不同灌溉方式对水稻生物学特性与水分利用效率的影响

以杂交水稻两优培九为试验材料,利用测坑栽培条件,比较了4种灌溉方式下的水稻生物学特性与水分利用效率.结果表明,与淹水灌溉相比,间歇灌溉叶面积指数大,叶片光合速率高,蒸腾速率较低,叶片水分利用效率高;半干旱栽培叶片水分利用效率相对较高;干旱栽培叶面积指数小,叶片净光合速率和水分利用效率降低,且后期叶片早衰.间歇灌溉、半干旱栽培和干旱栽培比淹水灌溉分别节水8.75%、17.96%和29.69%;产量分别增产24.02%、减产5.07%和减产38.93%;水分利用效率以间歇灌溉最高,半干旱栽培次之,淹水灌溉和干旱栽培较低.间歇灌溉下稻粒的整精米率、精米率、粒长均高于其它处理,但垩白粒率和垩白度低于其它处理;随着稻田耗水量的减少,水稻的直链淀粉含量降低,而胶稠度和蛋白质含量提高.试验结果表明间歇灌溉为南方稻区较适宜的灌溉方式.     

Effects of water regime on growth,yield, and nitrogen uptake of rice

Summary The effects of water regime on the performance of rice were investigated in a greenhouse experiment and two field experiments. The greenhouse experiment involved four water regimes (continuous flooding, and soil drying for 16 days — begun 2, 5, and 8 weeks after transplanting — followed by reflooding), four soils, and 0 and 100 mg N/kg. Soil drying raised the redox potentials of all soils beyond the aerobic threshold. Averaged for soils and N levels, yields from treatments in which soil drying was begun at 2 and 5 weeks after transplanting were lower than that from the continuously flooded treatment, but the simple effects of soil drying on yield and N uptake depended on the soil and the growth stage of the plant. None of the soil-drying treatments had adverse effects in the soil high in N but soil drying at 2 and 5 weeks after transplanting had adverse effects in the soil low in N. The field experiments tested the effects of three water regimes (continuous flooding, alternate drying and flooding every 2 weeks, and soil drying for 2 weeks at 6 weeks after transplanting following by reflooding), and 0, 50, 100, and 150 kg N/ha on a nearly neutral clay soil, during two seasons. None of the soil-drying treatments depressed growth, yield, or N uptake by rice at any level of N in either season. Nitrate was absent after drying, so denitrification was not possible on subsequent flooding. The adverse effects on yield of alternate flooding and drying, attributed to nitrification-denitrification, may be insignificant in wetland fields carrying an actively growing rice crop.     

交替地下滴灌对春玉米产量和水分利用效率的影响

采用自动式遮雨棚水分精量控制试验研究了交替地下滴灌条件下不同灌溉定额对春玉米产量和水分利用效率的影响.结果表明:交替地下滴灌春玉米需水关键时期为拔节-抽雄期、抽雄-灌浆期,具体表现为耗水模系数与耗水强度大,且对水分敏感性高,在灌溉条件有限的情况下要优先满足春玉米这两个时期的水分需求.随着灌溉定额的增加,产量呈现增加趋势;灌溉定额小于2764.5 m³·hm^-2时产量随灌溉定额增加快速增加,大于2764.5 m³·hm^-2时产量随灌溉定额增加缓慢增加;当灌溉定额为3357.1 m³·hm^-2时产量最高,达12109.0 kg·hm^-2.与固定地下滴灌相比,在灌溉定额相同条件下,交替地下滴灌产量提高5.4%,水分利用效率提高1.4%,灌溉水利用效率提高5.6%.与固定地下滴灌相比,灌溉定额减少20%时,交替地下滴灌虽然产量下降1.8%,但水分利用效率提高11.0%,灌溉水利用效率提高22.7%.综合考虑产量、水分利用效率两个指标,确定试验区春玉米交替地下滴灌的适宜灌溉定额为1600.4～3357.1 m³·hm^-2.     

