沈阳地区吸虫塔监测大豆蚜迁飞动态及其与气象因子关系的分析

【目的】明确沈阳地区吸虫塔对大豆蚜Aphis glycines(Matsumura)迁飞活动的监测效果以及对其有显著影响的气象因素,为大豆蚜防控提供预警信息。【方法】2009年至2014年采用吸虫塔(Suction trap)对大豆蚜的迁飞活动进行自动、实时监测。结合当年田间大豆蚜动态调查,分析吸虫塔诱捕量与田间蚜量的相关性;采用逐步回归分析研究了吸虫塔诱捕量与气象因素的关系。【结果】监测及分析结果表明,吸虫塔诱捕量与田间大豆蚜量之间存在显著的相关性。吸虫塔诱捕的始见期和首次高峰期均早于田间发生的大豆蚜始见期和盛发期,吸虫塔的监测结果对田间蚜虫的发生可以起到预警的作用。诱捕量与气象因子的逐年回归模型分析结果显示,温度和降水量是影响大豆蚜有翅蚜迁飞的重要气象因素;总回归模型显示,试验期间,吸虫塔当年度诱捕量与前一年度冬季极端最低温、4—6月均温、6—7月最低温、9月均温具有正相关同步协同作用,而与6—7月降雨量和9月雨日具有负相关反向抑制作用。【结论】吸虫塔监测结果比较清晰的展示了大豆蚜的迁飞习性,很好的拟合了当年田间大豆蚜的种群动态。结合气象因子和诱捕量的预测模型研究,为吸虫塔及时准确的发挥预警功能提供必要的理论指导和实践依据。     

播期对大豆蚜及其天敌种群动态的影响

【目的】研究大豆播期对大豆蚜Aphis glycines Matsumura及其天敌的影响。【方法】试验在2012年、2013年进行,设置了3个大豆播期处理。每周调查播期处理田大豆蚜种群及天敌种类和数量,分析大豆蚜种群数量、种群增长率的时序动态、大豆蚜和天敌的关联度。【结果】不同播期条件下大豆蚜有翅蚜及无翅蚜的种群动态趋势基本一致,有翅蚜蚜量高峰期要早于无翅蚜1周。处理间的大豆蚜田间始见期与终见期随着播期推后而延迟,大豆蚜在田间扩散和消退的时期也随着大豆播期延后。晚播的两个处理高峰期蚜量多于或等于正常播期处理的蚜量。大豆蚜与天敌关联度随着播期的推后而变高。在调查的7种天敌中大豆蚜与异色瓢虫的关联度最高,草蛉、小花蝽和蚜茧蜂也表现较高的关联度。【结论】播期会显著影响大豆蚜的田间始见期和终见期,随着播期的推迟大豆蚜种群高峰期蚜量以及大豆蚜与天敌的关联度都会提高。     

吸虫塔对麦长管蚜迁飞监测的影响因素分析

【目的】为了明确吸虫塔对麦长管蚜Sitobion avenae(Fabricius)迁飞活动监测效果的影响因素。【方法】采用回归分析和通径分析等方法,分析田间麦长管蚜数量与吸虫塔吸捕量的相关性,分析不同气象因素对吸虫塔中麦蚜吸捕数量的影响程度。【结果】结果显示,吸虫塔的有翅蚜吸捕量与田间麦长管蚜种群密度及有翅蚜数量存在显著的相关性,即田间麦长管蚜有翅成蚜数量对吸虫塔的吸捕量具有直接影响,而吸虫塔中麦长管蚜的吸捕量也直接反映田间有翅成蚜及种群动态的实际情况。另外,在廊坊地区,吸虫塔初期监测到的有翅麦长管蚜要比小麦田间发生的早几天。通过对吸虫塔中麦长管蚜有翅成蚜吸捕量与气象因素灰色关联度分析的结果表明,降雨天气对麦长管蚜的迁飞和种群动态具有突出的影响作用,可以造成麦长管蚜有翅成蚜迁入的"突增"和种群的"骤降";同时温度和湿度是两个影响麦长管蚜迁飞的重要因素;在麦长管蚜的迁入初期,温度对其迁飞影响最大;在大风天气,风速也会对麦长管蚜的迁入或飞翔活动产生较大影响。【结论】田间麦长管蚜发生数量与吸虫塔的吸捕量存在正相关;降雨、温度和风速是影响麦长管蚜迁飞活动的主要气象因素。     

