植保无人机施药对核桃黑斑蚜和黄刺蛾的田间防效评价

doi:10.6048/j.issn.1001-4330.2021.11.014

新疆农业科学 ›› 2021, Vol. 58 ›› Issue (11): 2077-2083.DOI: 10.6048/j.issn.1001-4330.2021.11.014

• 植物保护·园艺特产·贮藏保鲜加工 • 上一篇下一篇

植保无人机施药对核桃黑斑蚜和黄刺蛾的田间防效评价

朱晓锋¹(), 徐兵强¹, 宋博¹, 熊金铭², 高冠荣², 闫晓静³, 阿布都克尤木·卡德尔¹, 杨森¹

1.新疆农业科学院植物保护研究所/农业农村部西北荒漠作物有害生物综合治理重点实验室/特色林果产业国家地方联合工程研究中心,乌鲁木齐 830091
2.新疆农业大学,乌鲁木齐 830091
3.中国农业科学院植物保护研究所,北京 100193

收稿日期:2020-05-16 出版日期:2021-11-20 发布日期:2021-12-16
作者简介:朱晓锋(1979-),男,河南许昌人,副研究员,博士,硕士研究生导师,研究方向为新疆特色林果有害生物综合防控,(E-mail) zxf5117@163.com
基金资助:
新疆维吾尔自治区科技支疆项目计划(指令性)(2018E02028)

Field Control Evaluation of Plant Protection UAV Spreading Pesticide against Chromaphis juglandicola and Cnidocampa flavescens in Walnut Orchard

ZHU Xiaofeng¹(), XU Binqiang¹, SONG Bo¹, XIONG Jinming², GAO Guanrong², YAN Xiaojing³, Abudukeyoumu Kader¹, YANG Sen¹

1. Key Laboratory of Integrated Crop Pest Management in Northwestern Oasis of China, MOARA / National Local Joint Engineering Research Centre of Special Forestry and Fruit Industry/Institute of Plant Protection,Xinjiang Academy of Agricultural Sciences,Urumqi 830091, China
2. Xinjiang Agricultural University, Urumqi 830091, China
3. Institute of Plant Protection, Chinese Academy of Agricultural Sciences, Beijing 100193, China

Received:2020-05-16 Online:2021-11-20 Published:2021-12-16
Supported by:
Xinjiang uygur autonomous region science and technology assistance to Xinjiang project plan (mandatory) project(2018E02028)

摘要/Abstract

摘要：

【目的】评价植保无人机施药对核桃黑斑蚜Chromaphis juglandicola (Kaltenbach)和黄刺蛾Cnidocampa flavescens(Walker)的防治效果,为植保无人机防控核桃害虫提供理论依据和技术支撑。【方法】采用植保无人机田间喷雾、调查虫口减退率、计算防治效果、方差分析。【结果】在添加喷雾助剂量为0.5%时,植保无人机在核桃园施药后的农药地面流失率均在10%以内;药后14 d 70%吡虫啉(用量为150 mL/ hm²)对外围核桃黑斑蚜的防治效果最高,为96.05%,平均为80.37%,与22%噻虫·高氯氟(用量为375 mL/ hm²)和25%环氧虫啶(用量为300 mL/ hm²)处理有显著性差异;药后10 d 22%噻虫·高氯氟(用量为525 mL/ hm²)、1.2%烟碱·苦参碱(用量为1 050 mL/ hm²)、3.2%阿维菌素(用量为525 mL/ hm²)对黄刺蛾的防治效果最高,分别为98.17%、90.39%和95.46%,3个处理之间无显著性差异。【结论】在添加喷雾助剂时,植保无人机喷洒70%吡虫啉对核桃黑斑蚜的防治效果在80%以上,22%噻虫·高氯氟、1.2%烟碱·苦参碱和3.2%阿维菌素对黄刺蛾的防治效果在90%以上,在生产中可以利用植保无人机喷洒上述药剂防控核桃黑斑蚜和黄刺蛾。

关键词: 植保无人机; 核桃黑斑蚜; 黄刺蛾; 防效评价

Abstract:

