Effects of different combinations of drone flight defense agents and additives on their droplet deposition parameters and field spraying control of cotton aphids

doi:10.6048/j.issn.1001-4330.2025.04.017

Xinjiang Agricultural Sciences ›› 2025, Vol. 62 ›› Issue (4): 929-935.DOI: 10.6048/j.issn.1001-4330.2025.04.017

• Horticultural Special Local Products · Forestry · Agricultural Product Processing Engineering • Previous Articles Next Articles

Effects of different combinations of drone flight defense agents and additives on their droplet deposition parameters and field spraying control of cotton aphids

XUE Qinyuan¹(), ZHANG Jianliang², LI Pengfei¹, FENG Hongzu¹, WU Gang³, WANG Lan¹()

1. Key Laboratory of Integrated Pest Management (IPM) of Xinjiang Production and Construction Corps in Southern Xinjiang /Key Laboratory of Protection and Utilization of Biological Resources in Tarim Basin, Tarim University, Aral Xinjiang 843300, China
2. Agricultural Development Center of the Third Regiment of the First Division of Xinjiang Production and Construction Corps, Aral Xinjiang 843300, China
3. The Institute of Agricultural Sciences of the First Agricultural Production Division of Xinjiang Production and Construction Corps, Aral Xinjiang 843300, China

Received:2024-09-29 Online:2025-04-20 Published:2025-06-20
Supported by:
Financial S & T Program Project of XPCC(2021DB008);S & T Innovation Talent Program Project of XPCC(2022CB004-01);Kashgar Science and Technology Plan Project(KS2024002)

无人机飞防助剂和杀虫剂组合对其雾滴沉降特性及棉蚜防效的影响

薛钦元¹(), 张建良², 李鹏飞¹, 冯宏祖¹, 武刚³, 王兰¹()

1.塔里木大学/南疆农业有害生物综合治理兵团重点实验室/塔里木盆地生物资源保护利用兵团重点实验室,新疆阿拉尔 843300
2.新疆生产建设兵团第一师三团农业发展服务中心,新疆阿拉尔 843300
3.新疆生产建设兵团第一师农业科学研究所,新疆阿拉尔 843300

通讯作者: 王兰(1968-),女,山东招远人,教授,博士,硕士生/博士生导师,研究方向为植物保护,(E-mail)wang-lan95@163.com
作者简介:薛钦元(2002-),男,河南焦作人,硕士研究生,研究方向为果树绿色防控,(E-mail)1185225695@qq.com
基金资助:
新疆生产建设兵团财政科技计划(2021DB008);新疆生产建设兵团科技创新人才计划(2022CB004-01);喀什地区科技计划项目(KS2024002)

Abstract

Abstract:

【Objective】 This project aims to screen the optimal combination of pesticides and adjuvants for cotton aphid control in Xinjiang cotton field and its impact on the variable application by plant protection unmanned aerial vehicles (UAV). 【Methods】 Through the field efficacy experiment, the control effect of five spray auxiliaries added to different pesticides on Aphis gossypii was compared, and the physicochemical properties of 20% spirotetramat · dinotefuran suspension concentrate added with Beidatong and the control effect of UAV variable application on cotton aphids were measured. 【Results】 After adding 5 types of adjuvants, the control effect on Aphis gossypii was improved. Among them, 20% spirotetramat · dinotefuran suspension concentrate added with Beidatong had the strongest control effect, and the reduction rate of insect population reached 86% after 7 days of treatment, followed by the addition of 22% thiamethoxam·lambda-cyhalothrin suspension concentrate added with Beidatong, which was 81%. The difference between the two was not significant (P<0.05). According to the prescription map generated by the experimental site, the cotton field unmanned aerial vehicle variable spraying operation was carried out. The results showed that the combination of 20% spirotetramat · dinotefuran suspension concentrate added with Beidatong showed good control effects in four aphid infestation levels by UAV variable spraying. The optimal control effect was achieved when the level of harm was 4 and the dosage was 30 L/hm². After 7 days of treatment, the insect population reduction rate reached 91.14%, and the drug coverage rate, droplet density distribution uniformity, and droplet density were 133%, 87%, and 26.28 number/cm², respectively, with significant differences compared to other treatments (P<0.05). 【Conclusion】 The optimal combination of insecticides and adjuvants for the control of Aphis gossypii is 20% spirotetramat · dinotefuran suspension concentrate added with Beidatong by UAV. The variable operation with a hazard level of 4 has the best effect on the control of cotton aphids. The research results provide scientific basis for the precise application to control cotton aphids of variable pesticides by UAV variable spraying.

