三峡库区消落带土壤水分变化对落羽杉（Taxodium distichum）幼苗根部次生代谢物质含量及根生物量的影响

模拟三峡库区消落带土壤淹水变化特征设置了常规生长水分条件(CK组,土壤含水量为田间持水量的60%～63%)、轻度干旱水分胁迫(T1组,土壤含水量为田间持水量的47%～50%)、土壤水饱和(T2组,土壤表面一直处于潮湿状态)以及水淹(T3组,苗木根部淹水超过土壤表面1cm)4个不同处理组,研究落羽杉当年实生幼苗根部次生代谢物质含量与生物量的变化(均以干重计)。研究表明,不同水分处理对落羽杉幼苗主根、侧根和根部苹果酸、莽草酸含量以及生物量的影响程度有所差异,其中以T3组受到的影响最为明显。主根苹果酸、莽草酸含量在整个试验期的总体平均值,T3组显著低于CK组,分别达28.0%和16.4%;相反侧根苹果酸、莽草酸总体平均含量T3组则极其显著地高于CK组分别达105.7%和152.6%,根部平均值T3组显著地高于CK组分别达32.7%和26.2%。与之形成鲜明对比,主根、侧根和根部苹果酸、莽草酸含量在整个试验期的总体平均值,T1、T2与CK组相互之间分别均无显著差异。各处理组之间主根生物量没有显著差异;与CK和T1组相比,T3组侧根生物量分别降低38.3%和40.8%,根部生物量分别降低31.9%和31.1%,但与T2组相比均未达到显著差异。主根苹果酸含量与根系各部分莽草酸含量和生物量之间均无显著相关性,相反侧根、根部的苹果酸与莽草酸含量以及二者与生物量相互间均表现出显著或极显著相关性。在三峡库区消落带土壤含水量变化条件下,落羽杉幼苗将充分利用侧根增强代谢适应调节能力,通过产生大量苹果酸和莽草酸、减少根部生物量积累适应根部水淹环境,通过维持与CK组同样水平的代谢和生长而适应轻度干旱与饱和水环境。     

土壤水分交替变化对湿地松幼苗光合特性的影响

以盆栽湿地松幼苗为材料,通过实验室模拟三峡库区从水淹到干旱的过程,设置常规供水(CK)、常规供水-轻度干旱-复水(DR),水淹(FL),水淹-轻度干旱-复水(FD)4个实验组,研究土壤水分交替变化对湿地松幼苗光合参数及叶绿素含量的影响.结果表明:(1)不同土壤水分处理条件对湿地松幼苗的净光合速率、气孔导度、蒸腾速率、胞间CO2浓度、气孔限制值、水分利用效率和光合色素含量都有一定影响.(2)在实验的前中期,DR、FL和FD组湿地松幼苗的光合速率、气孔导度、蒸腾速率都显著下降,DR和FD在实验后期回升到较高水平.(3)在整个实验期间各处理组的水分利用效率较对照都有不同程度上升,并以DR组的最大(4.95μmol·mmol-1).(4)随着处理时间延长,各处理组湿地松幼苗的总叶绿素含量及叶绿素a/b值均呈先降后升的趋势,其中叶绿素/类胡萝卜素的比值在4.379～6.019间波动,而叶绿素a/b值则在2.207～2.850间波动.研究发现,湿地松幼苗在水分代谢、光合生理等方面等能够很好地适应水淹以及"淹-干"的水分交替变化环境,并且在解除胁迫后能够迅速恢复生长,可以考虑用于三峡库区消落带的植被修复和重建.     

