甘肃陇南市核桃病害调查及重要病害综合防治

[目的]为明确甘肃陇南地区核桃病害种类及重要病害的病原、为害特点、发生规律及综合防治策略[方法]通过采用踏查和五点取样对8县1区核桃主产区进行调查.[结果]发现为害核桃的病害8种,其中黑斑病、炭疽病、褐斑病和膏药病4种发生程度为重度.并对引起4种重要病害的病原、为害特点、发生规律及综合防控技术做了阐述.[结论]以期实现...     

氮、钾用量对机采加工番茄果实成熟、产量及品质的影响

为探索适合新疆地区膜下滴灌机械采收加工番茄的施肥规律,研究不同氮肥(N)、钾肥(K)及交互作用(N×K)对机械采收加工番茄果实成熟、产量及品质的影响,设置氮肥和钾肥二因素随机区组试验,设计9个处理,3次重复。结果表明不同N、K用量及其互作对加工番茄果实物质积累量、单果质量、果实红熟率、产量、可溶性固形物含量、番茄红素含量影响显著,对果实叶绿素含量、β-胡萝卜素含量、L值影响不显著。N₂K₂、N₂K₃、N₃K₂条件下加工番茄产量≥16.12×10⁴kg·hm^-2、成熟度≥93.29%、果实固形物含量≥5.22%、番茄红素含量≥21.38mg·hg^-1,可满足机械采收对加工番茄的要求。通过经济效益分析推荐施肥量为N 152.1 kg·hm^-2,K₂O 118.2kg·hm^-2。     

单生育期水分胁迫对温室葡萄根际土壤酶活性及微生物群落的影响

为明确单生育期水分胁迫对土壤酶活性和微生物群落结构的影响,选取5a生'红地球'鲜食葡萄为试验材料,采用单因素完全随机试验设计,以全生育期充分供水为对照(CK),依次在葡萄5个生育期分别设置轻度(M)和重度(S)两个水分胁迫水平进行大田试验,利用Illumina高通量测序技术分析土壤微生物的群落构成和多样性.结果表明:葡...     

贵州无公害番茄栽培专家系统的开发研究

贵州无公害番茄栽培专家系统是基于PAID 4.0开发平台研制的。系统将人工智能与番茄栽培领域专家的知识结合起来,模拟农业专家指导农户进行无公害番茄栽培,具有技术先进、功能丰富、结构规范、界面友好、易学实用等特点,可有效地解决目前贵州无公害番茄生产中专家型农业科技人员的短缺问题,为农业科技咨询服务提供新途径。     

不同叶背补光模式对戈壁温室番茄品质的影响

[目的]研究南疆戈壁日光温室内不同叶背补光模式对番茄果实品质的影响,以获得适合该地区设施番茄生产的经济最适补光模式.[方法]以NS3389番茄作为材料,LED为补光光源,于08:00～22:00期间内,以无补光处理为空白对照(CK),并设置3种叶背补光模式:T1,100μmol/(m2·s)持续补光;T2,揭帘之前与盖...     

设施番茄灰霉病气象指标及其生态防治措施

设施番茄灰霉病是由气象因子影响的一种重危害、高损失的真菌性病害。通过多年的观测调查发现：当连续10日及以上设施内日平均气温≥14.8℃、相对湿度≥90%、出现连阴或者连续多云寡照天气时,番茄就会出现灰霉病。番茄灰霉病不仅会导致番茄果实腐烂落果,造成减产甚至绝产,还会影响番茄品质。结合病虫害防治调查及农业气象试验,提出了选用抗病毒品种、改善设施内气象条件等减少番茄灰霉病发生的生态防控措施。     