Key words: Aphis gossypii; adjuvants; pesticide; control effect; plant protection unmanned aerial vehicle (UAV); variable spraying

摘要：

【目的】筛选新疆棉田防治棉蚜的最佳药剂与助剂组台,探究其对无人机变量施药防治效果,为无人机精准变量施药防控棉蚜提供依据。【方法】通过田间药效试验,比较不同药剂添加5种喷雾助剂后对棉蚜防效,同时依据试验地生成的处方图开展棉田无人机变量施药作业,测定20%螺虫乙酯·呋虫胺悬浮剂添加倍达通后的理化性质和无人机变量施药防治棉蚜的效果。【结果】20%螺虫乙酯·呋虫胺悬浮剂添加倍达通的防效最高,药后7 d,虫口减退率达到86%,22%噻虫·高氯氟添加倍达通次之,为81%,二者差异不显著,但与其余处理之间有明显差异(P<0.05);无人机变量喷施20%螺虫乙酯·呋虫胺悬浮剂与倍达通组合在4个蚜害等级区均有较好的防治效果,其中危害程度4级、用药量为30 L/hm²时的防效最佳,药后7 d,虫口减退率达到91.14%,其药液覆盖率、雾滴密度分布均匀度和雾滴密度分别为133%、87%和26.28个/cm²,与其他处理有显著差异(P<0.05)。【结论】无人机喷施杀虫剂防治棉蚜的药剂和助剂的最佳组合是20%螺虫乙酯·呋虫胺悬浮剂添加倍达通助剂,当危害程度达到4级、用药量30 L/hm²时的变量作业防治棉蚜的效果最佳。

关键词: 棉蚜, 助剂, 杀虫剂, 防效, 植保无人机, 变量施药

CLC Number:

S482.3

XUE Qinyuan, ZHANG Jianliang, LI Pengfei, FENG Hongzu, WU Gang, WANG Lan. Effects of different combinations of drone flight defense agents and additives on their droplet deposition parameters and field spraying control of cotton aphids[J]. Xinjiang Agricultural Sciences, 2025, 62(4): 929-935.

薛钦元, 张建良, 李鹏飞, 冯宏祖, 武刚, 王兰. 无人机飞防助剂和杀虫剂组合对其雾滴沉降特性及棉蚜防效的影响[J]. 新疆农业科学, 2025, 62(4): 929-935.

Figures/Tables 8

References 21

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助剂名称 Name of additives	类型 Type	生产厂家 Manufacturer of a product
倍达通 Beidatong	甲基化植物油	河北明顺农业科技有限公司
农健飞 Nongjianfei	超支化聚合物	桂林集琦生化有限公司
奇功 Qigong	基于聚氧乙烯醚改性三硅氧烷	桂林集琦生化有限公司
倍倍加 Beibeijia	脂肪胺	桂林集琦生化有限公司
混合橙精油助剂 Mixed orange essential oil additive	高效植物精油	福建路易达孚公司

助剂名称 Name of additives	类型 Type	生产厂家 Manufacturer of a product
倍达通 Beidatong	甲基化植物油	河北明顺农业科技有限公司
农健飞 Nongjianfei	超支化聚合物	桂林集琦生化有限公司
奇功 Qigong	基于聚氧乙烯醚改性三硅氧烷	桂林集琦生化有限公司
倍倍加 Beibeijia	脂肪胺	桂林集琦生化有限公司
混合橙精油助剂 Mixed orange essential oil additive	高效植物精油	福建路易达孚公司

处理 Treat- ments	供试药剂和助剂组合 Combinations of test chemicals and additives	用量 Dosage (mL/L)
1	氟啶虫酰胺·联苯菊酯+农建飞	0.225+6
2	噻虫·高氯氟+农建飞	1.15+6
3	螺虫·呋虫胺+农建飞	0.45+6
4	氟啶虫酰胺·联苯菊酯+倍达通	0.225+15
5	螺虫·呋虫胺+倍达通	0.45+15
6	噻虫·高氯氟+倍达通	1.15+15
7	氟啶虫酰胺·联苯菊酯+奇功	0.225+0.33
8	噻虫·高氯氟+奇功	1.15+0.33
9	螺虫·呋虫胺+奇功	0.45+0.33
10	氟啶虫酰胺·联苯菊酯+倍倍加	0.225+0.33
11	噻虫·高氯氟+倍倍加	1.15+0.33
12	螺虫·呋虫胺+倍倍加	0.45+0.33
13	氟啶虫酰胺·联苯菊酯+ 混合橙精油助剂	0.225+1
14	噻虫·高氯氟+混合橙精油助剂	1.15+1
15	螺虫·呋虫胺+混合橙精油助剂	0.45+1
16	噻虫·高氯氟+水	1.15
17	氟啶虫酰胺·联苯菊酯+水	0.225
18	螺虫·呋虫胺+水	0.45

