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设置不施肥(A)、100%氮肥(B)、75%氮肥/25%花生饼肥(C)、50%氮肥/50%花生饼肥(D)、25%氮肥/75%花生饼肥(E)及100%花生饼肥(F),共6组处理,基于高通量测序技术,分析番茄植株根际土壤及根系内生细菌多样性,探讨氮肥/花生饼肥不同配比处理对番茄根际土壤及根系内生细菌群落结构的影响,为番茄的平衡施肥提供理论依据。结果表明:与不施肥(A)相比,不同施肥处理的根际土壤优势细菌门分类组成的占比发生了改变;单一的氮肥和饼肥处理均导致番茄植株内生细菌优势细菌门的数量减少;与不施肥(A)相比,不同施肥处理改变了番茄根际土壤和根系内生细菌中优势细菌属的组成和占比。B处理或F处理条件下,假单胞菌属(Pseudomonas)、鞘脂菌属(Sphingobium)、泛菌属(Pantoea)、克雷伯氏菌属(Klebsiella)等优势菌属缺失,不仅不利于营造番茄植株根际土壤微环境健康,而且不利于植株抗性能力的提升;此外,单一的氮肥或饼肥处理,诱导了青枯菌属(Ralstonia)等病原细菌富集,并成为植株根系优势内生细菌属,不利于改良番茄植株根际土壤微环境和提高番茄植株抗性;25%氮肥和75%饼肥处理是改良番茄植株根际土壤微环境以及提高番茄植株抗性的最佳施用配比。 相似文献
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不同水肥管理对日光温室番茄生长、产量及经济效益的影响 总被引:1,自引:0,他引:1
在日光温室条件下,研究不同灌溉方式下施用不同种类、不同用量的有机物料对番茄生长及产量的影响。结果表明,不同水肥处理番茄植株缓苗期生长缓慢,定植后32 d开始快速生长,定植后115 d,FIF+OM处理植株最高,FIF+OM+S处理植株最低,且二者差异达到显著水平。FIF+OM处理的叶片数最多,显著高于其他处理。番茄植株茎的生长主要集中在前期,定植79 d后茎粗基本不再变化,其中,DIF+OM处理最粗,其次是FIF+OM处理。番茄产量呈S型增长曲线,定植后136 d膜下沟灌开始采摘,第158天进入采摘高峰期,膜下滴灌处理滞后1周左右,DIF+OM处理的番茄产量最高,比FIF+OM处理番茄增产19.89%。膜下滴灌处理的水分生产力、氮肥偏生产力远高于膜下沟灌处理,DIF+OM处理的水分生产力最高,达到FIF+OM处理的1.6倍,DIF+HOM+1/2S处理的氮肥偏生产力最高,达到FIF+OM处理的2.6倍。从经济效益来看,DIF+OM处理产值最高,为32.25万元/hm2,相对净产值为28.42万元/hm2,比FIF+OM处理增加近6万元/hm2。 相似文献
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大蒜秸秆对番茄根结线虫病及根际微生态的影响 总被引:7,自引:1,他引:6
【目的】研究土壤添加大蒜秸秆对番茄根结线虫病及根际微生态的影响,旨在探明大蒜秸秆对植物、根结线虫病和根际微环境的综合效应,为合理开发大蒜秸秆资源提供理论依据和技术支撑。【方法】试验设置土壤添加0(CK)、1%(T1)、2%(T2)、4%(T3)和8%(T4)共5个大蒜秸秆添加浓度(w/w)。于日光温室中采用装有5 kg田园土的花盆(直径20 cm,深20 cm)进行番茄幼苗培养,缓苗后于番茄幼苗周围打洞接种南方根结线虫二龄幼虫(5 000 J2/株)。每30盆作为一个处理,培养温度控制在白天/夜晚为28—32℃/15—23℃。于处理10、30和50 d后取番茄根系样品,并采用抖动法收集根际土壤样品,测定番茄植株的生物量;统计根结线虫数、雌虫数、雌虫比例、卵块数、卵粒指数、繁殖系数、根结指数等病情指数和相对防治效果;分析根际土壤中的脲酶、磷酸酶、蔗糖酶、纤维素酶、过氧化氢酶和多酚氧化酶等主要土壤酶活性;测定根际土壤中的细菌、真菌和放线菌的数量,以及植食性线虫、食细菌线虫、食真菌线虫和杂食捕食性线虫等不同营养类群的土壤线虫数。【结果】随着大蒜秸秆施用量的增加,番茄植株的生物量呈现先增加后降低的趋势。其中,T1处理略高于CK,而T2处理略低于CK。相对防治效果随着大蒜秸秆施用量的增加呈现递增趋势,分别达到13.6%、50.0%、72.7%和81.8%;土壤添加大蒜秸秆显著降低了根结线虫二龄幼虫向雌虫分化的比例,并降低其卵块数、卵粒指数和繁殖系数。土壤添加大蒜秸秆降低了根际土壤尿酶和磷酸酶活性,但提高了纤维素酶、蔗糖酶、过氧化氢酶和多酚氧化酶的活性。另外,土壤添加大蒜秸秆可显著增加根际土壤中细菌、真菌和放线菌的数量。其中,细菌数随着大蒜秸秆施用量的增加呈现先增后减的趋势,其峰值出现在T2处理;而真菌和放线菌则随着大蒜秸秆施用浓度的增加呈现递增趋势。土壤引入大蒜秸秆后,植食性线虫数量随着施用浓度的增加呈现递减趋势;同一浓度下,植食性线虫数随着施用时间的延长呈现递增趋势。而食细菌、食真菌和杂食捕食性线虫数量则随着大蒜秸秆施用量的增加呈现先增后减的趋势;相比之下,食真菌线虫数增幅相对较小。【结论】综合考虑大蒜秸秆对番茄旺盛生长期的植株生长、根结线虫病防控和根际微生态的影响,以T2处理(2%)的大蒜秸秆添加量较为适宜。 相似文献