Benefits of alternate partial root-zone irrigation on growth, water and nitrogen use efficiencies modified by fertilization and soil water status in maize

Alternate partial root-zone irrigation (APRI) is a new water-saving technique and may improve crop water use efficiency without much yield reduction. We investigated if the benefits of APRI on biomass accumulation, water and nitrogen use efficiencies could be modified by different soil fertilization and watering levels in pot-grown maize (Zea mays L. cv. super-sweet No 28, a local variety). Three irrigation methods, i.e. conventional irrigation (CI), alternate partial root-zone irrigation (APRI, alternate watering on both sides of the pot) and fixed partial root-zone irrigation (FPRI, fixed watering on one side of the pot), two watering levels, i.e. water deficit (W₁, 45–55% of field capacity) and well-watered (W₂, 70–80% of field capacity), and two N fertilization levels, i.e. no fertilization and fertilization, were designed. Results showed that APRI and FPRI methods led to more reduction in transpiration than in photosynthesis, and thus increased leaf water use efficiency (leaf WUE, i.e. the ratio of leaf net photosynthetic rate to transpiration rate). Compared to the CI treatment, APRI and FPRI increased leaf WUE by 7.7% and 8.1% before the jointing stage and 3.6% and 4.2% during the jointing stage, respectively. Under the fertilization and well-watered conditions, APRI treatment saved irrigation water by 38.4% and reduced shoot and total dry masses by 5.9% and 6.7%, respectively if compared to the CI treatment. APRI also enhanced canopy WUE (defined as the amount of total biomass per unit water used) and nitrogen (N) apparent recovery fraction (Nr, defined as the ratio of the increased N uptake to N applied) by 24.3% and 16.4%, respectively, indicating that effect of APRI can be better materialized under appropriate fertilization and water supply. Responsible Editor: Rana E. Munns     

调亏灌溉和生物炭对大豆生长、产量及水分利用效率的影响

为了解生物炭及调亏灌溉对大豆的影响,以大豆"开育12号"为试验材料,采用随机区组试验设计,利用盆栽栽培条件,研究不同生物炭添加量B₀(0 t·hm^-2)、B₁(6t·hm^-2)、B₂(12 t·hm^-2)和不同程度调亏灌溉W₁(充分灌溉,70%田间持水量)、W₂(轻度调亏,55%～60%田间持水量)、W₃(重度调亏,45%～50%田间持水量)对大豆生长、产量及水分利用的影响。结果表明:轻度调亏灌溉不会影响大豆叶面积指数及地下部分干物质累积量,而大豆叶面积指数和地下部分干物质累积量随着生物炭使用量的增加而增加;地上部分干物质累积量随着调亏程度的加重而降低,而生物炭施用量为12 t·hm-2时,才会提高地上部分干物质累积量。调亏灌溉和生物炭均能影响大豆的耗水量,其中耗水量随着调亏程度的加剧而减少,而添加6 t·hm^-2生物炭耗水量最高,但有利于产量的形成。与充分灌溉不施用生...     

Effect of long-term fertilizer treatments on groundnut yield,nodulation, and nutrient uptake at Samaru,Nigeria

It was observed in a long-term fertility study that P application results in better nodulation and seed yield. The N yield per plant increased significantly with P, K, and B application, but the promoting effect of K and B on N content per plant was not reflected in the final yield. Data on mean nutrient uptake indicate that about 63% of N, 68% of P, 23% of K, 4% of Ca and 24% of Mg were present in the kernels, the remainder being in the haulm and shells. Soil will be exhausted fast if the nutrient rich groundnut residues are completely exported from the field and not compensated by adequate fertilizer application. Judicious use of fertilizers on groundnut has been shown to yield more than 100 kg of biologically fixed N per hectare.     

