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1.
不同铁制剂与施用方法对矫正花生缺铁黄化症的效果 总被引:3,自引:0,他引:3
研究了在盆栽和田间小区试验条件下,叶面和土壤施用铁肥以及土施酸化肥料对纠正花生缺铁黄化症的作用效果。在盆栽条件下,叶面喷施黄腐酸铁(FeFA)、土施硫酸亚铁及酸化肥料都可以提高花生新叶中活性铁以及叶绿素含量,促进花生植株的生长;在田问小区栽培条件下,叶面喷施FeFA可以提高花生的叶绿素含量,尿素与FeFA结合使用的作用效果大于单喷FeEA。土施硫酸亚铁在花生生长前期提高了花生叶绿素含量,后期作用不明显。叶面喷施与土施铁肥都可以增加花生产量,土施铁肥的作用效果不如叶面喷施效果明显,酸化肥料对提高花生叶绿素含量及产量没有明显效果。 相似文献
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以缺铁的石灰性紫色土为供试土壤进行盆栽实验,选用三株慢生型花生根瘤菌Spr3 5、Spr3 7、Spr4 5及gusA和celB标记的菌株gusA3 5、gusA3 7、gusA4 5、celB3 5、celB3 7、celB4 5接种天府9号花生。通过标记根瘤菌形成的根瘤能与检测试剂产生颜色反应的特征,检测施铁肥及施不同浓度的铁肥对花生 根瘤菌有效性和竞争性的影响。结果发现:缺铁的石灰性紫色土上单施铁肥、单接种根瘤菌、接种根瘤菌配施铁肥均能促进花生与根瘤菌的共生固氮效应和竞争结瘤能力,但接种根瘤菌配施铁肥的效果最好,单接种根瘤菌的效果次之,单施铁肥的效果差。喷施0 .2 %硫酸亚铁溶液的效果比0 .3%的好。植株全氮含量和叶绿素含量都是指示共生固氮效应的重要指标,与花生产量间存在极显著的相关性,相关系数分别为0 .76 3和0 .795。gusA和celB两种标记方法检测的结果基本一致,两种标记根瘤菌的平均占瘤率分别为79.6 4 %、75 .6 2 %、74 .4 1%。供试菌株中Spr4 5的有效性和竞争性最强,Spr3 7次之,Spr3 5最差 相似文献
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海涂黄花梨叶片黄化现象系植株铁素缺乏所致。试验表明,主干注射浓度为0.3%硫酸亚铁营养液,黄花梨叶片叶绿素含量10 d后由0.306 mg.g-1FW增加到0.812 mg.g-1FW,在较短时间内使黄花梨叶片达到复绿效果;叶面喷施0.3%硫酸亚铁营养液,10 d后黄花梨叶片叶绿素含量由0.306 mg.g-1FW增加到0.626 mg.g-1FW,叶片复绿效果明显,但20 d后叶绿素含量有所下降,新抽出叶片还有黄化症状;土壤施铁肥短期内效果并不明显。不同施肥方式下,黄花梨叶片活性铁含量变化趋势与叶绿素变化趋势基本一致,叶片中活性铁含量与叶绿素含量有很好的正相关关系,相关系数为0.887 3。 相似文献