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<正>覆膜沟灌施肥技术是在地膜覆盖栽培技术的基础上发展起来的一种灌溉施肥方法。它是将地膜平铺于沟中,沟全部被地膜覆盖,水肥混合液从膜上(膜上沟灌)或膜下(膜下沟灌)输送到田间的灌溉施肥方法。技术特点及适用条件覆膜沟灌施肥适用于小高畦宽窄行种植作物,如茄果类蔬菜等。包括膜上沟灌施肥(适宜偏砂质土壤)、膜下沟灌施肥(适宜于偏黏质土壤)。 相似文献
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水肥对番茄产量、品质和水分利用率的影响及综合评价 总被引:2,自引:0,他引:2
【目的】优化设施番茄水肥一体化灌溉施肥制度。【方法】以"金棚1号"番茄为试材,在2013年研究总结的水肥总量(灌水量2 518.74m~3/hm~2,N 542.58kg/hm~2,P_2O_5206.30kg/hm~2,K_2O 940.03kg/hm~2)基础上,上下浮动30%后,设置T1(中水中肥)、T2(中水低肥)、T3(中水高肥)、T4(低水中肥)、T5(高水中肥)5个处理,以传统沟灌为对照,在滴灌条件下研究不同水肥对番茄产量、品质和水分利用效率的影响,并用模糊综合评价方法,通过赋予客观权重和主观权重后得到综合权重,对不同水肥处理下番茄综合品质、产量和水分利用效率进行综合评价。【结果】试验结果表明:在一定范围内番茄产量随水肥用量的增加先增高后降低;水分利用效率随灌水量的增加呈下降趋势,合理施肥有利于水分利用效率的提高;中水中肥和低水中肥条件下番茄综合品质较好,水分或肥料过多均会造成番茄品质下降;T1处理的综合表现最优,产量最高,为130.80t/hm2,品质较好,水分利用率较高,为51.90kg/m3;与沟灌对照(产量115.40t/hm~2,水分利用效率23.46kg/m~3)相比,T1处理产量、水分利用效率分别提高了13.34%,121.23%。【结论】利用综合评价法得出的设施番茄水肥一体化最优水肥用量为灌水量2 518.74m~3/hm~2,N 542.58kg/hm2,P_2O_5206.30kg/hm~2,K_2O 940.03kg/hm~2。 相似文献
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在设施番茄栽培条件下,采用田间小区试验,设不施氮(CK)、常规施氮(FP)、氮肥减量28.6%(OPT)和氮肥减量28.6%+秸秆反应堆(OPTS) 4个处理,研究减氮和秸秆反应堆对设施番茄产量、氮素利用、果实品质及土壤硝态氮累积的影响。结果表明:与FP施肥处理相比,减氮条件下OPT和OPTS处理番茄产量分别提高10.7%和15.6%,其中OPTS处理显著提高。与FP处理相比,OPT处理番茄氮吸收总量和氮肥利用率分别提高0.40%和4.48%, OPTS处理分别提高5.57%和7.64%;与FP处理相比,OPT和OPTS处理果实硝酸盐分别显著降低35.2%和39.7%,维生素C含量分别显著提高27.1%和29.0%。相对于常规施肥处理0-100 cm土壤NO-3-N总累积量652.8 kg·hm-2, OPT和OPTS处理土壤剖面NO-3-N总累积量分别显著减少26.3%和46.5%。综合考虑经济和环境效益,常规施肥基础上减氮28.6%结合秸秆反应堆效果最佳。 相似文献
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为探究华北平原冬小麦水肥一体化节水高产种植模式,以泰科麦33和山农29小麦品种为试验材料,于2017—2018年冬小麦生育期进行大田试验。试验以常规施肥沟灌处理为对照(F1),设置F2、F3、F4水肥一体化3个处理,对冬小麦群体动态变化、株高和产量进行测定。结果表明,水肥一体化条件下施氮量225kg/hm~2有利于增加春季冬小麦最大分蘖数及株高。同时,水肥一体化条件下施氮量225 kg/hm~2提高了泰科麦33的穗数和穗粒数和山农29的穗数和千粒重,从而显著提高冬小麦产量。 相似文献
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不同灌溉施肥模式对温室番茄产量、品质及水肥利用的影响 总被引:5,自引:2,他引:3