水肥互作对滴灌玉米氮素吸收、水氮利用效率及产量的影响

优化水、氮供应是实现作物高产与水肥资源高效利用的有效途径.本文研究了田间试验条件下,水(4500、6750、9000 m³·hm^-2)、氮(0、225、330、435、540 kg·hm^-2)互作对高密度(≥105000 株·hm^-2)滴灌玉米干物质积累、氮素吸收及产量的影响.结果表明: 玉米干物质积累与吸氮量均随灌溉和施氮水平的增加明显升高,当施氮量大于435 kg·hm^-2和灌溉量大于9000 m³·hm^-2时则呈减少趋势.完熟期玉米干物质积累对灌水的响应表现为W₆₇₅₀(36359 kg·hm^-2)>W₉₀₀₀(35077 kg·hm^-2)>W₄₅₀₀(33451 kg·hm^-2),施氮对玉米吸氮量的变化表现为N₄₃₅(459.9 kg·hm^-2)>N₅₄₀(458.1 kg·hm^-2)>N₃₃₀(416.3 kg·hm^-2)>N₂₂₅(351.3 kg·hm^-2),N₄₃₅比N₃₃₀、N₂₂₀分别升高9.1%、32.7%,N₅₄₀比N₄₃₅降低0.6%.在施氮量0～435 kg·hm^-2范围内,玉米最大氮素吸收速率随施氮量增加而升高,在施氮量为435 kg·hm^-2时达最大(6.57 kg·hm^-2·d^-1).灌水与施氮均可显著增加玉米产量、穗粒数和穗粒质量,二者有明显的正交互作用,且以氮为主效应.在施氮0～435 kg·hm^-2范围内,氮肥利用率随施氮量的增加而升高,此后反而降低;灌溉水分生产率随施氮量升高而增加,随灌水量增加而明显下降,灌溉定额为4500～6750 m³·hm^-2时,灌溉水分生产率可达2.57～3.80 kg·m^-3.玉米最高产量18072 kg·hm^-2的施氮量为567.0 kg·hm^-2.最佳经济施氮量为427.9～467.7 kg N·hm^-2时,玉米产量在17109～17138 kg·hm^-2,氮素偏生产力和氮肥利用率分别达122 kg N·hm^-2和45.0%.水氮一体化施肥可实现滴灌玉米高产协同水、氮利用效率的共同提高.     

有机营养液灌溉频次和灌水量对设施甜瓜产量、品质及肥水利用效率的影响

为研究高产优质甜瓜的有机管理模式,以甜瓜为试材,采用基质盆栽方式,设3种有机营养液灌溉频次(施用8次,每次每株750 mL, F₁; 施用12次,每次每株500 mL, F₂; 施用16次,每次每株375 mL, F₃)与2种单株灌水量(果实膨大前按120%日蒸腾蒸发量(ET)灌溉,之后按140%ET灌溉, W₁; 果实膨大前按140%ET灌溉,之后按160%ET灌溉, W₂),共6个试验处理,随机区组试验设计,研究了不同处理对设施甜瓜光合特性、产量、品质及肥水利用效率的影响.结果表明: 少量多次施用有机营养液可以显著提高甜瓜叶片光合速率,低灌水量显著提高果实产量和水分利用效率;高灌水量和中等有机营养液灌溉频次可使肥料利用率达到最高;少量多次有机营养液施用且相对适宜的水分供给提高了果实品质.回归分析发现,甜瓜果实维生素C含量与有机营养液灌溉频次呈指数函数y=0.214e^0.18x (R²=0.851)相关.综合考虑产量、品质、水分利用效率等因素,F₃W₁处理可在保证产量的前提下,提高果实品质,且水分利用效率最大,可以实现设施有机甜瓜肥水高效管理.     

冬小麦生长季不同灌溉模式对冬小麦-夏玉米产量与水分利用的影响

在华北平原黑龙港流域对冬小麦实行3种灌溉模式,研究了不同灌溉模式对冬小麦-夏玉米产量、耗水特性和水分利用效率的影响.结果表明:浇底墒水+拔节水处理(W2,75 mm+90 mm)和浇底墒水+拔节水+灌浆水处理(W3,75 mm+90 mm+60 mm)周年总产量均显著高于只浇底墒水处理(W1,75 mm),增幅分别为8.7%和12.5%.冬小麦全生育期对土壤水的消耗随灌溉量的增加而减少,夏玉米季总耗水量随冬小麦季灌溉量的增加而增加.W2处理冬小麦水分利用效率(WUE)比W3处理高11.1%,而其夏玉米水分利用效率(WUE)与W3处理差异不显著.W2和W1处理的周年水分利用效率(WUET)分别为21.28和21.60 kg.mm-1.hm-2,比W3处理分别高7.8%和9.4%.综合周年产量、耗水量和水分利用效率,W2是较好的节水丰产灌溉模式.     