水淹对枫杨幼苗光合生理特征的影响

通过设置对照(CK)、连续性水淹(CF)和间歇性水淹(PF)3个水分处理,模拟三峡库区库岸带土壤水分变化,研究乡土树种枫杨当年实生幼苗的生理生态适应机制.结果表明:不同水分处理均显著影响枫杨幼苗的光合作用、生物量积累和生长.与CK相比,CF和PF组枫杨幼苗除胞间CO2浓度升高,净光合速率(Pn)、气孔导度(gs)均显著降低.其变化趋势是枫杨幼苗的Pn、gs在试验初期下降,然后逐渐恢复或趋于稳定.随着处理时间的延长,CF和PF组枫杨幼苗的总生物量、根生物量、茎生物量、叶生物量、株高和地径均呈现上升趋势.CF和PF组的总生物量、根生物量、叶生物量和株高,以及PF组的茎生物量均显著低于CK,而CF组的茎生物量与CK无显著差异,其地径还高于CK.枫杨幼苗具有耐受水湿而不耐水淹-干旱交替的生理生态特征.     

水淹对枫杨幼苗光合生理特征的影响

通过设置对照(CK)、连续性水淹(CF)和间歇性水淹(PF)3个水分处理,模拟三峡库区库岸带土壤水分变化,研究乡土树种枫杨当年实生幼苗的生理生态适应机制.结果表明: 不同水分处理均显著影响枫杨幼苗的光合作用、生物量积累和生长.与CK相比,CF和PF组枫杨幼苗除胞间CO₂浓度升高,净光合速率(P_n)、气孔导度(g_s)均显著降低.其变化趋势是枫杨幼苗的P_n、g_s在试验初期下降,然后逐渐恢复或趋于稳定.随着处理时间的延长,CF和PF组枫杨幼苗的总生物量、根生物量、茎生物量、叶生物量、株高和地径均呈现上升趋势.CF和PF组的总生物量、根生物量、叶生物量和株高,以及PF组的茎生物量均显著低于CK,而CF组的茎生物量与CK无显著差异,其地径还高于CK.枫杨幼苗具有耐受水湿而不耐水淹-干旱交替的生理生态特征.     

落羽杉根系有机酸与NSC代谢对三峡消落带水位变化的响应

为探究三峡库区消落带水位变化下落羽杉根系有机酸和非结构性碳水化合物(NSC)的响应特征,以适生木本植物落羽杉为对象,在消落带原位环境中设置对照-SS(海拔175 m,试验期间无水淹)、MS(海拔170 m,中度水淹胁迫)和DS(海拔165 m,深度水淹胁迫)3个处理,分别于海拔170 m和165 m退水时采集样品,测定并分析根系有机酸和NSC的变化。结果表明:(1)库区水淹对落羽杉基径无显著影响,仅有DS组明显抑制了高生长,落羽杉生长能较积极地响应库区水淹。(2)库区水淹对落羽杉侧根和总根有机酸的影响一致,侧根有机酸代谢作用优于主根。与SS组相比,MS组根系有机酸含量增高,DS组根系有机酸含量降低,除部分根系酒石酸、苹果酸、柠檬酸变化达到显著水平外,其余有机酸均无显著变化。(3)库区不同强度水淹对落羽杉根系NSC有不同程度的影响。与SS组相比,MS组可溶性糖无显著变化,淀粉、NSC含量显著增加,但总根NSC在水淹前与水淹后无明显差异;形成鲜明对比的是,DS组显著降低了可溶性糖、NSC含量,对淀粉无显著影响,且水淹后总根NSC显著低于水淹前。(4)相关分析表明,主根、总根草酸、苹果酸、柠檬酸及侧根、总根莽草酸分别与淀粉、NSC间表现出显著相关性(P0.05)。研究结果表明,在三峡库区消落带水淹胁迫下,落羽杉根系有机酸与NSC代谢联系紧密。通过维持一定的根系淀粉含量,保持植株正常的有机酸代谢水平,较好地适应三峡库区消落带生境。     

