灌溉施肥部位对玉米同化物分配和水分利用的影响

用土柱管栽试验方法研究了不同灌溉施肥深度对夏玉米生长发育、地上地下部分同化物分配、产量和水分利用效率的影响。试验结果表明：土表下灌施抑制了玉米生育早期的地上部分生长,使根系向土壤中下层的分布加强,从而保证了作物中后期对水分养分的吸收利用,提高了水分利用效率。在本试验条件下,玉米生长的最佳灌施深度为30cm。     

水肥异区交替灌溉对夏玉米生理指标的影响

以夏玉米品种‘户单4号'为材料,通过防雨棚内微区试验研究了两种灌水量(450 m~3/hm~2和900 m~3/hm~2)条件下水肥异区交替灌溉和均匀灌溉对夏玉米生长以及某些生理指标的影响.结果显示:(1)在节水50%的条件下,水肥异区交替灌溉与高灌水量均匀灌溉的夏玉米生物量、产量均无显著差异.(2)低灌水量时,水肥异区交替灌溉下的玉米根系伤流液、叶片可溶性蛋白含量、硝酸还原酶活性、光合速率、蒸腾速率等均高于均匀灌溉施肥处理,而植株全氮含量及叶片水分利用效率与均匀灌溉施肥的差异不显著.(3)高灌水量时,水肥异区交替灌溉处理除根系活力、光合速率以及蒸腾速率高于均匀灌溉处理外,其他指标均低于后者.研究表明,在低灌水量条件下,水肥异区交替灌溉能使夏玉米保持较高的根系活力和正常生理代谢,提高其叶片水分利用效率,从而达到了节水增产的目的.     

基于DSSAT模型对豫北地区夏玉米灌溉制度的优化模拟

合理的灌溉制度是提高农业水资源利用效率、保证夏玉米高产稳产的前提。采用农业技术转化决策系统(DSSAT,Decision Support System for Agrotechno1ogy Transfer)探究了河南省北部地区夏玉米不同降水年型下的最优灌溉制度。经过参数的校正和验证,归一化均方根误差(nRMSE)、均方根误差(RMSE)和一致性指数(d)均表现出模拟值与实测值的吻合度很好,DSSAT-maize模型可以准确模拟夏玉米物候期、地上部分生物量、产量和土壤水分状况。然后基于模型模拟了不同灌溉处理下的夏玉米生产潜力,从而评估夏玉米缺水量,并对比分析不同生育时期灌水对产量的影响确定最优灌溉时期,综合考虑产量和水分利用效率确定最优灌溉制度。结果表明:夏玉米生长季的缺水量年际间差异显著,多年平均值为38.91 mm,波动范围为0—193.03 mm。在丰水年,不需要灌溉;在平水年,开花期灌水30 mm;在枯水年,开花期和灌浆期灌水50 mm;在特别干旱年,苗期、拔节期和开花期至少灌水180 mm。优化的灌溉制度下丰水年、平水年和枯水年的WUE达到最高且产量分别占其最高产量的100%、99.72%和97.89%,实现了作物高产节水协同提高的目标。     

夏玉米苗期有限水分胁迫拔节期复水的补偿效应

以作物调亏灌溉原理为基础 ,对夏玉米苗期水分胁迫拔节期复水进行了试验研究。结果表明 ,复水增加了夏玉米叶片气孔导度和光合速率 ,提高叶片水平上的水分利用效率(WUE)。复水 2天后 ,叶片气孔导度和光合速率即恢复到对照水平 ,部分时段 ,特别在下午 ,复水处理表现出高于对照的“反冲”现象。复水使苗期受旱的夏玉米株高、叶面积、地上 (下 )部分干物重和根系生长发育都恢复到或接近充分供水的植株生长水平。使其产量及构成因子与对照接近 ,水分利用效率显著地提高了 2 4 7%。这为玉米中后期的水分管理 ,提高玉米水分利用效率 ,提供了一定的理论依据 ;也提供了一种便于广大农民掌握的简单易行的灌溉方式     