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为探究铁、锌不同浓度配施对藿香生长、产量及有效成分的影响,以藿香为试验材料,采用双因素随机区组设计,研究铁锌配施对藿香生长、产量、各部位铁锌分配及挥发油含量的影响。结果表明,叶面喷施铁锌肥能显著影响藿香的生长发育、产量和挥发油成分,显著影响藿香的抗氧化酶活性,显著提高淀粉、还原糖、可溶性糖和可溶性蛋白含量,通过影响氮代谢相关酶活性间接影响植株氮代谢过程。叶面施铁对藿香产量的影响大于叶面施锌,铁锌配施的增产效果优于单独施用铁、锌肥;综合考虑藿香的生长和产量指标,认为Fe1Zn1(0.2%铁,0.1%锌)为铁锌配施的最优处理组合。施用锌铁肥能够增加藿香各部位的铁锌含量,锌在不同部位的含量呈叶>根>茎的变化趋势,铁在不同部位的含量呈根>叶>茎的变化趋势,锌主要集中在藿香叶片,而铁则主要集中在藿香根部。高浓度的叶面施铁有助于叶片Ca含量的累积。铁锌配施能显著提高藿香挥发油含量,并影响挥发油成分,其中D-柠檬烯含量最高,在Fe1Zn2处理时达到最大值(22.99%)。综上,合理配施铁锌肥能提高藿香主要化学成分的含量,但过高浓度的施用增产效果并不明显。本研究结果为铁锌肥在藿香生产中的应用提供了理论依据。 相似文献
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施用硒、锌、铁对玉米和大豆产量与营养 总被引:3,自引:0,他引:3
采用黄土高原低硒区典型土壤,以玉米、大豆为供试作物,研究施用硒、锌、铁对作物产量和营养品质的影响。结果表明,仅施用氮、磷、钾肥料,玉米、大豆产量无明显变化,施用适量硒、锌、铁时,玉米产量明显提高15.6%~73.8%,大豆产量提高58.9%~115.1%。施用硒、锌、铁,玉米籽粒氮含量明显增加,而磷、钾含量无明显变化,大豆籽粒氮含量无明显变化,磷、钾含量有所下降。土施或结合叶面喷施硒、锌、铁时,玉米和大豆籽粒硒、锌、铁含量明显增加,尤其是土施结合叶面喷施硒、锌、铁时效果突出。与对照比较,玉米籽粒硒增加480.4%、锌增加106.9%、铁增加126.7%; 大豆籽粒硒增加512.9%、锌增加62.2%、铁增加15.6%。综合考虑玉米、大豆产量和籽粒硒、锌、铁含量变化,锌、硒适宜土壤施用,或土施结合叶面喷施施用,叶面喷施铁可有效提高作物籽粒铁含量。 相似文献
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铜基叶面肥及控释肥对辣椒生长发育和叶片保护酶等生理特性的影响 总被引:8,自引:2,他引:6
【目的】针对辣椒喜肥、耐肥、对水分要求严格的特点,采用铜基叶面肥、控释肥两种新技术,研究了叶面喷施铜基叶面肥和土施控释肥对辣椒产量、矿质养分在植株体内的分布、保护性酶活性以及果实品质的影响,为提高果蔬产量和改善品质提供理论依据。【方法】分别于2011年4~11月和2012年3~9月,在山东农业大学南校区土肥资源高效利用国家工程实验室新型肥料中试基地, 以赤峰牛角王为供试辣椒品种设置肥料盆栽试验,试验设8个处理: 1)喷清水土壤不施肥对照(CKW- NF);2)喷清水+土施普通肥(CKW+CCF); 3)喷清水+土施控释肥(CKW+CRF); 4)喷清水+土施控释肥+保水剂(CKW+CRF+W); 5)喷铜基叶面肥土壤不施肥(CBFF-NF); 6)喷铜基叶面肥+土施普通肥(CBFF+CCF); 7)喷铜基叶面肥+土施控释肥(CBFF+CRF);8)喷铜基叶面肥+土施控释肥+保水剂(CBFF+CRF+W)。采用称重法测定辣椒产量,于收获期取果实及叶片鲜样用于果实品质和生理生化指标测定,植株各部位干样用于微量元素测定。