Sustainable production of crops and pastures under drought in a Mediterranean environment

Mediterranean environments are characterised by cool wet winters and hot dry summers. While native vegetation in Mediterranean-climatic zones usually comprises a mixture of perennial and annual plants, agricultural development in the Mediterranean-climatic region of Australia has led to the clearing of the perennial vegetation and its replacement with annual crops and pastures. In the Mediterranean environments of southern Australia this has led to secondary (dryland) salinisation. In order to slow land degradation, perennial trees and pasture species are being reintroduced to increase the productivity of the saline areas. The annual crops and pastures that form the backbone of dryland farming systems in the Mediterranean-climatic zone of Australia are grown during the cool wet winter months on incoming rainfall and mature during spring and early summer as temperatures and rates of evaporation rise and rainfall decreases. Thus, crop and pasture growth is usually curtailed by terminal drought. Where available, supplementary irrigation in spring can lead to significant increases in yield and water use efficiency. In order to sustain production of annual crops in Mediterranean environments, both agronomic and genetic options have been employed. An analysis of the yield increases of wheat in Mediterranean-climatic regions shows that there has generally been an increase in the yields over the past decades, albeit at a lower rate than in more temperate regions. Approximately half of this increase can be attributed to agronomic improvements and half to genetic improvements. The agronomic improvements that have been utilised to sustain the increased yields include earlier planting to more closely match crop growth to rainfall distribution, use of fertilisers to increase early growth, minimum tillage to enable earlier planting and increase plant transpiration at the expense of soil evaporation, rotations to reduce weed control and disease incidence, and use of herbicides, insecticides and fungicides to reduce losses from weeds, insects and disease. Genetic improvements include changing the phenological development to better match the rainfall, increased early vigour, deeper rooting, osmotic adjustment, increased transpiration efficiency and improved assimilate storage and remobilisation. Mediterranean environments that are subjected annually to terminal drought can be both environmentally and economically sustainable, but to maximise plant water use efficiency while maintaining crop productivity requires an understanding of the interaction between genotypes, environment and management.     

Root growth and water uptake in winter wheat under deficit irrigation

Root growth is critical for crops to use soil water under water-limited conditions. A field study was conducted to investigate the effect of available soil water on root and shoot growth, and root water uptake in winter wheat (Triticum aestivum L.) under deficit irrigation in a semi-arid environment. Treatments consisted of rainfed, deficit irrigation at different developmental stages, and adequate irrigation. The rainfed plots had the lowest shoot dry weight because available soil water decreased rapidly from booting to late grain filling. For the deficit-irrigation treatments, crops that received irrigation at jointing and booting had higher shoot dry weight than those that received irrigation at anthesis and middle grain filling. Rapid root growth occurred in both rainfed and irrigated crops from floral initiation to anthesis, and maximum rooting depth occurred by booting. Root length density and dry weight decreased after anthesis. From floral initiation to booting, root length density and growth rate were higher in rainfed than in irrigated crops. However, root length density and growth rate were lower in rainfed than in irrigated crops from booting to anthesis. As a result, the difference in root length density between rainfed and irrigated treatments was small during grain filling. The root growth and water use below 1.4 m were limited by a caliche (45% CaCO₃) layer at about 1.4 m profile. The mean water uptake rate decreased as available soil water decreased. During grain filling, root water uptake was higher from the irrigated crops than from the rainfed. Irrigation from jointing to anthesis increased seasonal evapotranspiration, grain yield, harvest index and water-use efficiency based on yield (WUE), but did not affect water-use efficiency based on aboveground biomass. There was no significant difference in WUE among irrigation treatments except one-irrigation at middle grain filling. Due to a relatively deep root system in rainfed crops, the higher grain yield and WUE in irrigated crops compared to rainfed crops was not a result of rooting depth or root length density, but increased harvest index, and higher water uptake rate during grain filling.     