【目的】建立适用于日光温室番茄水肥一体化的管理模式,探讨不同灌溉施肥模式在日光温室番茄节水节肥增产效能上的差异。【方法】基于负压装置和滴灌系统,研究常规施基肥(CK)、营养液滴灌施肥(DI)和负压供液施肥(NI)对温室番茄产量、品质及水肥利用效率的影响。【结果】负压供液施肥模式下土壤水分具有相对的稳定性,0—20 cm土层含水量周年变化幅度为20.8%—25.0%,低于滴灌施肥处理的19.7%—28.6%。基于负压装置的供液模式(NI)相对于处理CK和DI,不但养分(N+P_2O_5+K_2O)的周年总投入量分别降低了5.0%和17.2%,而且显著促进了番茄植株生长,增加了产量,改善了果实品质。其中处理NI与CK相比,番茄生物量提高了23.0%以上(P0.05),产量增加了7.5%—10.0%,而与处理DI相比,果实硝酸盐含量降低了17.3%—21.5%(P0.05)。负压供液施肥模式能够减少水肥用量,降低温室番茄周年耗水量,提高水肥利用率。与处理CK和DI相比,处理NI的年灌水量分别减少了18.4%和17.2%,番茄年耗水量分别降低了12.8%和12.1%(P0.05),而水分利用效率分别提高了12.7%—40.1%和10.0%—30.3%(P0.05),肥料偏生产力则分别提高了10.4%—19.6%和14.5%—42.7%(P0.05)。水分的持续稳定供给是负压供液施肥模式实现节水节肥增产保质等效能的重要原因。【结论】基于负压装置的供液模式不仅减少了水肥的投入量,而且能够促进温室番茄生长、确保产量,同时改善了果实品质并大幅度提高了水肥利用效率,可作为日光温室番茄水肥一体化管理的新模式。 相似文献
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水肥管理对土壤盐分、硝态氮分布及番茄产量和品质的影响 总被引:2,自引:0,他引:2
为探索盐碱地番茄一垄双行种植条件下的高效水肥管理模式,改善番茄品质,以当地习惯灌水施肥为对照,通过田间试验,开展不同灌溉方式下水肥减量对土壤盐氮分布、番茄产量和水分利用效率的影响。结果表明,土壤盐分含量随着施肥量的增加而增加,低水条件下的土壤盐分含量略高;土壤耕层硝态氮含量随着施肥量的增加而增加,随着灌水量的增加而降低。不同水量交替灌溉方式下,0~20 cm土层土壤硝态氮含量均高于常规灌溉,而40~60 cm土层土壤硝态氮含量则低于常规灌溉。与对照相比,常规沟灌方式下,中水高肥和中水中肥处理下的番茄产量最高,番茄产量分别增加了2.53%和2.02%,低灌水量下的番茄田灌溉水利用效率大于30%,但产量下降了9.60%以上;不同水量交替沟灌方式下,高水低水交替灌溉配施高肥处理下的番茄产量最高,番茄产量增加了1.58%,水分利用效率增加了23.97%,而中水低水交替灌溉配施中肥处理下的灌溉水利用效率最高,水分利用效率增加了36.80%,而产量并没有降低,该处理下番茄品质也有了明显改善。对一垄双行番茄田种植方式而言,采用中水低水交替灌溉配施中肥的水肥管理模式是一种可行的节水提质措施。 相似文献
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以高垄覆膜水肥一体化技术(FG+H)为试验处理,膜下沟灌(FP)为对照,通过田间试验研究了高垄覆膜水肥一体化技术对设施土壤理化性状及蔬菜产量的影响。结果表明,定植后26 d~55 d, FG+H处理明显提高了20 cm处地温;定植后118 d~154 d,5 cm、10 cm、15 cm、20 cm、25 cm处地温均低于FP。FG+H处理的表层土壤饱和导水率明显提高,是FP的2.2倍。FG+H处理可明显降低0~60 cm土壤硬度,而对土壤容重无明显影响。FG+H处理0~20 cm土壤全氮、有效P、速效钾、有机质含量比FP分别提高18.4%、47.6%、34.9%和20.9%,且明显降低了0~200 cm土壤剖面硝态氮含量。FG+H处理相对FP有缓解土壤酸化和盐化的趋势。FG+H处理番茄采收期相对FP推迟约10 d左右,但FG+H处理番茄总产量相对FP提高了19.9%。本研究结果表明,FG+H处理不仅明显改善了设施土壤理化性状,而且番茄产量也明显提高。 相似文献
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Effect of fertigation frequency on soil nitrogen distribution and tomato yield under alternate partial root-zone drip irrigation 
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下载免费PDF全文 FENG Xu-yu PU Jing-xuan LIU Hai-jun WANG Dan LIU Yu-hang QIAO Shu-ting LEI Tao LIU Rong-hao 《农业科学学报》2023,22(3):897-907