枫杨幼苗对土壤水分"湿-干"交替变化光合及叶绿素荧光的响应

以盆栽1年生枫杨幼苗为实验材料,通过人工设置土壤水分来模拟三峡库区消落带不同土壤水分对枫杨幼苗的光合参数、光合色素含量、叶绿素荧光特性等的影响.试验设置4个处理组,分别为常规供水、常规供水-轻度干旱-复水、水淹、水淹-轻度干旱-复水,3个处理期分别为前期(0-33 d)、中期(34-63 d)、后期(64-78 d).结果表明,不同的水分处理显著地影响了枫杨幼苗“表观性”的气体交换、光合色素含量和水分利用效率等特性,但相较而言对枫杨幼苗“内在性”的叶绿素荧光特性影响较小,且影响的结果和程度因处理组和指标而异.78 d时,除胞间CO2浓度(Gi)、叶绿素a/叶绿素b、光化学猝灭值(qP)和非光化学淬灭值(qN)外,水淹组(FL组)的各项指标在4个处理组中都为最低值;“湿-干”交替组(FD组)的净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)及总叶绿素含量则表现出先降低复水后显著增加的趋势;DR组的变化趋势与FD组类似,但变化的幅度较FD组小.研究发现,枫杨幼苗面对不同水分状况呈现出了一定的敏感特性,但随着胁迫时间的延长其无论是从光合、水分利用还是叶绿素荧光特性方面都表现出积极的响应,较能适应干旱、水淹、“湿-干”交替等多种环境胁迫,且在胁迫解除后能够迅速恢复生长,可以考虑用于三峡库区消落带的植被重建.     

土壤水分对湿地松幼苗光合特征的影响

通过设置常规供水(CK)、轻度干旱(T1)、水饱和(T2)、水淹(T3)4个处理组,研究湿地松当年实生幼苗在不同土壤水分条件下的光合生理响应及叶绿素荧光特性。结果表明:不同水分处理对湿地松幼苗的叶片气体交换参数、水分利用效率(WUE)、光合色素、叶绿素荧光参数等指标有不同的影响;其中,T3的光合色素含量最低;T2、T3组的湿地松幼苗表现出较低的净光合速率(Pn)、电子传递速率(ETR)和PSⅡ光化学的量子效应(ΦPSⅡ),但与其他耐水淹植物相比,T3条件下的湿地松幼苗仍具有较高的Pn,说明湿地松幼苗具有较强的耐水淹能力;在T1条件下,湿地松幼苗具有较高的WUE和较低的蒸腾速率(Tr)、气孔导度(Gs)以对抗干旱的逆境,其Pn、PSⅡ最大光化学效率(Fv/Fm)、ETR和ΦPSII均有所下降,但仍能维持在相对正常的水平。研究证明,湿地松幼苗具有一定的耐淹耐旱特性,可运用于三峡库区消落带的植被重建。     

不同施水量对云杉幼苗生长和生理生态特征的影响

在中国科学院成都生物研究所茂县生态站,参照云杉分布区的年降水量,设置4种水分处理梯度(分别模拟年降水量为350mm、700mm、1000mm和1350mm),研究云杉幼苗的生长和生理特征差异。经过4a的研究,结果表明,不同施水量显著影响了云杉幼苗的株高、基径、生物量积累(叶重、茎重和根重)、主根长度、第一级侧根数量、气体交换、叶绿素含量、脯氨酸以及丙二醛含量。700mm施水量的云杉幼苗的以上参数显著高于其他3个施水量(350mm、1000mm和1350mm)的幼苗。干旱胁迫下,云杉幼苗净光合速率和蒸腾速率显著降低,抑制了云杉幼苗生物量积累;过量施水则降低了云杉幼苗的根生长。云杉幼苗通过调节水分利用效率来适应不同的水分条件,当受到干旱胁迫时,通过提高水分利用效率来提供生长所需要的水分;然而当水分充足的时候,水分利用效率又降低。此外,水分不足和过量均导致针叶叶绿素含量降低,同时引起丙二醛含量的增加,表明云杉幼苗不适宜在土壤过于干旱和湿润的条件下生长。     