水氮互作对小麦土壤水分利用和茎中果聚糖含量的影响

通过田间试验,以强筋小麦济麦20为材料,设置3个施氮水平：0 kg·hm^-2（N₀）、180 kg·hm^-2（N₁）、240 kg·hm^-2（N₂）;4个灌水处理：不灌水（W₀）、底墒水+拔节水+开花水（W₁）、底墒水+冬水+拔节水+开花水(W₂)、底墒水+冬水+拔节水+开花水+灌浆水(W₃),每次灌水量为60 mm,研究水氮互作对土壤水分含量、旗叶光合速率、倒二茎中果聚糖含量及氮肥和水分利用效率的影响.结果表明：施氮水平为180 kg·hm^-2处理的旗叶光合速率和倒二茎中果聚糖含量较高,籽粒产量、氮肥表观利用效率、氮肥农学利用率和水分利用效率最高;施氮水平为240 kg·hm^-2处理的茎中果聚糖含量较高;不施氮（N₀）或施氮过多（N₂）均不利于小麦籽粒产量、氮肥和水分利用效率的提高.W₁水分处理促进了倒二茎中果聚糖的积累和向籽粒的转运,有利于产量的提高.180 kg·hm^-2施氮水平配合灌溉底墒水+拔节水+开花水的水氮交互处理（N₁W₁）具有较高的籽粒产量及较高的氮肥和水分利用效率,在此基础上增加施氮量或灌水量,小麦旗叶光合速率和倒二茎中果聚糖含量升高,籽粒产量无显著变化或降低,氮肥和水分利用效率降低.     

灌溉方法与施氮对土壤水分、硝态氮和小麦生长发育的调控效应

为探明玉米秸秆还田下小麦的合理灌溉与施肥方法,于田间研究了漫灌(FI)、微喷灌(SI)、滴灌(DI)和灌水施氮模式(N₁, 基施纯N 157.5 kg·hm^-2+拔节期施纯N 67.5 kg·hm^-2; N₂, 基施纯N 157.5 kg·hm^-2+拔节期施纯N 45.0 kg·hm^-2+灌浆期施N 22.5 kg·hm^-2)对土壤水分、硝态氮(NO₃^--N)含量和小麦生长发育的影响.结果表明: 灌溉方法和灌水施氮模式共同影响土壤含水量和贮水量的变化.其中,灌溉方法对越冬期和返青期0～60 cm、孕穗期和灌浆期0～160 cm、成熟期100～160 cm土层含水量影响相对较小,对越冬期和返青期80～160 cm、成熟期0～80 cm土层含水量影响大;FI对含水量和贮水量影响最大,DI次之,SI最小;SI和DI的灌水施氮模式中灌水量多,则土层含水量高、贮水量多,变化大.NO₃^--N含量受灌溉方法和施氮的影响,施氮对0～20 cm土层影响大,SI生育期NO₃^--N含量变化大,DI越冬期至孕穗期NO₃^--N含量变化小,此后变化大,FI与DI相反;生育前中期灌水量对NO₃^--N含量影响大,后期施氮对NO₃^--N含量影响大;SI和DI的2种灌水施氮模式中冬前灌水量多的NO₃^--N含量变化大.灌溉方法中SI越冬期总茎数和单株分蘖高,成穗率高,成穗数多,产量、水分利用效率(WUE)和氮素利用效率最高,滴灌次之,漫灌最低;SI和DI中N₁生育期总茎数、成穗数多,但穗粒数和千粒重低,产量、WUE和氮素利用效率低于N₂.因此,玉米秸秆还田后播种小麦,微喷灌代替漫灌生育期灌4水,施足基肥,拔节期和灌浆期分次追氮,是山西南部小麦-玉米一年两熟区小麦节水高产高效栽培模式.     

关中灌区沟垄集雨种植补灌对冬小麦光合特征、产量及水分利用效率的影响

通过大田试验,研究了沟垄集雨种植结合不同补灌量处理对冬小麦光合器官、光合速率、产量和水分利用效率的影响.结果表明:沟垄宽度各为60 cm时,集雨种植不灌溉(T1)、返青期种植沟补灌375 m3·hm-2(T2)和种植沟补灌750 m3·hm-2(T3)3个处理较平作灌水750 m3·hm-2(畦灌,T4)处理的小麦籽粒产量分别提高2.8％、9.6％和18.9％,收获系数提高2.0％～ 8.5％,旗叶叶绿素含量提高41.9％ ～64.4％,整个生育期内0～ 40 cm土壤含水量增加了0.1％～4.6％;开花期和灌浆期的叶片光合速率分别较T4处理提高了22.3％～ 54.2％和-4.3％～67.2％,农田总水分利用效率较T4处理分别提高17.9％、10.4％和15.4％,比平作不灌水处理(CK)提高69.3％、58.6％和65.7％;降水利用效率较CK提高94.3％ ～ 124.5％;T2、T3处理各生育阶段叶面积均显著高于T4处理,灌溉水利用效率分别比T4处理提高119.1％和18.8％.在灌溉量减少50％的条件下,集雨种植比畦灌处理能维持较高的籽粒产量,显著提高灌溉水利用效率,尤其是在降雨量偏少的年份,可以显著提高小麦水分利用效率.     