Alternate partial root-zone drip fertigation (ADF) is a combination of alternating irrigation and drip fertigation, with the potential to save water and increase nitrogen (N) fertilizer efficiency. A 2-year greenhouse experiment was conducted to evaluate the effect of different fertigation frequencies on the distribution of soil moisture and nutrients and tomato yield under ADF. The treatments included three ADF frequencies with intervals of 3 days (F3), 6 days (F6) and 12 days (F12), and conventional drip fertigation as a control (CK), which was fertilized once every 6 days. For the ADF treatments, two drip tapes were placed 10 cm away on each side of the tomato row, and alternate drip irrigation was realized using a manual valve on the distribution tapes. For the CK treatment, a drip tape was located close to the roots of the tomato plants. The total N application rate of all treatments was 180 kg ha–1. The total irrigation amounts applied to the CK treatment were 450.6 and 446.1 mm in 2019 and 2020, respectively; and the irrigation amounts applied to the ADF treatments were 60% of those of the CK treatment. The F3 treatment resulted in water and N being distributed mainly in the 0–40-cm soil layer with less water and N being distributed in the 40–60-cm soil layer. The F6 treatment led to 21.0 and 29.0% higher 2-year average concentration of mineral N in the 0–20 and 20–40-cm soil layer, respectively and a 23.0% lower N concentration in the 40–60-cm soil layer than in the CK treatment. The 2-year average tomato yields of the F3, F6, F12, and CK treatments were 107.5, 102.6, 87.2, and 98.7 t ha–1, respectively. The tomato yield of F3 was significantly higher (23.3%) than that in the F12 treatment, whereas there was no significant difference between the F3 and F6 treatment. The F6 treatment resulted in yield similar to the CK treatment, indicating that ADF could maintain tomato yield with a 40% saving in water use. Based on the distribution of water and N, and tomato yield, a fertigation frequency of 6 days under ADF should be considered as a water-saving strategy for greenhouse tomato production. 相似文献