黑龙江大豆蚜种群动态及田间空间分布研究

2007-2009年对黑龙江大豆蚜田间种群动态的调查结果表明,6月中旬大豆蚜Aphis glycines Matsumura开始在田间出现,3～5周后田间有蚜株率达到100%。7月未至8月初蚜量达到高峰期,9月中下旬在田间逐渐消失。大豆蚜有翅蚜与无翅蚜的发生动态基本一致,有翅蚜高峰期有时会稍有提前。2007年大豆蚜发生时期早、基数大、增长周期长导致高峰期蚜量显著高于2008年和2009年。大豆蚜田间分布聚集度指标I﹥0、m*/m﹥1、Ca﹥0、C﹥1,整个生长季种群都表现为聚集分布。建立的Iwao回归关系方程(m*=7.14758+1.11200m)表明种群分布的基本成分为个体群,个体之间表现为相互吸引。     

印度小裂绵蚜在土壤中的垂直分布及其种群消长

【目的】印度小裂绵蚜Schizoneurella indica Hille Ris Lambers是在云南昭通苹果上发现的一种新害虫,发生普遍且严重。研究印度小裂绵蚜种群在土壤中的垂直分布及其消长动态是为了掌握其发生与危害特点。【方法】2002—2006年,我们采用盆栽和田间调查的方法对印度小裂绵蚜在土壤中的垂直分布和种群消长开展了研究。【结果】印度小裂绵蚜田间种群数量高峰期主要集中发生在9—12月,5—7月份为其田间种群快速增长期,种群增长率可达200%~273%。印度小裂绵蚜无翅蚜种群在0~30 cm的土壤范围内占总虫量的49.0%,30~60 cm的占27.0%,>60 cm的占24.0%。无翅蚜的各虫龄全年均有发生,冬季以第4龄若虫和无翅成虫为主。有翅蚜的发生全年只有1个时期,为11月上旬至12月下旬。【结论】印度小裂绵蚜田间种群数量全年发生1个高峰期,主要集中在0~30 cm的土壤范围内,随着土壤深度的增加,印度小裂绵蚜种群数量亦逐渐下降。田间有翅蚜虫量极少,较难观察到。     

作物多样性对大豆蚜的控蚜效应

【目的】研究大豆蚜发生为害及大豆与多种作物间邻作种植对大豆蚜的控制作用,为大豆蚜的可持续综合治理提供理论依据。【方法】采用系统调查的方法,研究大豆蚜和天敌田间种群动态;通过田间罩笼、人工接蚜和释放天敌的方法,研究捕食性天敌对大豆蚜种群的控制作用;在佳木斯地区进行大豆与早熟马铃薯间作,牡丹江地区进行黄瓜-大豆-玉米、甜葫芦-大豆-玉米、烟草-大豆-香瓜、甜菜-大豆-玉米等多作物带状穿插种植模式,以单作大豆田为对照,对不同种植模式的大豆田大豆蚜与天敌进行调查,研究作物多样性对大豆蚜的控制作用。【结果】2009年6月中下旬大豆蚜开始侵入大豆田,3~5周后田间有蚜株率达到100%,大豆蚜种群发生高峰期在7月下旬至8月上旬,9月上旬在田间逐渐消失。草蛉、瓢虫和寄生蜂等为蚜虫天敌优势种;按大豆蚜与天敌数量之比700︰1,释放异色瓢虫和叶色草蛉成虫7 d后,蚜虫种群减退率分别为54.78%和78.79%;大豆与早熟马铃薯间作,在大豆蚜种群迅速增长期早熟马铃薯收获(7月20日)后第5天,豆田蚜虫天敌总数是收获前的2.6倍,与同期单作大豆田相比,间作田大豆蚜种群数量降低了51.3%。大豆与甜葫芦、香瓜、烟草和玉米等作物进行多样性间作种植,在大豆蚜田间发生高峰期,单作豆田益害比为1︰65.2,多样性种植区的大豆田益害比为1︰26~1︰42,与单作大豆田相比,间作田大豆蚜种群数量降低40.7%~83.5%。【结论】2009年大豆蚜的种群高峰期为8月3日,田间的天敌优势种类为草蛉、瓢虫和寄生蜂。早熟马铃薯与大豆间作,在大豆蚜种群迅速增长期间收获早熟马铃薯,大量蚜虫天敌转移至间作的大豆田,从而形成对大豆蚜的控制。大豆与其它经济作物间邻作,大豆田天敌昆虫与蚜虫的益害比明显提高,表明利用农田作物多样性能充分发挥自然天敌的生物控害作用。     