胡杨幼苗根系生长与构型对土壤水分的响应

胡杨实生幼苗成活率低是制约其更新与人工育苗保存的关键问题,而幼苗根系生长与构型是影响其存活的重要因素。该试验以1年生胡杨幼苗为材料,通过2种给水方式(断续给水和连续给水)下各6个土壤水分梯度处理的控制试验,探究胡杨幼苗根系生长与构型对荒漠地区关键因子水分的响应特征。结果表明:(1)2种给水方式下干旱胁迫均使根冠比增加,且断续给水处理下幼苗根冠比显著大于连续给水。(2)一定程度的干旱处理还可以促进幼苗根系形态发育特征的发展和根系生物量的积累,但过度干旱胁迫或土壤水分含量过多都会抑制根系生长,并以连续给水、土壤含水量15%处理下幼苗根系最为发达。(3)幼苗深扎根能力强,其根宽深比在2种给水方式下均小于1,且断续给水处理显著小于连续给水处理;2种给水方式下根宽深比都与土壤水分含量呈显著正相关。(4)根系拓扑指数在2种给水方式下无显著差异且均接近1,但都与土壤水分含量呈显著负相关。即幼苗根系趋向鱼尾状分支结构,次级分支少,这种根系延伸策略有利于胡杨幼苗在干旱贫瘠的土壤环境中生存。(5)根系构型参数的主成分分析显示,总根长、总根表面积、根宽深比和拓扑指数在2种给水方式下都能很好地表示胡杨幼苗根系构型特征。可见,胡杨幼苗根系通过构筑鱼尾状分支结构、增加垂直根纵向延伸能力和增大根冠比适应干旱环境;水分对于胡杨幼苗根系生长与构型作用显著,根系对水分因子的响应对于胡杨幼苗适应水分异质性环境具有重要意义。     

模拟三峡库区消落带土壤水分变化对落羽杉幼苗光合特性的影响

为三峡库区消落带植被恢复建设进行适生树种优选,本研究模拟三峡库区消落带土壤水分变化特征设置了常规生长水分条件、轻度干旱水分胁迫、土壤水饱和以及水淹4个不同处理组,研究落羽杉当年实生幼苗光合特性以及生理生态适应机理。研究结果表明,不同水分处理均显著影响落羽杉幼苗光合色素、叶片气体交换以及资源利用效率。其中,水淹处理组光合色素含量一直处于最低,受到的影响最大且最为明显;与轻度干旱组和水饱和处理组在干重条件下的光合色素含量和对照组并无显著差异形成鲜明对比。各组叶绿素a与b比值介于2.043~2.691之间,叶绿素与类葫萝卜素含量比则介于3.079~4.514之间。在轻度干旱水分胁迫环境下,落羽杉幼苗表现出较低的光能利用效率、CO2利用效率和净光合速率,其净光合速率比正常下降24.9%;相反在土壤饱和水与水淹环境下,其光能利用效率、CO2利用效率和净光合速率并未受到显著影响,仍保持与正常生长条件下一致的水平。在整个实验期,落羽杉幼苗各组的水分利用效率均随时间延长而持续增加,以水淹组增幅最小,常规生长组最大。研究证实落羽杉树种具有喜水和耐水淹生理学特性,完全可以考虑将落羽杉树种列为三峡库区消落带防护林体系建设树种之一,但应避免将其置于干旱环境之中。     

Non-hydraulic regulation of fruit growth in tomato plants (Lycopersicon esculentum cv. Solairo) growing in drying soil