处理 Treat- ments	供试药剂和助剂组合 Combinations of test chemicals and additives	用量 Dosage (mL/L)
1	氟啶虫酰胺·联苯菊酯+农建飞	0.225+6
2	噻虫·高氯氟+农建飞	1.15+6
3	螺虫·呋虫胺+农建飞	0.45+6
4	氟啶虫酰胺·联苯菊酯+倍达通	0.225+15
5	螺虫·呋虫胺+倍达通	0.45+15
6	噻虫·高氯氟+倍达通	1.15+15
7	氟啶虫酰胺·联苯菊酯+奇功	0.225+0.33
8	噻虫·高氯氟+奇功	1.15+0.33
9	螺虫·呋虫胺+奇功	0.45+0.33
10	氟啶虫酰胺·联苯菊酯+倍倍加	0.225+0.33
11	噻虫·高氯氟+倍倍加	1.15+0.33
12	螺虫·呋虫胺+倍倍加	0.45+0.33
13	氟啶虫酰胺·联苯菊酯+ 混合橙精油助剂	0.225+1
14	噻虫·高氯氟+混合橙精油助剂	1.15+1
15	螺虫·呋虫胺+混合橙精油助剂	0.45+1
16	噻虫·高氯氟+水	1.15
17	氟啶虫酰胺·联苯菊酯+水	0.225
18	螺虫·呋虫胺+水	0.45

处理 Treatments	防效Control effect(%)
处理 Treatments	药后1 d	药后3 d	药后7 d	药后14 d
1	(19.26±1.43)^fg	(45.74±1.85)^fg	(64.43±1.44)^f	(58.17±1.18)^e
2	(30.72±0.75)^cde	(53.04±1.68)^de	(73.16±2.18)^cd	(64.12±2.76)^cd
3	(16.11±1.92)^g	(49.83±3.03)^efg	(72.30±2.05)^cde	(65.31±2.80)^bcd
4	(38.31±1.60)^b	(68.48±0.64)^b	(77.25±1.59)^bc	(70.63±0.71)^b
5	(45.61±1.94)^a	(83.38±0.88)^a	(86.98±2.22)^a	(81.97±1.46)^a
6	(34.34±1.50)^bc	(80.59±0.37)^a	(81.39±0.23)^ab	(79.64±0.63)^a
7	(24.00±2.19)^ef	(52.56±1.86)^de	(73.31±2.28)^cd	(68.94±1.57)^bcd
8	(24.76±2.40)^def	(59.01±1.50)^c	(73.29±2.75)^cd	(70.86±1.32)^b
9	(27.21±2.27)^de	(56.31±1.78)^bc	(69.82±1.73)^def	(68.61±1.55)^bcd
10	(30.17±1.22)^cde	(49.50±2.23)^efg	(67.34±2.25)^def	(65.64±1.78)^bcd
11	(30.30±2.72)^cde	(50.73±2.27)^def	(71.63±3.30)^cdef	(70.19±2.20)^b
12	(31.08±2.91)^cd	(59.66±1.57)^c	(72.39±2.19)^cde	(69.79±1.32)^bc
13	(30.82±1.67)^cde	(52.61±1.61)^de	(66.50±1.91)^def	(64.92±1.52)^bcd
14	(30.37±1.51)^cde	(44.61±2.14)^g	(65.68±2.10)^ef	(63.30±1.75)^de
15	(19.39±3.12)^fg	(55.92±1.71)^bc	(67.26±2.54)^def	(63.34±2.27)^de

Effects of different combinations of drone flight defense agents and additives on their droplet deposition parameters and field spraying control of cotton aphids