基于吸虫塔（Suction Trap）的蚜虫测报预警网络的构建

吸虫塔（suction trap）是用来监测麦类蚜虫和大豆蚜Aphis glycines迁飞种群动态的大型植保测报设备,在欧洲和北美洲已经呈网络安装分布,为蚜虫的预警和防控提供重要依据。作者借鉴欧美吸虫塔的工作原理和设计,设计并生产了符合我国地域特征的吸虫塔设备,在东北、华北、华中、华东、西北等地布点安装了21台,用于监控我国麦类蚜虫和大豆蚜的迁飞动态,初步形成覆盖我国小麦主产区和大豆主产区的吸虫塔网络系统。此吸虫塔总高8.8m,由底部轴流风机运转产生的负压在塔顶部形成吸力,将迁飞经附近的小型昆虫吸入塔管,最后落入下部的样品收集瓶中,以此获得其迁飞的动态数据。吸虫塔网络的构建和完善,不仅为麦类蚜虫和大豆蚜的监控提供支撑,同时也为其它小型迁飞性昆虫监测、种群动态、生物多样性、生物信息学等研究提供数据。     

大豆蚜自然天敌种群动态及其控蚜作用研究

2008-2010年间,分别在辽东山区和辽西半干旱丘陵地区设置试验田,采用系统调查的方法,对大豆蚜Aphis glycines Matsumura自然天敌种群动态及控蚜作用进行研究。共鉴定辽宁地区大豆蚜天敌7目、16科、44种,其中优势天敌异色瓢虫Leis axyridis(Pallas)居首位。田间试验结果表明,大豆蚜天敌田间消长表现连续6个阶段,即初见期、波动期、上升期、盛期、下降期和消退期;田间3年平均大豆蚜数量与天敌(天敌单位)总体呈极显著的相关关系,各年度百株蚜量与天敌单位也均呈极显著相关关系。辽东地区天敌跟随紧密并随蚜虫数量变化波动,具有明显的自然控蚜作用。其中,7月11-21日天敌发生盛期与蚜虫高峰期吻合,蚜虫急剧下降;7月下旬后,受高温、多雨、蚜霉菌作用、植株老化等影响,蚜虫种群逐步下降、消退,天敌也陆续迁出豆田。辽西地区天敌迁入豆田比蚜虫晚10～15d,对前期蚜虫控制弱,且天敌峰期滞后蚜虫5d左右,一般年份蚜虫发生较重。     

田间不同防治方法对麦蚜种群动态的影响

【目的】从保护生态环境兼顾防治害虫的角度出发,研究不同防治方法对麦蚜种群动态的影响,为麦蚜的田间防治提供理论依据。【方法】本试验分别设置不同的麦蚜防治田(空白对照田、黄板田、糖醋液田、诱芯田、诱虫灯田、综合防治田),在小麦生长期观察不同的防治田内麦蚜的种群动态的变化。【结果】诱虫灯对有翅蚜的防治效果要好于黄板和糖醋液,但对禾谷缢管蚜Rhopalosiphum padi(Linnaeus)有翅蚜的诱捕效果不明显,黄板和糖醋液对有翅蚜和无翅蚜均有防治效果,多种防治方法共同利用对麦蚜种群数量有一定的防治效果。【结论】多种防治方法共同使用的防治效果优于单一防治方法,诱虫灯、糖醋液、黄板、诱芯对不同种类麦蚜的防治效果不同。在田间使用时应注意不同时期采用不同的防治方法。     