不同施氮量下灌水量对小麦耗水特性和氮素分配的影响

研究了不同施氮量条件下灌水量对高产小麦耗水特性和氮素分配利用的影响。设置4个施氮水平:0kg·hm-2(N0)、120kg·hm-2(N1)、210kg·hm-2(N2)和300kg·hm-2(N3),在每个施氮水平下设置4个灌水量处理:不浇水(W0)、底墒水+拔节水(W1)、底墒水+拔节水+开花水(W2)、底墒水+拔节水+开花水+灌浆水(W3),每次灌水量60mm。结果表明:(1)在N0水平下W0处理日耗水量以拔节至开花期最高,在N1水平下,拔节至开花期日耗水量与开花至成熟期的无显著差异。同一施氮水平下,小麦开花后总耗水量、耗水模系数和日耗水量随灌水量的增加而提高,但产量随灌水量的增加先升高后降低。(2)同一施氮水平下,成熟期W1处理20—140cm各土层土壤含水量低于W2和W3处理,140—200cm土层土壤含水量与W2处理无显著差异;W1处理0—40cm土层土壤硝态氮含量及植株氮素在籽粒中的分配比例高于W2和W3处理,100—140cm土层土壤硝态氮含量及植株氮素在营养器官中的分配量和分配比例低于W2和W3处理。表明灌溉底墒水和拔节水的W1处理,促进了小麦对20—140cm土层土壤水的吸收利用,减少了土壤硝态氮向100cm以下土层的淋溶,而且有利于营养器官中氮素向籽粒的再分配,水分和氮素利用效率较高。(3)在试验条件下,施纯氮210kg·hm-2、灌溉底墒水和拔节水的N2W1处理,籽粒产量最高,水分利用效率和氮素利用效率较高,可供生产中参考。     

不同灌水模式对冬小麦籽粒产量和水、氮利用效率的影响

在田间试验条件下,以冬小麦品种泰农18为材料,设置灌底墒水(CK)、底墒水+拔节水(W1)、底墒水+拔节水+越冬水与灌浆水交替灌溉(越冬/灌浆水交替灌溉模式,W2)、底墒水+拔节水+开花水(优化传统灌溉模式,W3)、底墒水+越冬水+拔节水+灌浆水(传统灌溉模式,W4)5种灌溉模式,每处理每次灌水量均为600 m3·hm-2,研究了山东泰安偏旱年份(2009-2010年)不同灌溉模式对小麦籽粒产量、水分利用效率和氮素利用效率的影响.结果表明:在小麦全生育期119.7 mm降水量条件下,越冬/灌浆水交替灌溉模式(W2)与传统灌溉模式(W4)籽粒产量差异不显著,但水分利用效率显著高于传统灌溉模式,与灌水量相同的优化传统灌溉模式(W3)相比,其小麦籽粒产量明显提高,水分利用效率无显著差异;越冬/灌浆水交替灌溉模式和传统灌溉模式的氮肥偏生产力最高,且籽粒收获后越冬/灌浆水交替灌溉模式在0 ～100 cm土层的硝态氮积累量显著高于传统灌溉模式和优化传统灌溉模式,降低了硝态氮的淋溶损失.在本试验条件下,越冬/灌浆水交替灌溉模式(W2)是可以兼顾小麦籽粒产量、水分利用效率和氮素利用效率的最佳灌溉模式.     