华北平原玉米田能量平衡、水分利用效率和表面阻力分析

根据华北平玉米田的观测结果,分析了地表／大气能量转化传输特征。结果表明,在作物生育期内,地表能量平衡过程受下垫面特征影响很大。潜热通量是地表／大气热量交换的主要分量;玉米生长的后期有热平流输入,日平均显热通量转为负值。表面阻力在生育期早期和后期较大,而在中期较小,显示了表面阻力对地表覆盖变化和叶片衰老的响应。农田水分利用效率在生长季呈逐渐增长的趋势。     

伤根对玉米光合作用和水分利用效率的影响

1　引　　言在世界范围内 ,水资源的短缺日益受到人们的关注 ,农业水资源的高效利用已是世界农业亟待解决的主要问题 .因此 ,现代农业不应再单纯满足于高产 ,还应着眼于节约资源 ,提高水资源利用效率 .近年来 ,为了提高产量及水分利用效率 ,农业科技工作者在植物 水分方面做了大量的工作[1～ 3 ,5～ 7,9～ 12 ] .在人类的农业生产实践中 ,水稻插秧、幼苗移栽以及对作物的中耕等都可以使植株生长状况好转 ,作物产量提高 ,而这些措施都会对植物根系产生一定的影响 .对作物根系进行人为的伤害 ,也可能会改善作物生长状况 ,调节作物对有限土壤水…     

Internal efficiency, nutrient uptake, and the relation to field water resources in rainfed lowland rice of northeast Thailand

Rice-based (Oryza sativa L.) rainfed lowlands are the major cropping system in northeast Thailand. Average yields are low, which is generally explained by frequent drought events, low soil fertility, and poor fertilizer response. However, neither the relative importance of these factors nor their interaction is well understood. Therefore, we analyzed an existing database on fertilizer trials conducted between 1995 and 1997 at eight different sites in northeast Thailand with the objective to determine indigenous nutrient supplies, internal efficiencies, and recovery efficiencies of applied nutrients in rainfed lowland rice. Of particular interest was the effect of variety type (traditional) and water supply on these components. Comparison of N, P, and K concentrations in grain and straw (average N–P–K grain concentration of 11.0–2.7–3.4 g kg⁻¹; average N–P–K straw concentration of 5.2–0.9–16.4 g kg⁻¹) in the traditional-type varieties used at all trial sites with literature values showed no differences for these parameters between traditional and modern-type varieties or between irrigated and rainfed environments. In contrast, internal efficiencies of N, P, and K (average IEN: 46 kg grain per kg N uptake; IEP: 218 kg grain per kg P uptake; IEK: 25 kg grain per kg K uptake) were much lower than reported for irrigated systems, and the difference was greatest for K, which is mainly accumulated in the straw. Indigenous nutrient supply (average INS: 38 kg ha⁻¹; IPS: 10 kg ha⁻¹; IKS: 89 kg ha⁻¹) and recovery efficiency (average REN: 0.28 kg kg⁻¹; REP: 0.13 kg kg⁻¹; REK: 0.49 kg kg⁻¹) were low but comparable to the lower values reported from irrigated systems. Average seasonal field water resources seemed to reduce the indigenous nutrient supply but had no or little effect on internal efficiency and recovery efficiency. We concluded that the main reason for the low system productivity without and with fertilizer in northeast Thailand is the dominant use of traditional-type varieties with low harvest indices, which was the dominant cause for the observed low internal nutrient efficiency. Therefore, intensification of rainfed systems through substantially increased nutrient inputs can be recommended only where varieties with an average harvest index of close to 0.4 or higher are available.     

亏缺灌溉对棉花生长和水分利用效率的影响研究进展

棉花是世界上最主要的农作物之一.随着全球水资源的日益紧张,灌溉用水将成为限制棉花生产的主要因素.亏缺灌溉是一种低于作物正常腾发量的灌溉方式,可以在保证棉花产量和品质的前提下提高水分利用效率,是一种有效的节水灌溉方式.本文综述了亏缺灌溉对棉花生长和水分利用效率的影响.亏缺灌溉可以通过促进棉花由营养生长向生殖生长转化,降低...     