Tomato (Lycopersicon esculentum cv. Solairo) fruit growth, fruit mesocarp and leaf epidermal cell turgor, and fruit and leaf sub-epidermal apoplastic pH were monitored as plants were allowed to dry the soil in which they were rooted. Soil drying regimes involved splitting the root system of plants between two halves of a single pot separated by a solid impervious membrane to form a split-root system. Plants were then allowed to dry the soil in both halves of the pot (a soil-drying (SD) treatment) or water was supplied to one-half of the pot (a partial root-drying (PRD) treatment), allowing only one-half of the root system to dry the soil. A well-watered control treatment watered the soil on both halves of the pot. The rate of fruit growth was highly correlated with the soil water content of both sides of the SD treatment and the dry side of the PRD treatment. Soil drying caused a significant restriction in fruit growth rate, which was independent of any changes in the turgor of expanding fruit mesocarp cells in the PRD treatment. By supplying water to half of the root system, the turgors of mesocarp cells were maintained at values above those recorded in well-watered controls. The turgor of leaf epidermal cells exhibited a similar response. The pH of the sub-epidermal apoplastic compartment in leaves and fruit increased with soil drying. The dynamics of this increase in leaves and fruit were identical, suggesting free transport of this signal from shoot to fruit. Fruit growth rate and sub-epidermal pH within the fruit showed a strong correlation. The similarity of fruit growth response in the SD and PRD treatment, suggests that tomato plants respond to a discrete measure of soil water status and do not integrate measures to determine total soil water availability. The results of this study are not consistent with Lockhartian models of growth regulation in expanding fruit of a higher plant. A non-hydraulic, chemical-based signalling control of fruit growth in plants growing in drying soil is proposed.     

Deficit and excess of soil water impact on plant growth of Lotus tenuis by affecting nutrient uptake and arbuscular mycorrhizal symbiosis

The impact of deficit and excess of soil water on plant growth, morphological plant features, N and P plant nutrition, soil properties, Rhizobium nodulation and the symbiosis between arbuscular mycorrhizal (AM) fungi and Lotus tenuis Waldst. & Kit. were studied in a saline-sodic soil. Water excess treatment decreased root growth by 36% and increased shoot growth by 13% whereas water deficit treatment decreased both root and shoot growth (26 and 32%, respectively). Differences between stress conditions on shoot growth were due to the ability of L. tenuis to tolerate low oxygen concentration in the soil and the sufficiency of nutrients in soil to sustain shoot growth demands. Water excess treatment decreased pH, and increased available P and labile C in soil. Water deficit treatment decreased available P and also increased labile C. In general, N and P acquisition were affected more by water excess than water deficit. The number of nodules per gram of fresh roots only increased in water excess roots (97%). Under both stress conditions there was a significant proportion of roots colonized by AM fungi. Compared to control treatment, arbuscule formation decreased by 55 and 14% under water excess and water deficit, respectively. Vesicle formation increased 256% in water excess treatment and did not change under water deficit treatment. L. tenuis plants subjected to water deficit or excess treatments could grow, nodulated and maintained a symbiotic association with AM fungi by different strategies. Under water excess, L. tenuis plants decreased root growth and increased shoot growth to facilitate water elimination by transpiration. Under water deficit, L. tenuis plants decreased root growth but also shoot growth which in turn significant decreased the shoot/root ratio. In the present study, under water excess conditions AM fungi reduced nutrient transfer structures (arbuscules), the number of entry points and spore, and hyphal densities in soil, but increased resistance structures (vesicles). At water deficit, however, AM fungi reduced external hyphae and arbuscules to some extent, investing more in maintaining a similar proportion of vesicles in roots and spores in soil compared to control treatment.     