根际土壤通透性对玉米水分和养分吸收的影响

为改善作物根系生长微环境,探索根际土壤通透性对作物水分和养分吸收的影响,在3个灌溉水平下（灌水量分别为每次600、400和200 ml）,采用盆栽玉米不通气、每隔2 d通1次气、每隔4 d通1次气等处理方法,研究了根际土壤通透性对盆栽玉米生理指标及水分和养分吸收的影响.结果表明：在相同灌水条件下,通气处理促进了玉米株高、叶面积的增长,提高了叶绿素含量;促进了玉米对土壤养分的吸收;显著提高了玉米的根系活力,灌水量为每次600 ml时,拔节期每隔4 d通气处理的玉米根系活力最大（8.24 mg·g^-1·h^-1）,较不通气处理（4.94 mg·g^-1·h^-1）提高了66.7%;根际土壤通气处理对盆栽玉米蒸腾的影响不显著,说明根际通气可提高玉米对水分与养分的吸收利用效率,促进植株生长发育.     

不同施肥制度对石灰性紫色水稻土中氨氧化古菌群落结构的影响

研究不同施肥制度对水稻土氨氧化古菌(AOA)群落结构和垂直分布特征的影响,可以深入认识不同施肥制度下的石灰性紫色水稻土氮素循环特征及微生物驱动机制,为该地区科学施肥、培肥地力提供理论依据。利用化学分析和变性梯度凝胶电泳(DGGE)对不同施肥制度下石灰性紫色水稻土理化性质和AOA群落结构进行了分析。结果显示:相对于无肥处理,施肥会降低石灰性紫色水稻土pH和硝氮含量,而增加土壤有机质、全氮和氨氮含量。伴随土壤深度增加,土壤pH增加,全氮和硝氮含量降低,氨氮含量变化趋势不明显。不同施肥制度在不同土壤深度对石灰性紫色水稻土AOA群落结构产生不同的胁迫效应,不同施肥制度下的AOA群落结构在0—20 cm处差异不明显;土壤深度增加,不同施肥制度下的AOA群落结构表现出明显差异,CK和N肥处理下的AOA群落结构较简单。AOA群落结构多样性指数和丰富度随土壤深度增加而减小。石灰性紫色水稻土AOA与来自不同土壤和水体环境的AOA具有明显相似性。冗余梯度分析(RDA)显示pH(P=0.012)是造成石灰性紫色水稻土AOA群落结构差异的主要原因。研究揭示石灰性紫色水稻土中的AOA群落结构受施肥制度明显影响并表现出明显的垂直分布特征。     

Responses of the fine root morphology and vertical distribution of Populus × euramericana ‘Guariento’ to the coupled effect of water and nitrogen

Aims Irrigation and fertilization have great potentials to enhance yield in forest plantations. The integrated effect of water and nitrogen management on fine roots morphology and distribution of Populus × euramericana ‘Guariento’, however, remains unclear. The objective of this study was to evaluate the effect of water and nitrogen addition on fine root morphology and distribution in poplar plantations for developing the best water and nitrogen strategy for promoting fine root. Methods The soil core method was used to quantify the morphology and distribution of fine roots in the 0–60 cm in a poplar plantation with surface dripping irrigation and fertilization technologies. The experiment included nine treatments, which were a combination of three irrigation treatments where dripping irrigation was applied when soil water potential (ψ_soil) reached –75, –50, or –25 kPa, and three fertilization treatments at nitrogen additions of 150, 300, or 450 g·tree–1·a–1, respectively). A control plot with non-irrigation and non-fertilizationtreatment in growing season (CK) was also included in the study. Important findings The fine roots biomass density, fine root surface area density, average root diameter in all treatments were mainly found at 0–10 cm and 10–20 cm depths, with root biomass density in the 10–20 cm of 1.03 to 1.21 times of that in the 0–10 cm, 1.25 to 1.80 times of that in the 20–30 cm, 1.62 to 22.10 times of that in the 30–40 cm, 2.77 to 54.35 times of that in the 40–50 cm, and 6.48 to 293.09 times of that in the 50–60 cm. The root biomass density in the 10–20 cm accounted for 27%–37% of the total biomass density in the top 60 cm. For root biomass density and average diameter, there were no significant differences between 0–10 cm and 10–20 cm depths, and between 40–50 cm and 50–60 cm depths. Fine roots in the irrigation and fertilization treatments were significantly higher than that of the CK, except the D1F1 treatment (i.e., with low water and low nitrogen level). Additionally, fine roots in the D2F3 treatment (i.e., with intermedia irrigation and high nitrogen level) and the D3F3 treatment (i.e., with high water and high nitrogen level) were significantly higher than those in other treatments, but not significantly different between D2F3 and D3F3. Compared with the CK, the fine roots biomass density in six soil layers were significantly enhanced at 359%, 388%, 328%, 3823%, 4774% and 2866%, respectively, for the treatment with high water and high nitrogen levels. The vertical distributions of fine roots appeared not affected by the interaction of irrigation and nitrogen addition. However, the surface dripping irrigation and fertilization treatments increased fine roots significantly. Finally, we found that the response of fine root growth and distribution was stronger to fertilization than to the irrigation in this poplar plantation.     