【结果】1)两年内喷施铜基叶面肥和土施控释肥均能提高辣椒产量,其中叶面喷施铜基叶面肥+土施控释肥+保水剂(CBFF+CRF+W)组合对辣椒产量的提高幅度最大,与CKW+CRF+W相比2011年增产24.1%,2012年增产29.0%。2)相同的土壤施肥条件下,与喷清水相比,喷施铜基叶面肥能够显著提高辣椒植株体内的铜浓度。其中,土施控释肥加保水剂基础上喷施铜基叶面肥处理的辣椒果实中铜浓度比叶面喷清水显著提高了103.9%;土施控释肥条件下,叶面喷施铜基叶面肥较喷清水处理下的果实铜浓度增加了41.5%。3)喷施铜基叶面肥后,辣椒叶片的超氧化物歧化酶(SOD)和过氧化物酶(POD)活性升高,而过氧化氢酶(CAT)活性下降。CBFF+CRF+W处理下的辣椒叶片SOD活性较CKW+CRF+W处理显著提高了26.6%,CBFF+CRF+W组合的叶片的POD活性和CAT活性与CKW+CRF差异显著。4)与喷清水处理相比,无论在土壤施用控释肥还是土壤施用控释肥+保水剂的条件下,叶面喷施铜基叶面肥均使辣椒果实可溶性蛋白和维生素C的含量显著提高,其增加幅度在12.8%~178.4%。【结论】综合考虑几种肥料组合,叶面喷施铜基叶面肥和土施控释肥可在一定程度上调控植株微量元素的积累,改善辣椒营养品质,提高辣椒产量。 相似文献
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探讨大田条件下,施镁对缺镁葡萄叶片光合速率和叶绿素荧光特性的影响,为葡萄科学施肥提供理论依据。采用裂区试验,主区设4个土施硫酸镁梯度,为0、112.5、150、187.5 kg/hm~2,副区设3个叶面喷施硫酸镁浓度,分别是0%、0.2%、0.4%。土施和叶面喷施镁肥能够显著提高叶片镁含量,土施150 kg/hm~2同时叶面喷施0.4%硫酸镁肥后,叶片叶绿素含量、净光合速率、实际光量子产量、表观光合电子传递速率、原初光化学效率、光化学淬灭、非光化学淬灭维持在较高水平,初始荧光最低。缺镁土壤适量施镁(如土施150 kg/hm~2同时叶面喷施0.4%硫酸镁肥)能够显著增加叶片中镁和叶绿素含量,提高净光合速率,增加PSⅡ天线色素的非光化学能力耗散,缓解光系统受损程度,同时保持PSⅡ原处光能转换效率和潜在活性,但施镁量过大,气孔导度降低,净光合速率下降。 相似文献
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外源硒肥对茶叶硒含量及化学品质的影响研究 总被引:13,自引:0,他引:13
硒肥对提高茶叶品质和增加茶树体内硒含量具有明显的促进作用。为了探讨硒对茶叶品质的影响机制,本研究进行了土施和喷施硒肥的盆栽试验。结果表明:叶面喷施和土施Na2SeO3两种施用方式对茶叶硒含量的提高及品质的改善都非常有利。叶面喷施浓度为120μgSe/ml时,喷施后第12天,春茶的硒含量最高为0.374μg/g;叶面喷施浓度为180μgSe/ml时,喷施后第18天,夏茶和秋茶的硒含量最高,分别为0.380μg/g和0.368μg/g。采用土施硒肥的方法制富硒茶时,土壤施硒量应不少于8mgSe/盆。叶面喷施浓度为180μgSe/ml时,夏茶化学品质提高最为明显,其中酚氨比下降为对照的65.73%,可溶性糖含量增加到对照的116.30%。与叶面喷施有降低儿茶素含量的作用相比,土施硒肥对整个采摘期内茶叶儿茶素的含量无明显影响,因此对改善茶叶品质特别是春茶品质的作用后者优于前者。 相似文献
10.
