非充分灌溉及其生理基础

介绍了非充分灌溉的概念及内涵,主要阐述了在非充分灌溉条件下,作物体内产生的适应性生理反应,经非充分灌溉及轻度干旱处理,作物气孔阻力增加,蒸腾失水减少,作物水分散失对气孔开度的依赖性大于光合对其的依赖性。可通过气孔调节作物光合与水分的关系,最终提高作物的水分利用效率;有限度的水分亏缺,有利于同化物向籽粒调运,利用^14CO2标记研究表明,生长后期水分亏缺下,小麦体内存在对花前营养器官“临时库”同化物的再动员和对产量的补偿机制;适度水分亏缺促进了小麦等作物初生根的生长发育,增加深层土壤中的根系与根系活性,防止后期根系早衰。总之,在非充分灌溉条件下,作物能够在营养生长,物质运输和产量形成等方面产生有效的补偿机制,可作为非充分灌溉的重要理论基础。     

土壤干旱条件下磷素营养对春小麦水分状况和光合作用的影响

研究了土壤干旱条件下磷素营养对春小麦水分状况和光合作用的影响。结果表明：土壤干旱下,磷素营养明显改善了春小麦的水分状况,维持了较高的ψｗ和ＲＷＣ,并因而导致了较高的净光合速率和较大的气孔开度。不同干旱程度下,限制春小麦光合的因子并不相同,轻度干旱下,光合降低主要是气孔的作用,而严重干旱下则主要是非气孔因子的作用。无论何种水分水平下,施磷处理的净光合速率皆高于不施磷处理,与其较大的气孔导度和叶肉光合     

开花、结荚期水分胁迫对蚕豆的生理效应

蚕豆从始荚至盛英期对水分胁迫最敏感,这时期缺水使生物产量和籽粒产量分别降低32.01％和44.92％,绿叶面积、叶绿素含量、比孔面积及净光合速率减少幅度最大,但气孔密度增加,是大田灌水的最关键时期。蚕豆开花进度可用Logistic曲线描述。干旱促进开花进程,降低植株氮磷钾含量,叶片磷钾含量与单株种子数相关。     

蚕豆碳氮含量变化与幼蕾,花荚脱落的关系（简报）

蚕豆分枝期和鼓粒期植株可溶性糖含量各有一个高峰期,始花期含量最低;全氮含量从分枝至结英期呈逐渐下降趋势。植株碳氮比主要受可溶性糖含量影响最大,鼓粒期比值最高。不同产量类型田块的植株碳氮比与蕾花荚脱落率呈负相关,相关系数为 -0.809～-0.890。     

改变源-库比率对蚕豆花荚脱落的影响

蚕豆多花而不多实,有效荚不足现蕾数的15％。高脱落低结荚率是限制蚕豆产量的重要因素,也是生产上长期没有解决的问题。有关大豆与棉花生殖器官脱落的原因及减少脱落的措施已有不少研究,认为生殖生长期养分供不应求,源的限制是导致脱落的主要原因。但对蚕豆花荚脱落的研究报道极少。源的限制对蚕豆花荚脱落有多大影响?阐明源—库比与花荚脱落的关系,对于了解蚕豆光合作用的调节,同化物的运输与分配,进而采取适宜的措施提高结荚率,在理论上和     

遮光对蚕豆花荚形成和脱落的影响

本文旨在研究蚕豆开花前后不同时期光照强度对花荚形成和脱落的影响。产量补偿能力以及花荚形成和脱落的生理生态原因。蚕豆花前遮光,开花总数和结荚数降低,但花荚脱落率下降,粒重增加。花期和花后遮光,对开花总数没有明显影响,但花荚脱落严重,减产最多。任何时期遮光均使比叶重、遮光后期叶绿素含量、光合生产量、生殖器官干物质分配率,可溶性糖和含N量下降,但成熟期可溶性糖和含N量,营养元素吸收量不受影响。遮光导致花荚形 成和产量减少的主要原因是C／N比值下降,而不是改变营养元素的丰度所致。     