河南省内乡县3种瓜类寄主作物上瓜实蝇的种群动态

【目的】近年来,世界性检疫害虫瓜实蝇由我国南部省份传入河南省西南部地区,对当地多种经济作物的产量和品质造成较大影响。明确该虫在新传入地区不同寄主作物上的种群动态,有助于揭示其在田间的发生危害规律,为当地防治工作提供科学依据。【方法】2020—2022年在河南省南阳市内乡县对田间瓜实蝇成虫开展诱捕监测,比较分析其在丝瓜、南瓜和西葫芦3种寄主作物上的种群发生动态。【结果】瓜实蝇在河南省内乡县每年均有发生,成虫种群基本发生于6~7月下旬—10月下旬,发生盛期在8月中旬—9月下旬,有一个明显发生高峰期;其种群数量、种群动态以及发生期均受寄主植物和年代的影响。【结论】河南省内乡县瓜实蝇种群数量和危害程度呈逐年加重趋势,不同瓜类作物蔬菜田中应因地制宜及时采取防治措施。     

吸虫塔诱捕的昆虫种类及对麦蚜的监测效果研究

在河南省原阳县河南省农科院试验基地安装了吸虫塔(suction trap),2009-2010连续2年在该地区进行了昆虫诱捕及麦蚜监测,并对诱捕到的麦蚜数量动态,以及吸虫塔和黄色粘板监测的比较进行了分析。结果显示:该吸虫塔对多种小型昆虫有很好的诱捕效果,在2009年和2010年分别诱捕到了8目39科58种和8目37科61种的小型昆虫,数量较多的主要集中在双翅目、半翅目、膜翅目等。该吸虫塔对麦蚜起到了很好的监测效果,2009年麦蚜始见期比2010年早,2009年麦蚜的优势种为禾谷缢管蚜Rhopalosiphum padi(L.),2010年是荻草谷网蚜Sitobion miscanthi(Takahashi),2009年麦蚜大量发生和高峰期出现的较早,禾谷缢管蚜分别在5月1日,5月13日,5月19日到达高峰,5月19日以后数量急剧减少;2010年麦蚜大量发生和高峰期出现的相对较晚,荻草谷网蚜在5月3日、5月7日、5月19日和5月31日出现4个高峰,5月31日以后蚜量才骤减。对白天不同时段诱捕的蚜量分析可知,麦蚜在早晨和傍晚飞翔活动相对较强。吸虫塔与黄色粘板监测的相关性分析表明,吸虫塔诱集麦蚜的数量动态与黄板诱集的数量动态趋势基本一致,吸虫塔诱蚜量与黄板蚜量具有较好的相关性,但吸虫塔诱集麦蚜出现高峰期早于黄色粘板。     

Spatial distribution of Aphis glycines (Hemiptera: Aphididae): a summary of the suction trap network

The soybean aphid, Aphis glycines Matsumura (Hemiptera: Aphididae), is an economically important pest of soybean, Glycine max (L.) Merrill, in the United States. Phenological information of A. glycines is limited; specifically, little is known about factors guiding migrating aphids and potential impacts of long distance flights on local population dynamics. Increasing our understanding of A. glycines population dynamics may improve predictions of A. glycines outbreaks and improve management efforts. In 2005 a suction trap network was established in seven Midwest states to monitor the occurrence of alates. By 2006, this network expanded to 10 states and consisted of 42 traps. The goal of the STN was to monitor movement of A. glycines from their overwintering host Rhamnus spp. to soybean in spring, movement among soybean fields during summer, and emigration from soybean to Rhamnus in fall. The objective of this study was to infer movement patterns of A. glycines on a regional scale based on trap captures, and determine the suitability of certain statistical methods for future analyses. Overall, alates were not commonly collected in suction traps until June. The most alates were collected during a 3-wk period in the summer (late July to mid-August), followed by the fall, with a peak capture period during the last 2 wk of September. Alate captures were positively correlated with latitude, a pattern consistent with the distribution of Rhamnus in the United States, suggesting that more southern regions are infested by immigrants from the north.     