玉米秸秆分解过程中细菌群落组成演化特征

【目的】土壤中存在着大量的分解秸秆的微生物。研究秸秆分解过程中细菌群落组成的演化规律,对了解和调控农田微生物群体组成以促进秸秆分解具有重要意义。【方法】试验于2014年10月至2015年10月在河南省农业科学院原阳试验基地进行,将成熟期玉米秸秆(茎和叶)烘干,剪成长1~2 cm、宽0.3~1 cm的碎片,称12 g样品(相当于8 t/hm^2)装入15 cm×10 cm的尼龙网包(孔径0.04 mm)内,于10月5日冬小麦出苗后埋置在小麦垄间。分别于埋置后0、1、2、4、7、10和12个月收集秸秆包和土壤样品。测定秸秆样品干物质量和碳氮含量,选择埋置了0、2、4、7和12个月的秸秆及其土壤样品分析细菌丰度及群落组成。【结果】秸秆埋入土壤后的前2个月内分解最快,然后逐步减慢,在1、2、4、7、10和12个月后分别降解了总生物量的19.2%、32.9%、44.2%、52.2%、66.8%和73.8%。秸秆埋入土壤后,秸秆和土壤中细菌丰度均显著增加,分别于第4和7个月达到最高后开始下降。秸秆细菌的丰度指标OTUs、ACE、Chao1和多样性指标Shannon随试验时间的延长逐步增加,而Simpson指数随试验时间延长逐步降低,而土壤中这些指标在试验过程中没有显著变化。与刚埋置秸秆时相比,埋置2个月后的秸秆细菌Bacteroidetes门相对丰度明显增加,主导细菌群为Bacteroidetes和Proteobacteria门。Actinobacteria丰度在埋置2个月后明显降低,然后又随试验时间延长逐步增加。Planctomycetes、Saccharibacteria、Verrucomicrobia、Acidobacteria、Chloroflexi和Gemmatimonadetes丰度在原始秸秆中较低,埋入土壤后随试验时间延长逐步增加。Sphingobacteriia、Gammaproteobacteria、Alphaproteobacteria和Flavobacteriia主导前期细菌纲组成,而Actinobacteria、Anaerolineae和Bacilli纲丰度在后期逐步增加。秸秆分解速率主要受其碳含量影响,秸秆细菌群落组成前期与秸秆碳含量相关,后期与秸秆氮含量相关。随着试验的进展,秸秆细菌群落组成与土壤中的细菌群落组成趋同。【结论】秸秆埋入土壤后前2个月的分解速率最高,随后逐步降低。秸秆分解前期细菌群落由富营养型组分Bacteroidetes和Proteobacteria门和Sphingobacteriia、Gammaproteobacteria、Flavobacteriia和Alphaproteobacteria纲主导,随后被逐步增加的贫营养型组分Actinobacteria、Acidobacteria、Chloroflexi、Saccharibacteria门和Deltaproteobacteria、Actinobacteria纲等代替。秸秆碳氮含量变化是影响秸秆分解及其过程中细菌群落演化的主要原因。     

红壤侵蚀区不同地层背景马尾松林土壤理化特性及细菌多样性

[目的] 揭示土壤理化特性与细菌丰度之间的内在关系,为红壤侵蚀区马尾松林水土流失分区精准治理提供参考。[方法] 以福建省长汀县红壤侵蚀区马尾松林为研究对象,选择侏罗系中统漳平组中段(J₂Z²)、侏罗系中统漳平组下段(J₂Z¹)、侏罗纪燕山期早期侵入岩(γ₅^{2(3) c})、第四系全新统(Q_h)4种地层背景,分析测定不同地层背景马尾松林土壤理化特性和细菌群落组成及多样性。[结果] 不同地层背景马尾松林土壤理化指标整体表现为：J₂Z¹＞J₂Z²＞Q_h＞γ₅^{2(3) c};土壤养分含量各地层背景各有丰缺,J₂Z¹地层背景土壤有机质含量大于其他地层,Q_h地层背景氮含量大于其他地层,而γ₅^{2(3) c}地层背景磷和钾含量较高;4种地层背景土壤细菌差异操作分类单元(OTU)数目表现为：Q_h＞J₂Z²＞J₂Z¹＞γ₅^{2(3) c},分别占总OTU数目的21.62%,18.29%,16.79%,12.08%;细菌群落多样性表现为：J₂Z²＞Q_h＞γ₅^{2(3) c}＞J₂Z¹;J₂Z¹地层和Q_h地层土壤细菌多样性与土壤含水率和土壤pH值正相关,J₂Z²地层与土壤容重以及全磷含量正相关,γ₅^{2(3) c}地层与土壤钾含量和速效氮含量正相关。[结论] 红壤侵蚀区不同地层背景马尾松林土壤理化特性存在一定差异,在植被恢复过程中应考虑地层背景因素进行分区治理,细菌对不同地层背景土壤性质具有一定指示作用。     