不同生育期玉米叶片光合特性及水分利用效率对水分胁迫的响应

利用大型移动防雨棚开展了玉米水分胁迫及复水试验,通过分析玉米叶片光合数据,揭示了不同生育期水分胁迫及复水对玉米光合特性及水分利用效率的影响。结果表明:水分胁迫导致玉米叶片整体光合速率、蒸腾速率和气孔导度下降以及光合速率日变化的峰值提前;水分胁迫后的玉米叶片蒸腾速率、光合速率和气孔导度为适应干旱缺水均较对照显著下降,从而提高了水分利用效率,缩小了与水分充足条件下玉米叶片的水分利用效率差值;在中度和重度水分胁迫条件下,玉米叶片的水分利用效率降幅低于光合速率、蒸腾速率和气孔导度的降幅, 有时甚至高于正常供水条件下的水分利用效率;适度的水分胁迫能提高玉米叶片的水分利用效率,从而增强叶片对水分的利用能力,抵御干旱的逆境;水分亏缺对玉米光合速率、蒸腾速率及水分利用效率的影响具有较明显滞后效应,干旱后复水,光合作用受抑制仍然持续;水分胁迫时间越长、胁迫程度越重,叶片的光合作用越呈不可逆性;拔节-吐丝期水分胁迫对玉米叶片光合作用的逆制比三叶-拔节期更难恢复。     

黄连木对干旱胁迫的生理响应

研究了自然干旱条件下黄连木（Pistacia chinensis Bunge）的生理变化。结果表明,随土壤含水量的减少,叶绿素b含量、光合速率、叶片相对含水量与叶水势均下降;叶绿素a和可溶性糖含量、叶绿素a和b的比值及总叶绿素含量呈现上升的趋势;超氧化物歧化酶活性先升后降;丙二醛含量干旱胁迫前期升高,后期变化不明显;净光合速率、气孔导度和蒸腾速率随土壤含水量的减少逐步降低。气孔和可溶性糖含量都是影响黄连木光合速率的关键因子,干旱胁迫前12d光合速率主要受气孔限制,之后为非气孔限制。干旱胁迫前期渗透调节物质以可溶性糖为主,干旱胁迫较重时脯氨酸含量急剧升高,与可溶性糖同时起渗透调节作用。     

阶段性干旱及复水对小麦光合特性和产量的影响

在田间人工遮雨条件下,研究了持续、缓慢的干旱胁迫及复水对小麦旗叶光合特性及产量的影响.结果表明:返青至成熟期充分供水(S0)的小麦旗叶叶绿素含量、叶绿素荧光参数、光合参数和产量较高;返青至成熟期(S3)或开花至成熟期(S2)遭受干旱胁迫的小麦上述光合特征参数与产量显著下降;开花至成熟期复水(S1)的小麦其上述光合参数与S0相比表现出超补偿效应,但产量略低于S0;S1、S2与S3水分利用效率分别为S0的143.2％、86.5％和97.3％;由此得出0～ 40 cm土层平均土壤相对含水量在返青至开花期保持在55％±5％,开花至灌浆期保持在70％±5％,可在获取一定产量的同时高效节水;由于水分和密度在产量表现上存在互作,得出0 ～ 40 cm土层平均土壤相对含水量在返青至开花期保持在55％ ±5％,开花至灌浆期保持在70％ ±5％,并采取675株·m-2的密度是该地区最佳的水分密度组合.     