Factors associated with winged forms of soybean aphid and an examination of North American spatial dynamics of this species in the context of migratory behaviour

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THE COMPARISON OF YELLOW CYLINDRICAL, FLAT AND WATER TRAPS, AND OF JOHNSON SUCTION TRAPS, FOR SAMPLING APHIDS

Different traps were compared to find the type most suitable for studying aphid vectors of plant viruses quantitatively.
A Moericke water trap caught more aphids than a flat sticky trap of equal area. A flat sticky trap (930 sq. cm.) caught half as many aphids as a cylindrical trap (945 sq. cm.), which caught about one-third as many as a water trap (1200 sq. cm.) or a Johnson suction trap (9 in. fan) when operated at between 2 and 3 ft. over bare soil.
Yellow traps caught proportionally more Tuberculoides annulatus , and in summer more Capitophorus species than a suction trap, but significantly fewer Anoecia corni, Sitobium spp. and Pemphigus bursarius. Traps with a level surface caught proportionally more Brevicoryne brassicae, Aphis fabae and Myzus persicae , but fewer Anoecia corni and Drepanosiphum plantanoides than vertical cylindical traps. Attraction by colour influences the catch on horizontal traps more than on cylindrical traps because there is less impaction by the wind.
Only suction traps indicate the number of aphids per unit volume of air and are non-selective, but they are expensive and require an electric power supply. Water traps effectively catch those aphids that are attracted to yellow, but they require frequent attention. Sticky traps catch fewer aphids than either suction or water traps, but they can be left unattended for about 2 weeks. Flat sticky traps catch aphids likely to land on a crop, and cylindrical traps show when aphids are in the air, but not if those aphids are able or wanting to land. For routine work cylindrical sticky traps have other advantages; they are cheap and do not require skilled handling, and their catches of alate Myzus persicae have been correlated with the spread of some plant viruses.     

马铃薯-大豆、玉米-大豆邻作对大豆田主要刺吸式害虫以及其他害虫的种群动态影响

【目的】大豆蚜Aphis glycines(Matsumura)是危害我国大豆产量的重要刺吸式害虫,茄无网蚜Acyrthosiphon solani(Kaltenbach)是近年来在大豆田发生逐渐呈上升趋势的刺吸式害虫,蚜虫的发生动态严重影响大豆的产量和品质,本试验调查了马铃薯-大豆、玉米-大豆邻作种植模式对大豆田刺吸式害虫及其他主要害虫的种群动态的影响,为精准使用农药防控蚜虫提供依据。【方法】采用系统调查的方法,研究大豆田刺吸式害虫以及天敌的种群动态,在哈尔滨香坊农场进行马铃薯-大豆、大豆-玉米邻作的种植模式,对其大豆田中大豆蚜、茄无网蚜等刺吸式口器的害虫及天敌动态发生数量进行调查。【结果】2014年与2015年玉米-大豆、马铃薯-大豆种植模式的大豆田中的大豆蚜数量明显低于对照田,2014年玉米-大豆差异更显著,2015年马铃薯-大豆差异性显著。2014年与2015年玉米-大豆、马铃薯-大豆邻作种植模式的大豆田中的茄无网蚜数量显著低于对照田。而2014年8月温度低于2015年虫量相对高于2015年,虫量高时天敌总群动态也相对较高,达到调控作用。【结论】玉米-大豆、马铃薯-大豆邻作种植模式能够起到减少大豆蚜和茄无网蚜的为害的作用,并能够减少农药的使用量。     