盐渍化灌区土壤盐分的时空变异特征及其与地下水埋深的关系

土壤盐分空间变异特征和地下水埋深状况是指导灌区合理用水和防治土壤盐碱化的重要依据。运用经典统计学和地质统计学方法,结合GIS技术,分析了河套灌区沙壕渠灌域0-20 cm、20-40 cm、40-60 cm土壤EC值的空间变异特征及地下水埋深对土壤盐分分布的影响。结果表明:沙壕渠灌域土壤盐分Cv值在不同灌溉时期和不同土壤深度均大于36%,表现为强变异特征;各灌水时期和不同土壤深度土壤EC值均表现为中等强度的空间自相关性,表层0-20 cm土壤空间自相关程度最高;秋浇前不同层次土壤EC值的空间分布在灌域内从南到北呈增大趋势,秋浇后土壤含盐量的高值区在西北部或东北部;土壤盐分受地下水埋深影响显著,灌域内地下水埋深南深北浅,土壤盐分随地下水埋深的增大而减小,二者之间满足指数关系。因此,应采取合理措施控制地下水埋深,防止区域土壤盐渍化加剧。     

微灌与播前深松对根际土壤酶活性和夏玉米产量的影响

为探明微灌与播前深松耕作对夏玉米根际土壤酶活性和产量的影响,以大田夏玉米为研究对象,设计微灌灌溉方式(地表滴灌、地下滴灌和微润灌)、灌水量(分别控制土壤含水量下限为田间持水率的50%、65%和80%)和深松深度(20、40、60 cm)3因素、3水平正交田间试验.结果表明: 夏玉米全生育期内,土壤过氧化氢酶和脲酶活性均呈先增加后减小趋势,磷酸酶活性则呈先减小后增加趋势.地下滴灌0~80 cm生育期平均土壤含水率比地表滴灌和微润灌高6.3%和1.8%,且显著提高土壤脲酶活性、夏玉米根系体积和产量;随着灌水量的增加,土壤磷酸酶活性呈先减小后增加趋势,脲酶活性和产量均呈先增加后减小趋势,生育期平均土壤含水率与根系体积均呈增加趋势;深松40 cm比20 cm的产量和根系体积增加量大于深松60 cm比40 cm的增加量,深松40 cm土壤酶活性较高.从提高水资源、氮肥利用率及作物产量角度考虑,该地区夏玉米种植的最优组合应为地下滴灌、灌水下限为田间持水率的65%与播前深松40 cm.     

黄土塬区不同土地利用方式土壤水分消耗与补给变化特征

对黄土塬区不同土地利用方式下2012年3—10月7龄果园(挂果初期)、17龄果园(盛果期)、小麦地、玉米地土壤水文状况进行分析,结果显示,0—600 cm试验土层7龄果园土壤贮水量最高,其次为玉米地、小麦地,17龄果园最低,且不同土地利用方式下贮水量随着降水量的变化而上下波动,但其变化滞后于降水。不同土地利用方式均表现为随土壤深度增加土壤含水量变异程度减弱的特征,且其土壤剖面的水分含量变化存在季节变异。农田和7龄果园中不存在土壤干燥化现象,而17龄果园土壤剖面存在较厚的干燥化土层,其分布深度为320—600 cm。不同的土地利用方式的土壤水分的消耗和补充深度有较大差异,17龄果园消耗深度为500 cm,补充深度为200 cm;7龄果园、玉米地和小麦地消耗深度分别为200、300 cm和300 cm,且补充深度均超过了测定的土壤深度,大于600 cm。     

Effect of Irrigation Type on Inoculum Density of Macrophomina phaseolina in Melon Fields in Arizona