Root distribution and water uptake patterns of maize cultivars field-grown under differential irrigation

Summary Rooting and water uptake patterns were determined for three maize (Zea mays L) varieties field-grown during the 1983/84 dry season under seven irrigation levels on a sandy loam soil. Roots were mainly concentrated in the top 22 cm due to a 40 cm thick compact gravelly layer occurring from about this depth in the profile. There were significant varietal differences, distinguished by root length density (RLD) and length/weight ratio (LAR) distributions at depth and at varying soil moisture regimes. These properties were related to water extraction patterns and grain yields. Yields obtained at adequate soil moisture were 6.9 tha⁻¹ for TZESR-W (var 1), 4.2 t/ha for TZSR-W (var 2) and 3.7t ha⁻¹ for FARZ-7 (var 3). These yeilds were respectively associated with maximum RLD of 2.56, 1.88 and 1.70 cm cm⁻³ and corresponding LWR of 2.64, 1.93 and 1.62 cm mg⁻¹. Average seasonal water uptake was estimated at 4.2, 3.0 and 2.8 mm day⁻¹ for var 1, 2 and 3, respectively. Better performance of var 1 was attributed to the development of a more active and deep rooting system.     

灌水量与密度互作对冬小麦籽粒产量和水分利用效率的影响

为明确协同提高冬小麦产量和水分利用效率的适宜灌水量和种植密度,选用大穗型品种‘泰农18’(T18)和中穗型品种‘山农22’(S22)为试验材料,设置4个灌溉水平(不灌水、每次灌水45、60、75 mm)和4个种植密度,其中泰农18选用135×10⁴、270×10⁴、405×10⁴、540×10⁴ 株·hm^-2,山农22选用90×10⁴、180×10⁴、270×10⁴、360×10⁴株·hm^-2,研究了籽粒产量、麦田耗水特性和水分利用效率对灌水量和密度互作效应的响应。结果表明: 籽粒产量、总耗水量、土壤贮水消耗量和水分利用效率均受到灌溉水平、种植密度及两者互作效应的显著影响。每次灌水量为45 mm,泰农18种植密度为405×10⁴株·hm^-2、山农22种植密度为270×10⁴株·hm^-2时,两品种籽粒产量均达到最高,拔节后棵间蒸发量占阶段农田总耗水量的比例最小,1 m以下土壤水消耗比例、水分利用效率高。种植密度与灌溉量合理组合,有利于降低水分无效损耗,提高水分利用效率。     

植物养分利用效率研究综述

养分利用效率的概念是理解生态系统功能的中心。本文从植物养分利用效率的概念出发,对养分利用效率的表示与计算方法、影响因素以及养分再吸收的生物化学基础等进行综述,分析目前研究中存在的问题,最后指出今后应加强研究的方面。     

沟垄全覆盖种植方式对旱地玉米生长及水分利用效率的影响

2008-2010年在渭北旱塬区,以沟不覆盖为对照(CK),研究垄上覆地膜沟内分别覆普通地膜(PP)、生物降解膜(PB)、玉米秸秆(PS)和液体地膜(PL)4种沟垄全覆盖种植模式对土壤水温、玉米生长、产量及水分利用效率的影响.结果表明,在玉米生长前期,PP、PB和PS处理可明显提高0-200 cm土壤蓄水量;生育中期,PS处理蓄水保墒效果最为显著;生育后期,各沟垄全覆盖处理与对照的土壤蓄水量无显著差异;整个生育期PL处理与CK的土壤蓄水量差异不显著.PP和PB处理3a玉米生育期5-25 cm平均土壤温度分别较CK增高1.6℃和1.3℃,PS处理降低1.9℃,而PL处理与CK无显著差异.PP和PB的增温保水效应使玉米株高、叶面积及地上生物量均高于CK;PS处理的降温效应促进玉米中后期生长,其株高、叶面积及地上生物量均高于CK;PL处理对玉米各生长指标影响不显著.与CK相比,PP、PB和PS处理3a平均的籽粒产量分别提高13.0％、13.8％和15.0％,水分利用效率分别提高9.8％、10.2％和11.6％.可见,垄覆地膜沟覆地膜、生物降解膜或秸秆的沟垄全覆盖种植可明显改善土壤的水温状况,促进玉米生长,从而显著提高作物产量和水分利用效率,对渭北旱塬区春玉米丰产栽培具有重要指导意义.     