锌肥施用方式对小麦、玉米产量和籽粒锌含量的影响 总被引:2,自引:0,他引:2
以"郑单958"和"先玉335"玉米品种,"良星99"小麦品种为试验材料,在田间试验条件下研究了土施和叶面喷施锌肥对小麦、玉米产量和籽粒锌含量的影响。结果表明:在华北石灰性土壤上,土施和叶面喷施锌肥并没有显著提高玉米产量,小麦产量有一定程度增加;土施以及叶面喷施锌肥均显著提高小麦、玉米籽粒锌含量,叶面喷施锌肥的效果更好,并且小麦籽粒锌含量增加幅度显著高于玉米。土施和叶面喷施均能显著降低小麦、玉米籽粒磷锌摩尔比,增加籽粒锌的生物有效性,叶面喷施的效果更好。因此,单独叶面喷施锌肥或与土施相结合是提高小麦、玉米籽粒锌含量的有效措施,是保障人体锌营养健康的重要途径之一。 相似文献
11.
纳米氧化铁对花生生长发育及养分吸收影响的研究 总被引:5,自引:0,他引:5
.通过温室砂培试验研究了纳米氧化铁与有机肥、腐殖酸配合施用对花生生长发育和吸收铁肥的影响。结果表明,纳米氧化铁能够显著地促进花生的生长发育和光合作用。有机肥和纳米氧化铁配施(OM-Fe)处理,花生叶片叶绿素含量最高,为2.89mg/g,显著高于柠檬酸铁处理(CT-Fe);纳米氧化铁和有机肥、腐殖酸配施可增强铁在植株体内的移动性,使铁向叶部转移,叶部的含铁量明显增加。纳米氧化铁与有机肥配施(OM-Fe)、纳米氧化铁(Nano-Fe)、纳米氧化铁与腐殖酸配施(HAs-Fe)处理,其植株叶部含铁量分别为218.95mg/kg、207.48mg/kg、206.64mg/kg,均大于柠檬酸铁处理(187.00mg/kg),提高了铁的利用率。此外,纳米Fe2O3还有利于促进花生对氮、磷、钾养分的吸收和利用。 相似文献
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玉米—花生混作体系中不同施氮水平对花生铁营养及固氮的影响 总被引:8,自引:3,他引:8
盆栽试验结果表明,不同氮水平条件下玉米—花生混作可明显改善花生铁营养。与单作相比,混作花生新叶叶绿素SPAD值明显提高,新叶活性铁浓度提高12.4%~27.1%,同时花生根瘤数和固氮酶活性显著增加。在本试验种植密度下,施氮水平和种植方式对单株花生生物量无显著影响,而施氮对玉米根际土壤活性铁浓度的提高有一定的促进作用,并且花生根瘤数和固氮酶活性受施氮水平影响较大。说明石灰性土壤上玉米—花生混作对花生铁营养改善及提高花生的固氮能力具有重要作用;施氮水平对花生铁营养影响不大,但随施氮量增加对花生共生固氮有抑制作用。 相似文献
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酸性根际肥对石灰性土壤pH和铁有效性的影响研究 总被引:3,自引:3,他引:3
在无植物栽培的条件下通过肥料在土壤中的扩散试验研究酸性根际肥对石灰性土壤 pH值、有效铁含量的影响 ,利用盆栽试验验证对石灰性土壤上花生缺铁失绿黄化症的矫正效果。结果表明 ,酸性根际肥 (pH 1.0~ 2 .0 )中的酸在土壤中扩散的影响半径可达 6cm ,但对土壤pH降低作用最显著的是在距肥料 2cm内 ;在施肥 2 8d内 ,距肥料 2cm处 ,土壤 pH值降低了 0 .9个单位 ,土壤铁有效性 (DTPA浸提量 )增加了 5 .9mg kg ;施用酸性根际肥可使花生叶绿素SPAD值与叶片活性铁含量显著提高 ,克服了花生缺铁黄化症状 ,使施肥区 (肥料周围 2cm内 )土壤pH值显著降低 ,并显著提高了该区土壤铁的有效性和花生对土壤Fe的吸收量。 相似文献
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《Journal of plant nutrition》2013,36(12):2425-2437
Abstract Pot and rhizobox experiments were carried out to investigate the iron availability in intercropped peanut and maize as affected by soil moisture. Results from pot experiment showed that the root growth of peanuts were significantly inhibited at 25% soil water content compared to those at 15% soil water content. The chlorophyll content in the new leaves of intercropped peanut decreased and leaves became chlorotic at 25% soil water content. There were no significant differences in the active iron concentration in new leaves of peanut between 15% and 25% soil water content. The soil pH were higher in peanut rhizosphere than in bulk soil at the early, middle, and harvest stages for both 15% and 25% soil water content. The soil bicarbonate content was also higher in peanut rhizosphere than in bulk soil for both 15% and 25% soil water