Charcoal rot, caused by Macrophomina phaseolina, has become increasingly problematic for melon growers using subsurface drip irrigation in Arizona; but has rarely been observed in fields with furrow irrigation. Since the relationship between increasing incidence of charcoal rot on melon and irrigation type is unknown, studies were initiated to determine the effects of edaphic factors on inoculum density. Soil samples were collected once from fields irrigated by subsurface drip, with and without plastic mulch, and by furrow at 10, 20 and 30 cm depths. Samples were analysed for percentage soil moisture, pH, salinity and inoculum density. Percentage soil moisture was significantly higher at 20 and 30 cm depths in the furrow‐irrigated field compared with the drip‐irrigated field with plastic mulch, but not in the field without plastic mulch. Average minimum and maximum temperatures and inoculum density were significantly lower at all three depths in the furrow‐irrigated field compared with both types of drip irrigation. pH was significantly higher in the furrow‐irrigated field compared with both types of drip irrigation at 20 and 30 cm depths but not at 10 cm depth. Differences in inoculum densities of M. phaseolina suggest that drip irrigation may contribute to higher disease incidences.     

宁南旱区耕作覆盖对马铃薯产量及土壤水热特征的影响

为探究耕作覆盖对土壤水热及旱作马铃薯产量的影响,连续2年在宁南旱区不同耕作深度结合覆盖模式下开展了研究工作。结果表明: 耕作深度、覆盖材料对马铃薯播种期0～100 cm土层土壤贮水量有极显著影响,而二者交互作用无显著影响;2019年土壤贮水量以深松30 cm覆盖地膜处理最高,2020年以深松40 cm覆盖秸秆处理较高,分别较翻耕15 cm不覆盖处理(对照)显著提高16.9%和33.4%;耕作深度、覆盖材料可显著影响马铃薯关键生育期土壤贮水量;同一耕作深度下土壤贮水量以秸秆、地膜覆盖处理效果较好,同一覆盖材料下以深松30～40 cm处理最佳。覆盖材料、耕作深度与覆盖材料二者交互作用对播种-现蕾期0～25 cm土层土壤有效积温影响显著;同一耕作深度下覆盖地膜处理土壤有效积温平均较不覆盖处理显著增加9.3%,而覆盖秸秆处理较不覆盖处理显著降低18.7%;2019和2020年各处理全生育期土壤有效积温分别以深松30 cm和深松40 cm覆盖地膜处理最高。2019年马铃薯总产量和经济效益以深松30 cm覆盖秸秆处理较高,分别较对照显著提高84.6%和107.9%;2020年以深松40 cm覆盖秸秆处理最佳,分别较对照显著提高81.7%和105.7%。耕作深度、覆盖材料对作物水热利用效率均有显著影响,水分利用效率以深松30～40 cm覆盖秸秆处理较高,而积温利用效率不同耕作深度结合秸秆覆盖各处理均较翻对照显著提高。相关分析表明,块茎形成期的土壤水分和有效积温对马铃薯总产量的形成至关重要,而全生育期土壤水分对总产量的影响高于土壤有效积温。可见,深松30～40 cm覆盖秸秆处理可改善土壤水热状况,实现马铃薯增产增收和水热资源的高效利用,在宁南半干旱区马铃薯生产中有一定的应用推广价值。     