不同水分管理方式下水稻的水分利用效率与产量

采用温室微区试验研究常规水作、裸地旱作、覆膜旱作和覆草旱作等土壤水分管理下水稻生长及其对水分的利用状况。结果表明,几种旱作水稻的需水量为349-473mm,常规水和水稻需水量为762.5mm。旱作水稻的水分籽粒和干物质生产效率为0.899-1.273g·kg^-1和1.655-2.321g·kg^-1之间,而相同条件下常规水作水稻水分的籽粒和干物质生产效率为0.766g·kg^-1和1.459g·kg^-1左右。覆草旱作水稻可以获得相当于常规水作水稻90％的经济产量。     

灌水模式对冬小麦光合特性、水分利用效率和产量的影响

试验于2013—2014和2014—2015年连续2个生长季在自动控制干旱棚内的隔离池中进行,拔节期设3个灌水梯度,灌水量分别为0(J_0)、37.5(J_1)、75 mm(J_2),扬花期设3个灌水梯度,灌水量分别为0(F_0)、37.5(F_1)、75 mm(F_2),灌浆期所有处理均按75 mm灌溉,共9个处理,研究不同灌溉模式对小麦中后期不同生育阶段植株生长、耗水量、水分利用效率、光合特性和产量构成因素的影响.结果表明:拔节期干旱(0和37.5 mm)显著降低了小麦扬花期的净光合速率和拔节后的叶面积,扬花期的灌水量直接影响扬花期后的旗叶净光合速率;拔节期干旱扬花期补水和扬花期干旱灌浆期补水都可以有效提高植株的干物质量;拔节期灌水量越多,全生育期耗水量越大;除J_1F_2外,全生育期灌水量越大,耗水量越大,产量也越高;J_1F_2处理产量和水分利用效率最高.扬花期充足的灌水量使J_1F_2处理具有较高的花后旗叶净光合速率,此期补偿性灌溉加快了干物质积累,也保证了较高的穗粒数,使其最终产量高于J_2F_2处理或与之持平,同时J_1F_2拔节期较低的灌水量降低了小麦生育中后期的耗水量,其水分利用效率也显著高于其他处理.综上,J_1F_2是小麦生育中期理想的水分处理组合.     

不同模拟雨量下耕作措施对夏玉米水分利用效率和产量的影响

基于西北夏玉米生产实际和降雨特征,用自制模拟降雨器,于2010年6-9月研究了250、350和450 mm模拟雨量下翻耕、免耕、免耕覆盖对夏玉米农田水分利用效率及产量的影响.结果表明： 在6-9月250 mm雨量下免耕水分利用效率比翻耕高26%,产量比翻耕高16.5%;350 mm雨量下免耕水分利用效率和产量分别比翻耕高17.6%和6.1%;在450 mm雨量下免耕的蓄水效应低于翻耕,水分利用效率比翻耕低1.1%,产量比翻耕低0.6%.免耕覆盖克服了免耕在雨量充沛时水分蓄积量低于翻耕的缺点,在3种雨量下均可有效抑制棵间蒸发,减少翻耕地表裸露造成的无效水分消耗,增加土层贮水量,增大蒸腾量占水分消耗的比例,250 mm雨量下免耕覆盖水分利用效率比翻耕高48.6%,产量比翻耕高32.9%;350 mm雨量下免耕覆盖水分利用效率比翻耕高51.6%,产量比翻耕高27.1%;450 mm雨量下免耕覆盖水分利用效率比翻耕高23.7%,产量比翻耕高13.1%.综上,免耕夏玉米在250和350 mm雨量下相对于翻耕有增产和提高水分利用效率的优势,免耕覆盖夏玉米在250、450 mm雨量下产量和水分利用效率显著高于翻耕.