compared using t-test. After determining the most suitable sampling method, the spatial distribution of jujube gall midge larvae on facility jujube trees was studied using seven aggregation indexes, Iwao’s m^*-m regression analysis, and Taylor power law. 【Result】 Although all five sampling methods were suitable for the investigation of jujube gall midge larvae in facility jujube trees, the parallel line sampling method was the best performing one. The spatial distribution pattern of jujube gall midge larvae on protected jujube trees was of the aggregation type. The basic component of distribution is the mutual attraction between individuals. The greater the density, the higher the aggregation of individual groups. The larvae of jujube gall midge were clustered on facility jujube trees, caused by the joint action of environmental factors and the aggregative habit of individual larvae. According to Iwao’s m^*-m regression analysis, the optimal theoretical sampling formula for jujube gall midge larvae was obtained as: N = 3.841 6/D² (2.878 3/m + 0.176 5). When the control threshold of jujube gall midge larvae was set at four inds/plant, the formula of sequential sampling model was obtained as: $T_{(n)}=4 n \pm 7.4214 \sqrt{n}$. If 100 facility jujube trees are investigated, and the cumulative number of jujube gall midge larvae is greater than 474, they need to be controlled. 【Conclusion】 The parallel line sampling method was determined to be the most suitable investigation method for jujube gall midge larvae on facility jujube trees. The spatial distribution of jujube gall midge larvae on facility jujube trees is of the aggregation type, which provides a theoretical support for the prevention and control of jujube gall midge larvae in facility jujube trees.

Key words: Dasineura jujubifolia, facility, jujube tree (Ziziphus jujuba), spatial distribution pattern, sampling technique

CLC Number:

S763
S433

YAN Xiongfei, CHENG Xinhui, HAO Zhe, WANG Tinghao, QIN Fulin, LI Gang. Spatial distribution patterns and sampling techniques of Dasineura jujubifolia larvae on facility jujube trees[J]. JOURNAL OF NANJING FORESTRY UNIVERSITY, 2022, 46(4): 201-208.

Figures/Tables 8

Table 1

Criteria for determining the spatial distribution pattern of Dasineura jujubifolia larvae by seven aggregation indices"

空间分布 spatial distribution	扩散系数C diffusion coefficient	I	K	C_A	m^*	L	$L a / m$
均匀分布 uniform distribution	< 1	< 0	< 0	< 0	<m	< 1	< 1
聚集分布 aggregate distribution	> 1	> 0	>0(超过8近乎poisson分布)	> 0	>m	> 1	> 1
随机分布 random distribution	1	0	趋向于∞	0	m	1	1

Table 1

Table 2

Table 3

Fig.1

Fig.2

Table 4

Table 5

Table 6

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抽样方法 sampling methods	抽取株数 sampling number	平均幼虫数量 mean samples	标准偏差 standard deviation	标准误差 standard error	变异系数 variation coefficient	与总样本 t_0.05 检验值 total sample t₀_.₀₅ test value	自由度 df	t	适合性 fitness
全查 whole check	140	15.144	9.782	—	0.646	—	—	—	—
五点抽样 five-point	15	15.400	10.894	2.813	0.707	0.929	14	0.091	适合
双对角线抽样 double diagonal	20	14.750	8.528	1.907	0.578	0.839	19	-0.207	适合
棋盘式抽样 checkerboard	27	14.407	9.783	1.883	0.679	0.700	26	-0.390	适合
平行线抽样 parallel line	45	15.178	9.724	1.450	0.641	0.982	44	0.023	适合
“Z”形抽样 Z-shaped	33	16.030	9.587	1.669	0.598	0.617	32	0.505	适合

样地序号 sample number	平均幼虫数 sample mean	方差(S²) variance	扩散系数(C) diffusion coefficient	I	C_A	K	m^*	L	L_a/_m
1	15.840	93.851	5.925	4.925	0.311	3.216	20.765	1.311	1.053
2	14.540	76.580	5.267	4.267	0.293	3.408	18.807	1.293	1.056
3	16.240	87.288	5.375	4.375	0.269	3.712	20.615	1.269	1.050
4	15.420	86.113	5.584	4.584	0.297	3.364	20.004	1.297	1.053
5	15.260	92.356	6.052	5.052	0.331	3.020	20.312	1.331	1.055
6	14.720	78.124	5.307	4.307	0.293	3.417	19.027	1.293	1.055
聚集度aggregation indexes			>1	>0	>0	>0且<8	>m	>1	>1
分布型distribution forms			聚集分布	聚集分布	聚集分布	聚集分布	聚集分布	聚集分布	聚集分布

样地序号 sample No.	株数tree number	K	γ	λ
1	15.840	3.216	5.773	14.215
2	14.540	3.408	6.155	13.132
3	16.240	3.712	7.424	14.796
4	15.420	3.364	6.067	13.907
5	15.260	3.020	5.381	13.593
6	14.720	3.417	6.175	13.299

防治阈值 (m₀) control threshold	上下限 upper and lower limits		不同调查株数的累计虫口数/头 the cumulative number of insects in different investigation plants
防治阈值 (m₀) control threshold	上下限 upper and lower limits		10		20		30		40		50		60		70		80		90	100
2	上限(T₁) upper limits	36		62		87		112		135		159		182		205		227		250
2	下限(T₀) lower limits	4		18		33		48		65		81		98		115		133		150
4	上限(T₁) upper limits	63		113		161		207		252		297		342		386		430		474
4	下限(T₀) lower limits	17		47		79		113		148		183		218		254		290		326
6	上限(T₁) upper limits	90		163		232		300		367		434		500		565		630		695
6	下限(T₀) lower limits	30		77		128		180		233		286		340		395		450		505

Spatial distribution patterns and sampling techniques of Dasineura jujubifolia larvae on facility jujube trees

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相对允许误差 permissible variation	估计不同枣瘿蚊幼虫数量的最佳抽样数/株 the number of Dasineura jujubifolia larvae estimated
相对允许误差 permissible variation	2	6	10	14	18	22	26	30	34	38
0.1	621	252	178	147	129	118	110	105	100	97
0.2	155	63	45	37	32	30	28	26	25	24
0.3	69	28	20	16	14	13	12	12	11	11