宁夏平原北部地下水埋深浅地区不同灌木的水分来源

宁夏平原北部引黄灌区地下水埋深浅是该地区土壤盐碱化的主要原因, 种植耐盐植物可以吸收利用地下水, 在降低地下水位的同时可以减少对地面灌溉的依赖。为了分析银川平原北部4种灌木对不同水源的利用特征, 于2010年生长季测定了灌溉前后20年生多枝柽柳(Tamarix ramosissima)、3年生多枝柽柳、3年生宁夏枸杞(Lycium barbarum)和3年生四翅滨藜(Atriplex canescens)木质部水及不同潜在水源稳定氧、氢同位素组成(δ¹⁸O和δD), 应用IsoSource同位素线性混合模型估算了不同灌木对不同水源的利用率。同时测定了0-200 cm土壤剖面的全盐含量、含水量和pH值以及灌溉前后光合气体交换参数。结果表明: 不同深度土壤水δ¹⁸O和δD值存在较大差异, 并呈规律性变化。土壤水δ¹⁸O和δD值随深度加深呈逐渐降低的趋势。灌溉后80 cm以上土壤水δ¹⁸O和δD值低于灌溉前。无论灌溉前还是灌溉后, 20年生多枝柽柳与3年生灌木相比具有更低的δ¹⁸O和δD值。灌溉前, 3年生多枝柽柳、宁夏枸杞和四翅滨藜主要利用表层土壤水(70.1%、52.3%和48.9%); 20年生多枝柽柳对地下水的利用率最高(21.5%)。灌溉后, 3年生多枝柽柳和宁夏枸杞对80-140 cm土壤水利用率较高(59.5%和58.8%)。20年生多枝柽柳对地下水的利用率最高(18.3%)。灌溉前, 20年生多枝柽柳净光合速率、气孔导度和蒸腾速率显著高于其他3种灌木, 灌溉后3年生四翅滨藜净光合速率最高。灌溉对3年生多枝柽柳和宁夏枸杞的净光合速率和气孔导度有显著影响。无论灌溉前还是灌溉后, 3年生四翅滨藜瞬间水分利用效率均高于其他3种灌木。研究表明, 不同灌木在不同水分条件下水分利用策略不同, 这主要与植物种类及树龄有关。灌溉前幼龄多枝柽柳凭借其对干旱较强的忍耐能力利用浅层不饱和土壤水, 灌溉后其又转而利用中层土壤水, 表现出潜水湿生植物的特征, 主要吸收利用深层土壤水分, 对灌溉反应不明显。     

Seasonal changes in water source of four families of loblolly pine (<Emphasis Type="Italic">Pinus</Emphasis><Emphasis Type="Italic">taeda</Emphasis> L.)

Source water utilized by four families of loblolly pine (Pinus taeda L.) was assessed by comparing the H isotope composition ('D) of xylem sap and of soil water from four depths (0-20 cm, 20-40 cm, 1.2 m, and 2.1 m) across 1 year. Soil water 'D values varied with soil moisture content in the well-drained, sandy site and at each of the four soil depths. In September and November 1997 and May through November 1998, xylem sap 'D values closely matched the soil water 'D values of the upper soil horizons (0-20 and 0-40 cm) and, therefore, reflected significant water uptake from upper regions of the soil profile. In March 1998, xylem sap 'D values closely matched the soil water 'D values of the 1.2 m soil depth and, therefore, indicated that trees during this portion of the growing season were obtaining their water from deep in the soil profile. Analysis of source water use with a two-ended mixing model in the 3 months of collection that exhibited a range of soil water 'D values across the soil profile confirmed that trees utilized different sources of water depending upon season of the year. In September 1997 and November 1998, source water uptake was primarily from the upper soil profile while in March 1998, source water uptake was from deep in the soil profile. With few exceptions, we did not find striking differences in source water use between drought-hardy families and those that were locally adapted.     

Tomato root distribution, yield and fruit quality under subsurface drip irrigation

Tomato rooting patterns were evaluated in a 2-year field trial where surface drip irrigation (R0) was compared with subsurface drip irrigation at 20 cm (RI) and 40 cm (RII) depths. Pot-transplanted plants of two processing tomato, `Brigade' (C1) and `H3044' (C2), were used. The behaviour of the root system in response to different irrigation treatments was evaluated through minirhizotrons installed between two plants, in proximity of the plant row. Root length intensity (L _a), length of root per unit of minirhizotron surface area (cm cm^–2) was measured at blooming stage and at harvest. For all sampling dates the depth of the drip irrigation tube, the cultivar and the interaction between treatments did not significantly influence L _a. However differences between irrigation treatments were observed as root distribution along the soil profile and a large concentration of roots at the depth of the irrigation tubes was found. For both surface and subsurface drip irrigation and for both cultivars most of the root system was concentrated in the top 40 cm of the soil profile, where root length density ranged between 0.5 and 1.5 cm cm^–3. Commercial yields (t ha^–1) were 87.6 and 114.2 (R0), 107.5 and 128.1 (RI), 105.0 and 124.8 (RII), for 1997 and 1998, respectively. Differences between the 2 years may be attributed to different climatic conditions. In the second year, although no significant differences were found among treatments, slightly higher values were observed with irrigation tubes at 20 cm depth. Fruit quality was not significantly affected by treatments or by the interaction between irrigation tube depth and cultivar.