土壤干旱条件下不同施钾水平对烟草光合速率和蒸腾效率的影响

研究了土壤干旱条件下,不同的施钾水平对烟草光合速率,胞间CO2浓度,气孔导度,蒸腾速率,蒸腾效率及生物量的影响。结果表明：在土壤干旱条件下适量施钾可以减少叶肉细胞光合活性的下降,消弱非气孔因素对光合的限制,增强气孔调节能力,提高蒸腾效率,并获得较高的生物量。     

羊草叶片气体交换参数对温度和土壤水分的响应

 采用生长箱控制的方法研究了羊草(Leymus chinensis)幼苗叶片光合参数对5个温度和5个水分梯度的响应和适应。结果表明：轻度、中度土壤干旱并没有限制羊草叶片的生长,对气体交换参数亦无显著影响,反映了羊草幼苗对土壤水分胁迫的较高耐性。叶片生物量以26 ℃时最大,其它依次为23 ℃、20 ℃、29 ℃和32 ℃。温度升高使气孔导度和蒸腾速率增加, 却使光合速率和水分利用效率降低。水分和温度对叶片生物量、光合速率、气孔导度和蒸腾速率存在显著的交互作用,表明高温加强了干旱对叶片生长和气体交换的影响, 降低了羊草对土壤干旱的适应能力。高温和干旱的交互作用将显著减少我国半干旱地区草原的羊草生产力。     

种间互作和施氮对蚕豆/玉米间作生态系统地上部和地下部生长的影响

为河西走廊绿洲灌区豆科/禾本科间作体系的养分管理提供科学依据,于2007年在武威绿洲农业试验站应用田间原位根系行分隔技术研究了蚕豆/玉米种间互作和施氮对玉米抽雄期的根系空间分布、根系形态和作物地上部生长的影响。研究结果表明:种间互作和施氮均增加了玉米和蚕豆在纵向和横向两个尺度上的根重密度、根长密度、根表面积、根系体积。根长密度和根表面积与两种作物产量和氮素吸收均呈正相关,而与蚕豆的根瘤重呈负相关;抽雄期的土壤含水量与玉米产量和养分吸收呈显著的负相关。玉米根系可以占据蚕豆地下部空间,但蚕豆的根却较少到间作玉米的地下部空间,也就是间作后增加了玉米根系水平尺度的生态位。蚕豆和玉米根系主要分布分别在0-40 cm浅土层和0-60 cm 土层,且间作玉米根系在60-120 cm比单作和分隔的多。因此,种间互作和施氮扩大了两作物根系纵向和横向的空间生态位,改变了作物根系形态,即扩展了两者水分和养分吸收的生态位,增加了作物吸收养分的有效空间,从而提高了间作生态系统的生产力。     

干旱胁迫对花生根系生长发育和生理特性的影响

以花育17号和唐科8号两个花生品种为试验材料,在防雨棚栽培池内进行土柱栽培试验,研究了中度干旱胁迫和正常供水处理下花生生育后期根系形态发育特征和生理特性.结果表明: 唐科8号具有较发达的根系及较高的产量和抗旱系数,花育17号根系对干旱胁迫的适应性小于唐科8号.两品种根长密度、根系生物量均主要分布于0～40 cm土层中,但同一土层内两品种根系性状存在差异.与正常供水处理相比,干旱胁迫处理使花育17号各生育期总根长、根系总表面积和总体积均降低,而唐科8号除花针期显著降低外,其余生育期均明显升高;干旱胁迫增加了两品种20～40 cm土层内根系生物量、根系表面积和体积,而降低了40 cm以下土层内各根系性状;干旱胁迫处理使两品种饱果期40 cm以下土层内根系活力降低,且花育17号降低幅度高于唐科8号.干旱胁迫下两品种生育后期根系发育和生理特性的差异表明其根系在干旱胁迫下对水分吸收和利用存在差异.     