Impacts of climate change on rice production in Africa and causes of simulated yield changes

This study is the first of its kind to quantify possible effects of climate change on rice production in Africa. We simulated impacts on rice in irrigated systems (dry season and wet season) and rainfed systems (upland and lowland). We simulated the use of rice varieties with a higher temperature sum as adaptation option. We simulated rice yields for 4 RCP climate change scenarios and identified causes of yield declines. Without adaptation, shortening of the growing period due to higher temperatures had a negative impact on yields (?24% in RCP 8.5 in 2070 compared with the baseline year 2000). With varieties that have a high temperature sum, the length of the growing period would remain the same as under the baseline conditions. With this adaptation option rainfed rice yields would increase slightly (+8%) but they remain subject to water availability constraints. Irrigated rice yields in East Africa would increase (+25%) due to more favourable temperatures and due to CO2 fertilization. Wet season irrigated rice yields in West Africa were projected to change by ?21% or +7% (without/with adaptation). Without adaptation irrigated rice yields in West Africa in the dry season would decrease by ?45% with adaptation they would decrease significantly less (?15%). The main cause of this decline was reduced photosynthesis at extremely high temperatures. Simulated heat sterility hardly increased and was not found a major cause for yield decline. The implications for these findings are as follows. For East Africa to benefit from climate change, improved water and nutrient management will be needed to benefit fully from the more favourable temperatures and increased CO2 concentrations. For West Africa, more research is needed on photosynthesis processes at extreme temperatures and on adaptation options such as shifting sowing dates.     

5. The use of genetic resources in breeding and breeding research

The dramatic increase in yields of agricultural crops over the last 40 years in developed countries has been attributed equally to improved genetic components and improved agronomic practices. The success of plant breeding is based partly on an increased understanding of the parameters involved, to a great extent on improved and more efficient methods of selection, to greater use of available genetic diversity and also to advances in a number of related disciplines including plant pathology, biochemistry, agronomy and genetics. Successes and problems associated with using various genetic resources in plant breeding are illustrated with examples from some of the world's major crops, including potatoes, barley and cotton.     

Yield and water use of wheat (Triticum aestivum) in a Mediterranean environment: Cultivar differences and sowing density effects

Yield of eight wheat cultivars was evaluated under rainfed and irrigated conditions in a Mediterranean environment. Variation in grain yield resulted from variation in both aboveground biomass production and in harvest index. Under rainfed compared to irrigated conditions, grain yield, biomass and days to heading were decreased, whereas harvest index was increased. Grain yield of the different cultivars under rainfed conditions correlated with that under irrigated conditions in one of the two years. Among cultivars, harvest index under rainfed and irrigated conditions were correlated in both years.Water was used more efficiently for biomass production, and equally efficiently for grain production, under irrigated compared to rainfed conditions. Under rainfed conditions, crop water use efficiency was higher for cultivars developed for rainfed environments than for those developed for high-rainfall or irrigated environments. Cultivars with low-rainfall target environments had the lowest evapotranspiration under rainfed conditions. Under rainfed conditions, differences between the cultivar groups in crop water use efficiency corresponded with trends in water use efficiency of individual plants and with the ratio of photosynthesis to transpiration, measured on plants grown in a growth room.Early in the season, water was used more efficiently for biomass production at high sowing densities than at low sowing densities. Through faster biomass production and ground cover a smaller proportion of the evapotranspired water was lost in soil evaporation and a larger proportion was transpired. However, the net effect was a greater water use in the early phases of growth and consequently a lower water availability later in the season, leading to similar yields regardless of sowing density.     

气候变化背景下东北三省主要粮食作物产量潜力及资源利用效率比较

以东北地区喜温作物和喜凉作物的潜在种植区为研究区域,基于研究区域内65个气象台站1961—2010年地面气象观测数据,结合作物生育期资料,应用作物产量潜力逐级订正法,分析不同作物各级产量潜力时空分布特征,明确作物各级产量潜力受气候资源限制程度,比较气候资源利用效率差异.结果表明： 1961—2010年,东北三省6种作物（玉米、水稻、春小麦、高粱、谷子和大豆）的光温产量潜力呈明显的西高东低的空间分布特征,作物气候产量潜力除春小麦外其他作物均呈现南高北低的空间分布规律.6种作物受温度限制的产量潜力损失率呈东高西低的空间分布特征,大豆受温度限制引起的产量潜力损失率最高,平均为51%,其他作物为33%～41%;因降水制约引起的潜力损失率分布有明显的区域性差异,在松嫩平原和长白山区各有一个高值区,春小麦因降水亏缺引起的产量潜力损失率最高,平均为50%,其他4种雨养作物集中在8%～10%.东北三省各作物生长季内光能利用效率在0.9%～2.7%,其中玉米>高粱>水稻>谷子>春小麦>大豆;雨养条件下,玉米、高粱、春小麦、谷子和大豆各作物的降水利用效率在8～35 kg·hm^-2·mm^-1,其中玉米>高粱>春小麦>谷子>大豆.在光能利用效率和降水利用效率均较低的长白山区和小兴安岭南部地区,可采取合理密植、选择适宜品种、适时施肥、蓄水保墒耕作以及优化作物布局等措施提高资源利用效率.     