content. There was significant difference in soil bicarbonate of peanut rhizosphere between 15% and 25% soil water content at the harvest stage. The available iron content in both rhizosphere soil and bulk soil were lower than 3.5 mg kg?1 in all growth stages at both 15% and 25% soil water content. Results from rhizobox experiment showed that citric acid, maleic acid, and fumaric acid in exudates of peanuts significantly increased at 25% soil water content compared to that at 15% soil water content. The apoplastic iron content of peanut roots decreased by 0.216 and 0.409 µmol g?1 fresh weight?1 (FW) from the 28th growth day to 42nd growth day at 25% and 15% soil water content, respectively. The mobilizing ability of apoplastic iron in intercropped peanuts at 15% soil water content was 20.1% higher compared to that at 25% soil water content. It is concluded that improvement of iron nutrition of peanuts with intercropping with maize could be affected by soil moisture condition. 相似文献
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《Communications in Soil Science and Plant Analysis》2012,43(7):1011-1024
This study examined the effects of exogenous nitric oxide (NO) on physiological characteristics of peanut (Arachis hypogaea L.) growing on calcareous soil. Sodium nitroprusside (SNP) was added into slow-release fertilizer (SRF) or sprayed on leaves to supply NO for iron-deficient peanut. The results showed that root application of SNP at 5.63 mg/g and foliar spray of SNP at 1.0 mmol L?1 significantly enhanced the peanut growth, pod yield, and quality. The soil pH was reduced, and available iron content and iron (Fe3+) reductase activity in root were increased, indicating NO application improved the availability of iron in the soil. Additionally, NO increased the chlorophyll and active iron content in young leaves, implying NO enhanced the availability of iron within the plant. Nitric oxide also inhibited the malondialdehyde (MDA) accumulation in leaves and increased the activity of antioxidant enzymes, which protected peanut against iron-deficiency-induced oxidative stress. It was concluded that NO might be employed for ameliorating iron-deficient chlorosis of peanut on calcareous soil when added into SRF or sprayed on leaves. 相似文献
16.
灭菌土壤玉米一花生混作对花生铁营养的影响研究 总被引:2,自引:1,他引:2
盆栽试验研究灭菌土壤玉米 花生混作对花生植株Fe营养与根际土壤有效铁的影响结果表明 ,玉米 花生混作可显著提高花生新叶叶绿素及活性铁含量 ,下针初期可增加花生地上部全Fe含量和根际土壤活性铁含量 ,混作在改善花生Fe营养过程中始终起主导作用 ;而灭菌土壤处理则仅在花生生长早期有利于改善其Fe营养状况 相似文献
17.