小麦/蚕豆间作作物生长曲线的模拟及种间互作分析

物种间的相互作用与间作产量优势的形成密切相关,但很少有人注意到种间互作动态.本研究通过2年田间定位试验,运用Logistic分析模拟了不同种植模式(小麦单作、蚕豆单作和小麦/蚕豆间作)和不同磷水平下[P₀,施磷量(P₂O₅)为0 kg·hm^-2(对照);P₁,施磷量(P₂O₅)为45 kg·hm^-2;P₂,施磷量(P₂O₅)为90 kg·hm^-2]单间作小麦、蚕豆的生长模型,分析了作物种间互作的动态变化.结果表明: 小麦/蚕豆间作使小麦产量提高了10.5%~18.6%,蚕豆产量却降低了4.8%~12.3%,但间作系统仍具有产量优势,土地当量比(LER)和相对拥挤系数(K)分别为1.01~1.15 和1.12~3.20.小麦和蚕豆的产量及关键生长参数均受磷水平调控,但LER和K并不受磷水平影响.与单作相比,间作小麦的最大生长速率(R_max)和最初生长速率(r)分别提高21.8%~38.7%和20.7%~38.9%,但间作对蚕豆的关键生长参数无影响.在小麦、蚕豆的生长初期,不同磷水平下,单间作作物的生长曲线无差异;间作群体以种间竞争为主,无间作生物量优势(LER<1,K<1).当蚕豆达到最大生长速率(T_max)后,间作显著提高了小麦的生长速率,降低了小麦的种内竞争压力,表现出间作生物量和产量优势(LER>1,K>1).总之,在不同的生长发育阶段,小麦、蚕豆的相互作用不同,间作提高了中后期小麦的生长速率,为间作优势的形成奠定了基础.     

全膜微垄沟穴播对春小麦土壤水热环境的影响及其光合和产量效应

减弱春季寒旱生境限制是提高甘肃中东部旱地春小麦产量的关键要素之一。本研究于2016—2018年在甘肃中部半干旱旱作区开展大田试验,以‘陇春35号’为供试品种,设置全膜微垄沟穴播(PRF)、全膜覆土穴播(PMS)和露地穴播(CK)3个处理,测定春小麦不同生育期0～300 cm土层的土壤含水量、0～25 cm土壤温度、叶片生物量、叶片叶绿素(SPAD)、光合速率、蒸腾速率和作物产量,从土壤水热-冠层发育-产量角度揭示PRF处理对土壤水热环境、水分利用效率(WUE)和产量的影响。结果表明: 与CK相比,PRF和PMS处理0～25 cm土层的土壤温度在苗期分别提高2.8和2.5 ℃,灌浆-成熟期分别降低1.4和0.9 ℃;0～300 cm土壤贮水量在播前-苗期分别增加59.7和41.8 mm;0～300 cm耗水量在苗期-灌浆期分别提高46.1和39.8 mm。与PMS处理相比,PRF处理的小麦苗期温度提高0.3 ℃,灌浆-成熟期降低0.5 ℃;播前-苗期0～300 cm土壤贮水量增加18.0 mm,拔节-成熟期耗水量提高13.0 mm。基于对土壤水热条件的优化,PRF和PMS处理的叶片生物量、SPAD值、苗期-灌浆期叶片净光合速率、蒸腾速率均显著高于CK,且PRF处理均显著高于PMS处理。PRF处理比PMS处理和CK分别增产9.1%和36.5%,WUE分别提高5.9%和30.8%。因此,PRF处理能提高苗期地温,降低灌浆-成熟期地温,促进春小麦苗期-灌浆期的耗水,提高了春小麦叶片SPAD值和生物量,增强春小麦苗期-灌浆期旗叶的光合功能,从而实现增产和水分高效利用,而且这一优势在欠水年份(2016和2017年)更加明显。     

Evaluation of physiological traits for improving drought tolerance in faba bean (<Emphasis Type="Italic">Vicia faba</Emphasis> L.)