川西北不同沙化程度草地土壤细菌群落特征

研究川西北不同沙化程度草地（未沙化草地、轻度沙化草地、中度沙化草地、重度沙化草地）土壤细菌多样性和群落结构特征,利用Illumina二代高通量测序技术MiSeq对土壤细菌的16 SrRNA V₃—V₄可变区进行测序,研究土壤细菌多样性、物种组成和丰富度,并结合土壤理养分探讨影响细菌群落结构的环境因素,对发挥土壤潜在肥力,了解土壤健康状况,实现该区植被的管理与可持续利用有着重要的意义。结果表明:（1）不同沙化草地土壤养分具有明显差异,依次表现为:随着沙化程度的增加,土壤pH值逐渐增加,而土壤有机碳、全氮、全钾、碱解氮和速效磷逐渐降低;（2）不同沙化程度草地土壤样品中共检测到细菌的32个门,65个纲,169个目,优势菌门为变形菌门（Proteobacteria）、放线菌门（Actinobacteria）、酸杆菌门（Acidobacteria）、绿弯菌（Chloroflexi）、浮霉菌门（Planctomycetes）,主要的优势菌纲为放线杆菌纲（Actinobacteria）、α-变形菌纲（α-Proteobacteria）、酸杆菌纲（Acidobacteria）、β-变形菌纲（β-Proteobacteria）、浮霉菌纲（Planctomycetacia）,与沙化草地相比,未沙化草地优势菌主要是变形菌门（Proteobacteria）和放线菌门（Actinobacteria）;（3）随着沙化程度的增加,OUT数目、Chao指数、Ace指数、Shannon指数逐渐减小,其中不同沙化草地土壤细菌覆盖率和Simpson指数差异不显著（p > 0.05）;（4）冗余分析和Pearson相关性分析表明,土壤pH值、土壤有机碳（SOC）和全氮（TN）是土壤细菌群落结构和多样性的主要影响因子。     

Threshold of Soil Olsen-P in Greenhouses for Tomatoes and Cucumbers

Phosphorus (P) accumulation is a common phenomenon in greenhouse soil for vegetables. Excessive P accumulation in soil usually decreases the yield and quality of vegetables as well as potentially polluting water environments. Ninety-eight tomato and 48 cucumber greenhouses were investigated in the eight main vegetable production areas of Hebei Province, China. Soil Olsen-P, the electrical conductivity (EC), the pH value, the organic matter of the soil, and the cropping years of these greenhouses were investigated and analyzed in order to better understand the status of soil P accumulation and positively find effective ways to solve the excessive phosphate accumulation problem. The investigation showed that the ratio was above 70% for all of the greenhouses where the soil Olsen-P exceeded 90 mg·kg^?1 (upper bound of soil Olsen-P optimum value in greenhouse) in the 0–20 cm surface soil in the investigated greenhouses. There was a significant positive correlation between the soil Olsen-P content and the soil EC, between the soil Olsen-P and the cropping years, and the Olsen-P had a significant negative correlation with the soil pH value. It is concluded that supplying phosphate fertilizer excessively induced the soil EC to ascend and the pH value to descend, which increases the possibility of the soil secondary salinization and soil degeneration. The significant positive correlation between the soil organic content and the soil Olsen-P contents suggests that supplying organic fertilizer might mobilize soil residual phosphate. This also provides a good way to solve the problem of soil P accumulation. In order to further explore the threshold content of soil Olsen-P demanded by tomato and cucumber under the high soil Olsen-P condition, two tomato greenhouses (T1, T2) in Dingzhou and two cucumber greenhouses (C1, C2) in Wuqiang were researched. All of the greenhouses had ranges of soil Olsen-P content that were between 150 and 300 mg·kg^?1, which far exceeded the 90 mg·kg^?1 ideal. The P fertilizer application rates showed positive correlations with the soil Olsen-P contents and EC values in cucumber and tomato greenhouses in the current season. Analyzing T1 and T2 results showed that tomato was sensitive to the high soil Olsen-P contents ranging from 230.64 to 729.42 mg kg^?1 at the seedling stage (15 days after transplanting; DAT) and from 199.41 to 531.42 mg kg^?1 at the fruiting stage (90 DAT), because the yields correlated negatively with soil Olsen-P contents at each growth stage. It is suggested that the maximum soil Olsen-P threshold content for tomato should be lower than 230 mg·kg^?1 at the seedling stage and lower than 199 mg·kg^?1 at the fruiting stage. But cucumber yield did not change significantly as soil Olsen-P content rose from 248.75 to 927.62 mg kg^?1, 212.40 to 554.07 mg kg^?1, 184.48 to 455.90 mg kg^?1, and 128.42 to 400.96 mg kg^?1 at the seedling stage (15 DAT), early fruiting stage (50 DAT), middle fruiting stage (140 DAT), and late fruiting stage (235 DAT), respectively, suggesting that the maximal soil Olsen-P threshold content was lower than 249, 212, 185, and 128 mg·kg^?1 at each growth stage, respectively. The relationship between fruit qualities and soil Olsen-P contents at each growth stage was not evident. Activities of soil alkaline phosphatase (ALP) decreased as soil Olsen-P supply was raised in T1, T2, and C1 at the seedling stage. It is concluded that in an excess soil Olsen-P condition tomato yield decreases strongly as soil ALP activity decreases, whereas ALP activity has little direct effect on cucumber yield.