在覆膜条件下,研究土施硒肥对不同花生品种开花期和结荚期生理特性、农艺及产量性状的影响。结果表明,土施硒肥对3个花生品种结荚期的生理特性(黑玉珍的叶片POD活性除外)和农艺性状影响不大,而开花期的生理特性和百果重、饱果率、单株果数和单株生产力等产量性状较对照都显著提高,但不同花生品种间存在差异。其中,鲁花4号施硒后,其开花期叶片叶绿素a含量和超氧化物歧化酶(SOD)、过氧化氢酶(CAT)活性都显著增加,产量性状中单株果数和单株生产力也分别较对照显著增加52.4%和90.8%,分别达12.8个和22.7 g;花育16号施硒后则表现开花期叶片叶绿素a、b、a+b含量和SOD、CAT活性增加显著,但产量性状方面增加未达到显著水平;黑花生品种黑玉珍在施硒后表现光合特性中叶绿素a、a+b含量增加达显著水平,而产量性状中的百果重、饱果率和单株生产力依次达166.9 g、95.2%和20.5 g,较对照分别显著增加37.5%、4.73%和64.0%。此外,开花期生理性状与产量性状相关分析结果进一步表明,叶片叶绿素a含量、叶绿素a/b与单株果数、单株生产力呈较大正相关,其中叶绿素a/b与单株果数相关达显著水平(0.9257),这说明在本试验覆膜条件下,就3个花生品种平均而言,土壤施硒提高了花生植株开花期的叶片光合性能和抗氧化酶活性,从而增加了单株果数和单株生产力,增加了花生产量,这为富硒花生高产高效栽培技术提供了一定的理论依据。建议在实际工作中,可以根据不同的花生品种采取相适应的配套硒肥施用技术,以达到最佳的节本增效目标。 相似文献
18.
Sadegh Farrabi-Aschtiam 《植物养料与土壤学杂志》1972,131(2):190-196
Effect of ammonium and nitrate nitrogen, iron chelates and CCC on the chlorophyll and carbohydrat content in leaves of chlorotic, periwinkle plants an alkaline soils in Isfahan In pot experiments with periwinkle plants on alkaline soils the effect of nitrogen fertilization, iron chelats and cycocel in treating iron chlorosis was studied. High amounts of calcium nitrate produced chlorosis, followed by a general decrease in plant growth, while the same amount of ammonium sulfat prevent chlorosis and increased chlorophyll content and production of dry matter. In chlorotic plants both the chlorophyll and sugar content was increased by spraying with iron chelate, and with cycocel as well. 相似文献
19.
Yiling Song Jing Kong Xianyi Tian Xiaoying Bai Linlin Xu 《Journal of plant nutrition》2017,40(1):63-81
Nitric oxide (NO) and salicylic acid (SA) are two important signaling molecules, which could alleviate chlorosis of peanut under iron (Fe) deficiency. Here, we further investigated the mechanism of different combinations of sodium nitroprusside (SNP, a nitric oxide donor) and SA supplying in alleviation Fe deficiency symptoms and selected which is the best combination. Thus, peanut was cultivated in hydroponic culture under iron limiting condition with different combinations of SNP and SA application. After 21 days, Fe deficiency significantly inhibited peanut growth, decreased soluble Fe concentration and chlorophyll contents, and disturbed ionic homeostasis. In addition, the content of reactive oxygen species (ROS) and malondialdehyde (MDA) concentration increased, which led the lipid peroxidation. Application of SNP and SA significantly changed Fe trafficking in cells and organs, which increased Fe uptake from nutrient solution, and transport from root to shoot, enhanced the activity of ferric-chelate reductase (FCR), that increased the available Fe in cell organelles, and the active Fe, chlorophyll contents in leaves. Furthermore, ameliorated the inhibition of calcium (Ca), magnesium (Mg) and zinc (Zn) uptake and promoted plant growth in Fe deficiency. At the same time, it increased the activities of superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT) to protect the plasmolemma from peroxidation. Results demonstrated that different combinations of SNP and SA application could alleviate the chlorosis of peanut in Fe deficiency by various mechanisms. Such as increased the available Fe and chlorophyll concentrations in leaves, improved the activities of antioxidant enzymes and modulated the mineral elements balance and so on. Foliar application of SNP and SA is the best to protect leaves while directly adding them into nutrient solution is the best to protect roots. These results also indicated that the effects of SNP and SA supplying together to leaves or roots are better than respectively adding to roots and spraying to leaves. The best combination is foliar application of SNP and SA. 相似文献