Among grain legumes, faba bean is becoming increasingly popular in European agriculture due to recent economic and environmental interests. Faba bean can be a highly productive crop, but it is sensitive to drought stress and yields can vary considerably from season to season. Understanding the physiological basis of drought tolerance would indicate traits that can be used as indirect selection criteria for the development of cultivars adapted to drought conditions. To assess genotypic variation in physiological traits associated with drought tolerance in faba bean and to determine relationships among these attributes, two pot experiments were established in a growth chamber using genetic materials that had previously been screened for drought response in the field. Nine inbred lines of diverse genetic backgrounds were tested under adequate water supply and limited water conditions. The genotypes showed substantial variation in shoot dry matter, water use, stomatal conductance, leaf temperature, transpiration efficiency, carbon isotope discrimination (Δ¹³C), relative water content (RWC) and osmotic potential, determined at pre-flowering vegetative stage. Moisture deficits decreased water usage and consequently shoot dry matter production. RWC, osmotic potential, stomatal conductance and Δ¹³C were lower, whereas leaf temperature and transpiration efficiency were higher in stressed plants, probably due to restricted transpirational cooling induced by stomatal closure. Furthermore, differences in stomatal conductance, leaf temperature, Δ¹³C and transpiration efficiency characterized genotypes that were physiologically more adapted to water deficit conditions. Correlation analysis also showed relatively strong relationships among these variables under well watered conditions. The drought tolerant genotypes, ILB-938/2 and Melodie showed lower stomatal conductance associated with warmer leaves, whereas higher stomatal conductance and cooler leaves were observed in sensitive lines (332/2/91/015/1 and Aurora/1). The lower value of Δ¹³C coupled with higher transpiration efficiency in ILB-938/2, relative to sensitive lines (Aurora/1 and Condor/3), is indeed a desirable characteristic for water-limited environments. Finally, the results showed that stomatal conductance, leaf temperature and Δ¹³C are promising physiological indicators for drought tolerance in faba bean. These variables could be measured in pot-grown plants at adequate water supply and may serve as indirect selection criteria to pre-screen genotypes.     

全膜覆土下施有机肥对春小麦旗叶碳氮比、光合特性和产量的影响

于2016和2017年,以春小麦品种‘陇春27'为试验材料,在甘肃省中部半干旱雨养农业区设置定位试验,分析全膜覆土平作穴播(PMS)、全膜覆土平作穴播+有机肥(PMO)、裸地平作穴播(CK)3个处理春小麦抽穗至灌浆阶段土壤水分与群体冠层温度、净光合速率(P_n)、气孔导度(g_s)、蒸腾速率(T_r)、旗叶C/N、旗叶全氮之间的相互关系,探讨不同处理对产量及其构成要素的影响。结果表明: 施用有机肥可提高小麦生育中后期土壤含水量,PMO抽穗至灌浆阶段0～300 cm土层土壤贮水量较PMS和CK分别提高4.6%和8.5%,群体冠层温度分别降低0.1～1.3 ℃和1.4～4.9 ℃,P_n分别提高9.3%和29.7%,g_s分别提高30.9%和103.8%,T_r分别提高5.1%和55.0%,全氮含量分别提高6.6%和18.9%,C/N分别降低6.4%和22.8%。收获后,PMO较PMS和CK显著促进穗粒数和千粒重增加,籽粒产量分别提高9.1%和53.7%。抽穗至灌浆阶段旗叶P_n和g_s与C/N呈负相关性;C/N与籽粒产量呈显著负相关。因此,半干旱区全膜覆土穴播条件下施有机肥可提高春小麦抽穗至灌浆阶段土壤含水量,促进旗叶光合作用,有利于降低生理干旱胁迫强度和旗叶氮吸收同化限制,促进穗粒数和粒重增加,使产量提升。     

Salinity and drought interaction in wheat (Triticum aestivum L.) is affected by the genotype and plant growth stage

Salinity and drought are important agro-environmental problems occurring separately as well as together with the combined occurrence increasing with time due to climate change. Screening of bread wheat genotypes against salinity or drought alone is common; however, little information is available on the response of wheat genotypes to a combination of these stresses. This study investigates the response of a salt-resistant (SARC-1) and a salt-sensitive (7-Cerros) wheat genotype to drought at different growth stages under non-saline (ECe 2.1 dS m^?1) and saline soil (ECe 15 dS m^?1) conditions. Drought was applied by withholding water for 21 days at a particular growth stage viz. tillering, booting, and grain filling stages. At booting stage measurements regarding water relations, leaf ionic composition and photosynthetic attributes were made. At maturity grain yield and different yield, components were recorded. Salinity and drought significantly decreased grain yield and different yield components with a higher decrease in the case of combined stress of salinity × drought. The complete drought treatment (drought at tillering + booting + grain filling stages) was most harmful for wheat followed by drought at booting stage and grain filling–tillering stages, respectively. The salt-resistant wheat genotype SARC-1 performed better than the salt-sensitive genotype 7-Cerros in different stress treatments. A decrease in the water and turgor potentials, photosynthetic and transpiration rates, stomatal conductance, leaf K⁺, and increased leaf Na⁺ were the apparent causes of growth and yield reduction of bread wheat due to salinity, drought, and salinity × drought.     