无人机飞防助剂和杀虫剂组合对其雾滴沉降特性及棉蚜防效的影响

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Figures/Tables 8

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危害程度 Degree of harm	用药量 Dosage (L/hm²)	虫口减退率Decrease rate(%)
危害程度 Degree of harm	用药量 Dosage (L/hm²)	药后1 d	药后3 d	药后7 d	药后14 d
1级Level 1	18	(28.18±0.63)^a	(61.70±1.98)^a	(76.34±0.41)^a	(67.27±0.63)^a
2级Level 2	21	(31.33±0.56)^b	(69.65±1.22)^b	(81.92±0.24)^b	(71.55±0.40)^b
3级Level 3	25.5	(33.91±0.58)^c	(76.86±0.74)^c	(88.03±0.53)^c	(80.27±0.73)^c
4级Level 4	30	(39.44±0.27)^d	(80.71±0.45)^d	(91.14±0.13)^d	(84.03±0.24)^d

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[2]	ZHANG Shuai, GAO Guowen, WU Lili, ZHAO Haiyan, WANG Xiaowu, FU Kaiyun, JIA Zunzun, Tuerxun Ahemaiti, DING Xinhua, LI Kemei, GUO Wenchao. Evaluation of the synergistic application of seed coating agents, synergists, and micro fertilizers for the prevention and control of corn stem rot disease [J]. Xinjiang Agricultural Sciences, 2024, 61(S1): 19-27.
[3]	YUAN Zihan, ZHAO Wenhui, WANG Xiaowu, Tuerxun Ahemaiti, DING Xinhua, ZHANG Shuai, FU Kaiyun, JIA Zunzun, GUO Wenchao. Screening of Corn Stalk Rot control bacteria and evaluation of control effects [J]. Xinjiang Agricultural Sciences, 2024, 61(S1): 35-48.
[4]	SHEN Yuyang, HONG Gaojie, FAN Guiqiang, CHEN Li, LEI Junjie, LI Guangkuo, GAO Haifeng. The control effect of reduced pesticides application and adjuvant addition on wheat aphids in jujube-wheat intercropping pattern [J]. Xinjiang Agricultural Sciences, 2024, 61(9): 2257-2268.
[5]	AN Zhe, NIU Ruichang, ZHU Xiangzhen, WANG Li, ZHANG Kaixin, LI Dongyang, JI Jichao, NIU Lin, GAO Xueke, LUO Junyu, CUI Jinjie, MA Deying. Analyze the microbial diversity of cotton aphids with different bacterial types in cotton fields [J]. Xinjiang Agricultural Sciences, 2024, 61(9): 2277-2284.
[6]	MA Baihuan, ZHAO Qiang, XIE Jia, XU Kaiyue, REN Ruofei, SONG Xinghu. Effects of biopharmaceutical mixture on the control and growth of cotton Verticillium wilt [J]. Xinjiang Agricultural Sciences, 2024, 61(7): 1748-1756.
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[9]	QIAN Tao, WU Lili, LI Lei, Anniwaer Kuerban, DING Ruifeng. Control effect of pyroxasulfone mixed with pendimethalin on broadleaf weeds in cotton filed and its safety evaluation [J]. Xinjiang Agricultural Sciences, 2024, 61(4): 861-868.
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[11]	WANG Heya, LUO Jingjing, WANG Kang, WANG Ruinan, WANG Xu, GAO Guangrui, FANG Yan. Effects of different microbial agents on the disease prevention effect and yield of beetroot rot [J]. Xinjiang Agricultural Sciences, 2024, 61(2): 448-454.
[12]	WANG Wei, ZHANG Renfu, LIU Haiyang, DING Ruifeng, LIANG Gemei, YAO Ju. Transcriptome analysis of Aphis gossypii sulfoxaflor and acetamiprid-resistant strains with different genetic backgrounds of resistance [J]. Xinjiang Agricultural Sciences, 2024, 61(12): 3078-3088.
[13]	QI Ping, Suoyin Tuya, WEI Yang, ZHANG Shuo, Adili Shataer, Adili Aihemaiti. Evaluation of field control efficacy of 10 medications against Acalitus phloeocoptes Nalepa [J]. Xinjiang Agricultural Sciences, 2024, 61(11): 2761-2768.
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[15]	SONG Danbo, ZHANG Guoxin, WANG Quan, LIU Baojun, HUANG Tao, HAN Hongwei, BAI Jianyu, GUO Qingyuan. Study on the biological characteristics of the pathogen of bacterial perforation of alternaria alternata in Xinjiang and the screening of laboratory agents [J]. Xinjiang Agricultural Sciences, 2023, 60(6): 1515-1522.