【Objective】 To evaluate the control effects of plant protection unmanned aerial vehicle (UAV) as sprayer on Chromaphis juglandicola (Kaltenbach) and Cnidocampa flavescens (Walker) in walnut orchards, so as to provide theoretical reference and technical support for control of walnut pests by plant protection UAV.【Method】 Field spraying with plant protection UAV, investigation of insect pest decline rate, calculation of control effects and variance analysis.【Result】 The ground loss rates of pesticides sprayed with plant protection UAV were less than 10% in walnut orchard after adding 0.5% spray adjuvant. And the control effect of 70% imidacloprid (The dose was 150 g/hm²) was 96.05% against C. juglandicola on the outside leaves and the average control effect was 80.37%, which was significantly higher than that of 22% thiamethoxam·lambda-cyhalothrin (The dose was 375 g/hm²) and 25% cycloxaprid (The dose was 300 g/hm²) on the 14 days after application. The average control effects of 22% thiamethoxam · lambda-cyhalothrin (The dose was 525 g/hm²), 1.2%matrine·nicotine (The dose was 1,050 g/hm²) and 3.2% abamectin (The dose was 525 g/hm²) against C. flavescens were 98.17%, 90.39% and 95.46%, respectively on the 10 days after application. There was no significant difference between the three treatments.【Conclusion】 When adding spray adjuvant, the control effect of 70% imidacloprid against C. juglandicola in plant protection UAV is over 80%, the control effects of 22% thiamethoxam·lambda-cyhalothrin, 1.2% matrine·nicotineand 3.2% abamectin against C. juglandicola are 90%.Plant protection UAV can be used to spray the above pesticides to control C. juglandicola and C. flavescens in production.

Key words: plant protection unmanned aerial vehicle (UAV); Chromaphis juglandicola; Cnidocampa flavescens; control effect evaluation

中图分类号:

S436.64

朱晓锋, 徐兵强, 宋博, 熊金铭, 高冠荣, 闫晓静, 阿布都克尤木·卡德尔, 杨森. 植保无人机施药对核桃黑斑蚜和黄刺蛾的田间防效评价[J]. 新疆农业科学, 2021, 58(11): 2077-2083.

ZHU Xiaofeng, XU Binqiang, SONG Bo, XIONG Jinming, GAO Guanrong, YAN Xiaojing, Abudukeyoumu Kader, YANG Sen. Field Control Evaluation of Plant Protection UAV Spreading Pesticide against Chromaphis juglandicola and Cnidocampa flavescens in Walnut Orchard[J]. Xinjiang Agricultural Sciences, 2021, 58(11): 2077-2083.

图/表 3

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药剂 Insecticide	用药量 Dose of insec ticide (g/ hm²)	助剂用量 Dose of adju vant (mL/ hm²)	农药地面流失率 Ground loss rates of pesticide (%)	平均防治效果±SE Average control effect(%)± SE
药剂 Insecticide	用药量 Dose of insec ticide (g/ hm²)	助剂用量 Dose of adju vant (mL/ hm²)	农药地面流失率 Ground loss rates of pesticide (%)	2 d	4 d	6 d	8 d	10 d	14 d
70%吡虫啉 70% Imidacloprid	150	225	9.22±3.06^a	20.73±5.12^a	24.12±13.90^a	47.63±4.56^a	60.60±5.50^a	68.48±0.97^a	80.37±3.79^a
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	375		4.44±0.34^a	7.51±11.69^a	22.95±9.93^a	47.38±10.50^a	48.56±13.46^ab	56.94±4.58^a	48.79±3.75^b
25%环氧虫啶 25% Cycloxaprid	300		6.66±1.37^a	13.13±6.57^a	-7.99±23.01^a	-7.15±17.04^b	-9.52±20.04^b	-12.52±15.37^b	-32.26±9.63^c

药剂 Insecticide	用药量 Dose of insec ticide (g/ hm²)	助剂用量 Dose of adju vant (mL/ hm²)	农药地面流失率 Ground loss rates of pesticide (%)	平均防治效果±SE Average control effect(%)± SE
药剂 Insecticide	用药量 Dose of insec ticide (g/ hm²)	助剂用量 Dose of adju vant (mL/ hm²)	农药地面流失率 Ground loss rates of pesticide (%)	2 d	4 d	6 d	8 d	10 d	14 d
70%吡虫啉 70% Imidacloprid	150	225	9.22±3.06^a	20.73±5.12^a	24.12±13.90^a	47.63±4.56^a	60.60±5.50^a	68.48±0.97^a	80.37±3.79^a
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	375		4.44±0.34^a	7.51±11.69^a	22.95±9.93^a	47.38±10.50^a	48.56±13.46^ab	56.94±4.58^a	48.79±3.75^b
25%环氧虫啶 25% Cycloxaprid	300		6.66±1.37^a	13.13±6.57^a	-7.99±23.01^a	-7.15±17.04^b	-9.52±20.04^b	-12.52±15.37^b	-32.26±9.63^c