Interannual dynamics of aerial and arboreal green spruce aphid populations

Partial defoliation of spruce by the green spruce aphid Elatobium abietinum (Walker) is a recurrent event in European and, increasingly, North American forests. The patterns of insect abundance on trees have never been satisfactorily described by a numerical model despite considerable knowledge of endogenous and exogenous factors in the population dynamics of the species. Long-term field population estimates of the aphid on foliage provided the opportunity to evaluate such a model. Unlike comparable models for tree-dwelling aphids, this was also applicable to almost completely independent aphid field data derived from the Rothamsted Insect Survey’s nationwide network of suction traps. Although based on relatively few parameters, the model was robust in its predictions of alate aphids geographically remote from the forest in which the original population was estimated. The population maximum, which causes the greatest forest damage, is reached in early summer and can be predicted from knowledge of winter temperature (chill bouts), spring temperature (thermal sum), and interannual negative feedback (density dependence). The model provides confirmation that alate populations of spruce aphids, upon which a number of other extensive studies have been based, are ultimately influenced by similar endogenous and climatic factors and that they are a reasonable proxy for aphids on trees.     

Seasonal phenology of Aphis glycines (Hemiptera: Aphididae) and other aphid species in cultivated bean and noncrop habitats in Wisconsin

The occurrence of aphid-transmitted viruses in agricultural crops of the Midwest and northeastern United States has become more frequent since the arrival and establishment of the soybean aphid, Aphis glycines Matsumura (Hemiptera: Aphididae). A. glycines is a competent vector of plant viruses and may be responsible for recent virus epidemics in Wisconsin snap bean, Phaseolus vulgaris L., fields. To determine whether vegetation surrounding crop fields could serve as sources of virus inocula, we examined the settling activity ofA. glycines and other aphid species in agricultural crops and noncrop field margins adjacent to snap bean fields. Noncrop field margins were made up of numerous virus-susceptible plant species within 10 m from snap bean field edges. During summers 2006 and 2007, horizontal pan traps were placed in commercial soybean [Glycine max (L.) Merr.], snap bean, and surrounding field margins to characterize aphid flight activity patterns in the different habitat types. Alate abundance and peak occurrence across years varied between crop and noncrop field margins and differed among patches of plants in field margins. Overall aphid activity peaked late in the season (21 August in 2006 and 28 July in 2007); with the majority (52%) of total aphids trapped in all habitats being A. glycines. Susceptibility to viral infection and confirmed visitation of A. glycines to these forage plants suggests the importance ofnoncrop habitats as potential sources of primary virus inoculum. Viral disease onset followed peak aphid flights and further implicates A. glycines as a likely vector of viruses in commercial bean and other crops in Wisconsin.     

Migration of alate morphs of the bird cherry aphid (Rhopalosiphum padi) and implications for the epidemiology of barley yellow dwarf virus

Suction trapping data indicate three periods of migration of Rhopalosiphum padi in spring, summer and autumn. Four alate morphs are present at different times during the year. A comparison of data from suction traps operating at 12·2 and 1·5 m suggests a different behaviour of females in autumn with more being recorded at 12·2 than 1·5 m. Males, which are only present in autumn, were also more numerous at 12·2 m. During tests to measure barley yellow dwarf virus (BYDV) infectivity, only 9% of female R. padi reproduced on oat seedlings in autumn compared with 74% in summer. Tests on alate female R. padi trapped alive showed that in summer all were exules, but during the first half of September these were largely replaced by gynoparae so that in autumn only 5% of all R. padi trapped at 12·2 m were alate exules. The aerial densities of gynoparae and males were 10 times greater at 12·2 than 1·5 m while densities of alate exules were similar at both heights. It is suggested that gynoparae and males fly higher to increase the chance of finding a taller dispersed host plant. The implications for BYDV epidemiology of the behaviour and presence of the various R. padi alate morphs indicate that autumn-sown cereals emerging before mid-September are particularly at risk from colonisation by alate exules before the transition to a mainly sexual migrant population is complete. Alate exules introduce BYDV from comparatively local sources. The ratio of total R. padi to Sitobion avenae in suction trap samples in autumn usually exceeds 100: 1, but on crops it was only 10: 1. The ratio of alate exule R. padi to S. avenae in suction traps in autumn was only 12: 1, similar to that observed on crops.