控制性分根交替灌溉下氮形态对番茄生长、果实产量及品质的影响

以高产大果型西红柿品种中研988为材料,采用分根培养的方法,研究了控制性分根交替灌溉(APRI)条件下,不同氮素形态(硝态氮、铵态氮)对番茄生长、产量及果实品质的影响.结果表明: 同一灌溉方式或下限处理下,铵态氮对番茄植株前期生长有利,而硝态氮促进番茄植株后期生长,并促进果实产量增加.在APRI同一灌水下限下,硝态氮处理可提高果实维生素C含量及糖酸比,提高营养品质.同一氮素形态供应下,APRI番茄的株高和叶面积均小于正常灌溉(CK),但灌水下限为60%田间持水量(θ_f)的APRI处理番茄茎粗在生长后期有所增加.在同一氮素形态下,与CK相比,APRI各处理的产量均下降,其中灌水下限在40%θ_f的APRI处理产量下降了22.4%～26.3%;而灌水下限在60% θ_f的APRI处理仅下降了5.3%～5.4%,下降幅度相对较小,而品质显著提高,并具有明显的节水效果.因此,控制灌水下限在60%θ_f、供应硝态氮的APRI处理为番茄高产、优质、节水的最佳处理.
     

土壤湿度对香樟幼苗根系生长和构型的影响

以1年生香樟(Cinnamomum camphora)幼苗为试材,设置对照组(CK)、中度干旱处理(M)、重度干旱处理(S)三个处理,比较不同土壤湿度下香樟幼苗不同时期地上部分生长和根系构型,探究香樟幼苗根系对不同土壤湿度的适应性及其耐旱机制。结果表明,中度和重度干旱处理组的香樟根系及地上部分干物质积累、根系长度、根系表面积、根系直径和根尖数均显著小于对照组(P<0.05)。同时干旱显著增加香樟幼苗的根系拓扑指数,降低香樟根的分形维数和平均分枝角度(P<0.05)。可见土壤湿度程度及处理时间显著影响香樟根系的生长及在土壤中的布局。较低土壤湿度可显著抑制根长的延长、根表面积扩大和根的增殖,且随着土壤湿度的继续降低以及处理时间延长,香樟幼苗根系的生长受到水分亏缺的抑制作用加重,根系建成成本增高的同时,根系分枝的复杂性降低,根系必须通过朝着更陡、更深的方向生长伸长来提高水分吸收效率。建议在园林绿化工程养护过程中制定科学的水分管理策略,以满足香樟生长过程中对土壤水分的需要。     

Effects of submergence on photosynthesis and growth of <Emphasis Type="Italic">Pterocarya stenoptera</Emphasis> (Chinese wingnut) seedlings in the recently-created Three Gorges Reservoir region of China

Chinese wingnut (Pterocarya stenoptera) is the dominant native tree species in the riparian zone of the Three Gorges Reservoir region of China. Water treatments of continuous wet soil (WS) and submergence of the soil (SS) were imposed on 4-month-old Chinese wingnut seedlings for 12 months. The effects of water treatment on photosynthesis and growth were investigated after 2 and 12 months compared to a control (C). Submergence of the soil resulted in significant reductions in net photosynthetic rate (Pn), and stomatal conductance (g _s) as compared to C. However, stomatal conductance in wet soil treatment was maintained comparable to that of C, although net photosynthetic rate was reduced significantly. Overall, intrinsic water use efficiency (WUE _i ) under submergence of the soil was not significantly different from that of C, but significantly higher than that of the wet soil treatment. The intrinsic water use efficiency in the wet soil treatment was also significantly decreased compared to that in the control. During the entire experiment, growth and biomass of Chinese wingnut seedlings were significantly reduced due to adverse impacts of the submergence of the soil or wet soil treatment. These results suggest that Chinese wingnut seedlings less than 1-year-old would probably need intensive soil water management for sound growth. In the Three Gorges Reservoir region, adequate draining activities should be considered for this species’ regeneration.     