药剂 Insecticide	方位 Azimuth	平均防治效果±SE Average control effect(%)± SE
药剂 Insecticide	方位 Azimuth	2 d	4 d	6 d	8 d	10 d	14 d
70%吡虫啉 70% Imidacloprid	外围	28.22±11.29^a	50.68±13.76^a	76.24±4.81^a	86.26±4.08^a	94.40±1.40^a	96.05±0.83^a
70%吡虫啉 70% Imidacloprid	内膛	19.92±5.06^a	10.07±19.22^a	29.61±7.37^b	42.33±12.87^b	44.68±2.87^b	65.28±6.19^b
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	外围	2.38±21.46^a	30.95±12.78^a	56.19±17.84^a	62.34±15.02^a	68.57±8.75^a	58.97±12.19^a
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	内膛	9.19±14.87^a	15.61±19.01^a	40.94±10.52^a	38.38±14.99^a	49.02±3.29^a	37.69±9.99^a

药剂 Insecticide	方位 Azimuth	平均防治效果±SE Average control effect(%)± SE
药剂 Insecticide	方位 Azimuth	2 d	4 d	6 d	8 d	10 d	14 d
70%吡虫啉 70% Imidacloprid	外围	28.22±11.29^a	50.68±13.76^a	76.24±4.81^a	86.26±4.08^a	94.40±1.40^a	96.05±0.83^a
70%吡虫啉 70% Imidacloprid	内膛	19.92±5.06^a	10.07±19.22^a	29.61±7.37^b	42.33±12.87^b	44.68±2.87^b	65.28±6.19^b
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	外围	2.38±21.46^a	30.95±12.78^a	56.19±17.84^a	62.34±15.02^a	68.57±8.75^a	58.97±12.19^a
22%噻虫·高氯氟 22% Thiamethoxam·Lambda-cyhalothrin	内膛	9.19±14.87^a	15.61±19.01^a	40.94±10.52^a	38.38±14.99^a	49.02±3.29^a	37.69±9.99^a

药剂 Insecticide	用药量 Dose (g/ hm2)	助剂用量 Dose of adjuvant (mL/ hm2)	农药地面流失率 Ground loss rates of pesticide(%)	平均防治效果±SE Average control effect(%)± SE
药剂 Insecticide	用药量 Dose (g/ hm2)	助剂用量 Dose of adjuvant (mL/ hm2)	农药地面流失率 Ground loss rates of pesticide(%)	1 d	3 d	5 d	7 d	10 d	14 d
22%噻虫·高氯氟	525	150	8.57±1.73^a	48.44±11.50^ab	86.34±3.73^a	94.98±3.05^a	96.20±1.92^a	98.17±1.83^a	97.10±2.90^a
22% Thiamethoxam·Lambda-cyhalothrin	525		8.57±1.73^a	48.44±11.50^ab	86.34±3.73^a	94.98±3.05^a	96.20±1.92^a	98.17±1.83^a	97.10±2.90^a
1.2%烟碱·苦参碱1.2% matrine·nicotine	1 050		5.30±0.76^a	58.22±7.87^a	74.28±11.12^ab	86.08±7.85^a	87.11±6.46^a	90.39±9.61^a	89.77±6.24^a
3.2%阿维菌素3.2% abamectin	525		9.59±1.00^a	17.36±10.19^b	49.85±10.20^b	71.26±10.58^a	85.09±2.05^a	95.46±2.37^a	92.43±4.25^a

植保无人机施药对核桃黑斑蚜和黄刺蛾的田间防效评价

Field Control Evaluation of Plant Protection UAV Spreading Pesticide against Chromaphis juglandicola and Cnidocampa flavescens in Walnut Orchard

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