Wheat and faba bean intercropping changes phenolic acids from roots to rhizosphere

The changed phenolic acids (PAs) allelochemicals exuded by the roots induced by interspecific interactions is related to intercropping alleviates soil-borne disease. However, the presence of PAs in roots and root exudations and their rhizodeposition under intercropping are still unclear. Hydroponic and soil experiments of wheat, faba bean, and wheat intercropped with faba bean were conducted, and the major compositions and contents of PAs in roots, root exudations, and rhizospheric soil were determined. The results showed that ρ-hydroxybenzoic, vanillic, and syringic acids were the major components of PAs in roots, root exudations, and rhizospheric soil in a wheat and faba bean intercropping system. The compositions and percentages of PAs in roots of faba bean were altered when faba bean intercropped with wheat. The total exudation rate of PAs in root exudations was decreased by 30%–60% under the wheat and faba bean intercropping (W//F) system as compared to mono-cropped faba bean (MF). ρ-hydroxybenzoic acid was identified in the root exudation of both MF and mono-cropped wheat (MW), but not detected in the intercropping on 60 days after transplanting. Vanillic acid was only detected in the root exudation of MF on 30 days after transplanting. The rhizodepostion of vanillic and cumaric acid were decreased at both branching and pod setting stages in W//F as compared to MF. In conclusion, interspecific interaction changed the compositions and contents of PAs in faba bean roots and root exudations. W//F constrained vanillic acid exuded by roots and decreased vanillic and coumaric acid rhizodeposition by faba bean, which provides insight into root-soil interactions in the intercropping systems.     

间作减轻蚕豆枯萎病的微生物和生理机制

通过田间小区试验,研究了小麦与蚕豆间作对蚕豆枯萎病发病率、病情指数、根际镰刀菌数量、蚕豆根系抗氧化酶活性和膜质过氧化的影响.采用Biolog ECO板分析了根际土壤微生物的代谢功能多样性,通过高效液相色谱(HPLC)测定了蚕豆根际土壤中酚酸含量.结果表明: 与单作蚕豆相比,小麦与蚕豆间作有降低蚕豆枯萎病发病率的趋势;发病盛期和发病末期,间作使蚕豆枯萎病的病情指数比单作显著降低15.8%和22.8%,明显提高了蚕豆根际微生物活性(AWCD值),根际微生物的Shannon多样性指数显著提高4.4%和5.3%,丰富度指数显著提高19.4%和37.1%.主成分分析表明,发病盛期和发病末期,间作明显改变了蚕豆根际微生物的群落结构,蚕豆根际镰刀菌数量分别降低53.8%和33.1%;并显著降低了蚕豆根际土壤中对羟基苯甲酸、香草酸、丁香酸、阿魏酸、苯甲酸和肉桂酸的含量.发病盛期和发病末期,间作蚕豆根系的过氧化物酶(POD)和过氧化氢酶(CAT)活性分别显著提高了20.0%、31.3%和38.5%、66.7%,丙二醛(MDA)含量显著降低36.3%和46.3%;发病初期间作对蚕豆根系的POD、CAT酶活性和MDA含量无显著影响.小麦与蚕豆间作显著提高了蚕豆根际微生物的活性、多样性和根系抗氧化酶活性,降低了蚕豆根际土壤中酚酸含量和膜质过氧化程度,减少了土壤镰刀菌的数量,从而提高了蚕豆对枯萎病的抗性,降低了枯萎病的危害程度.