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While fertigation can increase fertilizer use efficiency, there is an uncertainly as to whether the fertilizer should be introduced at the beginning of the irrigation or at the end, or introduced during irrigation. Our objective was to determine the effect of different fertigation schemes on nitrogen (N) uptake and N use efficiency (NUE) in cotton plants. A pot experiment was conducted under greenhouse conditions in year 2004 and 2005. According to the application timing of nitrogen (N) fertilizer solution and water (W) involved in an irrigation cycle, four nitrogen fertigation schemes [nitrogen applied at the beginning of the irrigation cycle (N-W), nitrogen applied at the end of the irrigation cycle (W-N), nitrogen applied in the middle of the irrigation cycle (W-N-W) and nitrogen applied throughout the irrigation cycle (N&W)] were employed in a completely randomized design with four replications. Cotton was grown in plastic containers with a volume of 84 l, which were filled with a clay loam soil and fertilized with 6.4 g of N per pot as unlabeled and 15N-labeled urea for 2004 and 2005, respectively. Plant total dry matter (DM) and N content in N-W was significantly higher than in N&W in both seasons, but these were not consistent for W-N and W-N-W treatments. In year 2005, a significantly higher nitrogen derived from fertilizer (NDFF) for the whole plant was found in W-N and N-W than that in W-N-W and N&W. Fertigation scheme had a consistent effect on total NUE: N-W had the highest NUE for the whole plant, but this was not significantly different from W-N. Treatments W-N and W-N-W had similar total NUE, and N&W had the lowest total NUE. After harvesting, the total residual fertilizer N in the soil was highest in W-N, lowest in N-W, but this was not significantly different from N&W and W-N-W treatments. Total residual NO3-N in the soil in N&W and W-N treatments was 20.7 and 21.2% higher than that in N W, respectively. The total 15 N recovery was not statistically significant between the four fertigation schemes. In this study, the fertigation scheme N-W (nitrogen applied at the beginning of an irrigation cycle) increased DM accumulation, N uptake and NUE of cotton. This study indicates that Nitrogen application at the beginning of an irrigation cycle has an advantage on N uptake and NUE of cotton. Therefore, NUE could be enhanced by optimizing fertilization schemes with drip irrigation. 相似文献
16.