Effect of soil water content on the gravitropic behavior of nodal roots in maize

The direction of root growth is an important factor that determines the spatial distribution of roots in the soil. The influence of soil water content on the direction of growth of maize nodal roots was studied both in the field and in the greenhouse. In the field experiment, the one plot was regularly irrigated (I-plot) and the other non-irrigated (N-plot). In the greenhouse experiment, three water treatments were conducted on plants grown in pots: continuously wet (CW), early drying (ED), and late drying (LD). The direction of root growth was quantified by the angle from the vertical, measured at 1 cm intervals for 10 cm from the first five internodes. Nodal roots grew more vertically in the N-plot and ED treatment than those in the I-plot and CW treatment. This was due to the decrease of the initial angle and/or the liminal angle. It is therefore thought that two events regulate the growth direction of nodal roots under dry soil conditions: gravitropic bending at root emergence from the stem and the later establishment of the angle of growth. Nodal roots appearing after rewatering in the ED treatment grew in a similar direction as those in the CW treatment. It follows from this that the water content of the surrounding soil has a direct effect on the direction of growth. Nodal roots that emerged in rapidly drying soil in the LD treatment ceased growing after showing negative gravitropism. The possible mechanisms determining the growth direction of nodal roots in drier soils are discussed.     

Response of Soybean in Cyst Nematode-Infested Soils at Three Soil Water Regimes

Large pot (2 years) and field experiments (1 year) were conducted to determine the response of susceptible soybean Glycine max (L.) Merr. cultivars (Essex and Hutcheson) grown in soybean-cyst-nematode (SCN), Heterodera glycines-infested soils at three soil water regimes. The soil water regimes were irrigation whenever soil water potential ([psi]s) 0.30-m deep was i) -30 kPa (I-30) or ii) - 50 kPa (I-50), and iii) no irrigation. Cyst nematode levels in the pot experiment were either 0 or 20,000 second-stage juveniles (J2) per pot. The field experiment was conducted on soil naturally infested with a population of 145 to 475 cysts L⁻¹ of soil. All growth parameters studied were drastically affected in the presence of SCN under nonirrigated conditions for the large pot tests; however, SCN did not influence growth parameters in the field experiment. Seed yield was lowest in the no irrigation treatment when all treatments were compared in both the pot and field experiments. The infested no irrigation treatment in the pot experiment had the lowest yield among soil water treatments.     

土壤深层供水对冬小麦干物质生产的影响

采用根系研究装置研究了土壤深层供水对冬小麦干物质生产的影响 .结果表明 ,上层低湿度下层高湿度的处理在小麦灌浆期仍然保持了较高的土壤和叶片含水量 ,具有发达的根系 ,特别是 1m以下的根量在 4个处理中为最高 ,旗叶和穗的干重也最大 ,具有最大的产量潜力 .本研究表明 ,上层土壤较干下层土壤湿润有利于发挥小麦根信号的积极作用 ,平衡水分利用 ,同时通过对土壤水分的合理调节可以促进深层根的发育 ,有利于提高产量和水分利用效率 .     

疏花水柏枝幼苗生物量与构件对模拟土壤地下水位变化的响应

通过模拟不同地下水位的方法,对疏花水柏枝（Myricaria laxiflora（Franch.）P.Y.Zhang et Y.J.Zhang）一年生幼苗在不同条件下地上与地下部生物量及构件的变化进行测定,分析幼苗生长对地下水位变化的响应。结果显示：随着地下水位的降低,疏花水柏枝幼苗的生长特征指标均呈先增加后减少的趋势,其中地上、地下部分生物量的最高值分别为0.0438、0.0100 g,最低值分别为0.0177、0.0026 g。幼苗地上部生物量在-10 cm处理水平最高;地下部生物量在-15 cm处理水平最高。幼苗直径、根表面积、株高、主根长度、根体积、一级枝数、二级枝数等指标也分别在-10 cm或-15 cm处理水平达到最高值。疏花水柏枝幼苗主要构件的生长与地下水位的变化存在显著相关性。主成分分析结果表明,幼苗的地下部分更容易受到土壤地下水位变化的影响,幼苗性状症候群随地下水位的变化而发生移动,说明该物种幼苗在不同地下水位时的生长投资策略具有较大差异。