【目的】水肥管理是设施栽培蔬菜高产高效的关键技术,研究不同灌溉施肥方式对日光温室土壤性状及蔬菜生育的影响,为高效水肥管理及防控土壤次生盐渍化提供理论指导。【方法】在日光温室中以黄瓜品种‘新津11’为试材,设置传统畦灌定期冲肥(CK1)、常规滴灌定期追肥(CK2)、每天定量滴灌1/4剂量山崎黄瓜专用配方营养液不加微量元素(T1)、每天定量滴灌1/4剂量专用配方营养液加微量元素(T2)、每天定量滴灌2/4剂量专用配方营养液加微量元素(T3)、每天定量滴灌3/4剂量专用配方营养液加微量元素(T4)6个处理,研究不同灌溉施肥方式对土壤理化、生物学性状以及黄瓜产量和品质的影响。【结果】与传统畦灌定期冲肥和常规滴灌定期追肥相比,每天定量滴灌营养液处理的土壤容重减小,孔隙度增大,EC值降低;土壤真菌数显著减少,细菌和放线菌数明显增多,脲酶、转化酶和过氧化氢酶活性增强;黄瓜植株生长量增大。与传统畦灌定期冲肥和常规滴灌定期追肥相比,每天滴灌1/4剂量山崎专用配方+微量元素的处理黄瓜单株结瓜数和产量最高,并可部分改善果实品质,且节水、节肥率分别达到30%和70%以上。【结论】每天定量滴灌1/4剂量山崎黄瓜专用配方加微量元素营养液可以推荐作为日光温室土壤栽培黄瓜的一种新型水肥管理模式。 相似文献
17.
为了研究不同种类秸秆发酵物对设施蔬菜根区温度及CO2释放的影响,在日光温室内以番茄为供试材料,设置未填埋秸秆(CK)、水稻秸秆(T1)、玉米秸秆(T2)、番茄秸秆(T3)及豇豆秸秆(T4)共5个处理,以垄沟填埋的方式施入土壤,检测冬季土垄内嵌式基质栽培番茄的根区温度、CO2释放及番茄生长指标变化。结果表明:与CK相比,4个秸秆处理均能不同程度地提高日光温室根区温度和填埋区CO2释放量,促进番茄生长。其中,番茄秸秆(T3)效果最好,其根区温度的最低值和最高值分别较CK提高了2.42和2.03 ℃,CO2释放量的最低值和最高值分别较CK提高了276和387 mg·m-3,并促进了番茄的生长,主要表现在提高了番茄的株高、茎粗、叶片数和叶片叶绿素SPAD值。因此,在日光温室蔬菜生产中,使用以番茄秸秆为主的垄沟填埋物料的方式具有更好的应用前景。 相似文献
18.
Irrigation combined with fertigation has produced unquestionable results for the last few decades. It is a rather complicated process as many factors must be controlled in order to produce good and environmentally safe fertigation practices. The efficiency and uniformity of irrigation, as well as the balance of the nutritive solution used to irrigate are highly ruled by the complex and diverse information (weather, soil, water, and crop data). The article presents the rationale and structure of a decision support system (DSS) and of a Fertigation module (FS – Fertigation Simulator). The DSS-FS system is intended to support design and optimization of irrigation and fertigation systems while increasing their environmental sustainability. The data set to be processed is stored in the DSS database and can be continuously updated according to new development results. Afterwards, the user might handle the input data through a basic and user-friendly interface while allowing the DSS-FS to retrieve default scenarios and thereby reducing the systems user’s need for advanced knowledge. An advanced mode of DSS-FS, which adds an increased level of precision in exchange for human support, includes soil sample analysis and other relevant information. 相似文献
19.
土壤调理剂对日光温室土壤改良效果的研究 总被引:1,自引:0,他引:1
土壤调理剂改良土壤结果析表明:土壤调理剂可改善宁夏灌淤土日光温室土壤结构,增加土壤有效养分,降低pH0.08;促进番茄生长发育,提高外观品质,增加产量7.9%。 相似文献