不同施肥水平对旱地冬小麦水分利用效率的影响

1987—1988年,研究了旱地施肥对冬小麦(Triticum aestivum cv．Shanhe No．6)水分利用效率的影响,初步探讨了“以肥调水”的生理机制。施肥不仅提高了旱地土壤含水量,更重要的是提高了土壤水势和土壤水的有效性,从而增加了有效水分利用。施肥增大旱地冬小麦绿叶面积,延缓叶片衰老,从而降低土壤蒸发,增加蒸腾用水潜势和光合潜势,但净同化率不一定提高。施肥增加旱地冬小麦总的水分利用(ET,即蒸散量)和蒸腾(T)用水,增加地上部生物产量,提高了经济产量和水分利用效率。施肥使冬小麦同时具有耗水和节水以抵御干旱的能力,对植株具有调节作用,使之更好地适应干旱环境。     

三江平原粮食作物生产水足迹时空特征及影响因素

水足迹是评价人类活动对水资源开采和水环境污染程度的重要方法,对农作物生长过程的绿水足迹、蓝水足迹和灰水足迹进行量化和分析,可以为农业用水综合评价和用水管理提供指导。以三江平原为研究区域量化粮食作物生产水足迹的时空特征,揭示粮食生产对区域水资源的占用情况,并分析水足迹的影响因素。结果表明:(1)三江平原粮食生产水足迹总量在2005-2018年间呈显著增加趋势,其中绿水足迹、蓝水足迹和灰水足迹在水足迹总量中的占比历年平均为28%、8%和64%;(2)粮食生产水足迹空间差异明显,在地市尺度,佳木斯市水足迹最高,占三江平原总量的47%,在县区尺度,富锦市、依兰县和桦南县是水足迹热点地区;(3)只考虑蓝水足迹,粮食生产给三江平原水资源造成轻度压力,而同时考虑蓝水和灰水足迹,粮食生产给三江平原水资源造成重度压力;各地市间水资源压力有较大差异,其中佳木斯市负担了该区域将近一半的粮食产量,水资源压力最高,鹤岗市则水资源压力最低;(4)降雨量、灌溉水利用效率、化肥施用量、粮食种植结构和作物单产水平等都会影响粮食作物生产水足迹,其中蓝水足迹响应种植结构的变化最敏感,灰水足迹响应化肥施用量的变化最敏感,而水足迹总量响应作物单产水平的变化最敏感。因此,建议减少化肥施用量、提高作物单产水平和优化作物种植结构纳入区域水资源可持续管理之中。     

Development of Dryland Oilseed Production Systems in Northwestern Region of the USA

This report addresses the development of dryland oilseed crops to provide feedstock for production of biofuels in semi-arid portions of the northwestern USA. Bioenergy feedstocks derived from Brassica oilseed crops have been considered for production of hydrotreated renewable jet fuel, but crop growth and yields in the northwestern region are limited by a lack of plant available water. Based on a review of the scientific literature, several areas were identified where research could be directed to provide improvements. The current agronomic limitations for oilseed production are mainly due to seedling establishment under extreme heat, dry seedbeds at optimum planting times, survival under extreme cold, and interspecific competition with weeds. To improve emergence and stand establishment, future work should focus on developing soil management and seeding techniques that optimize plant available water, reduce heat stress, and provide a competitive advantage against weeds that are customized for specific crops, soil types, and soil and environmental conditions. Spring and winter cultivars are needed that offer increased seedling vigor, drought resistance, and cold tolerance.     

Millet-inspired systems metabolic engineering of NUE in crops

The use of nitrogen (N) fertilizers in agriculture has a great ability to increase crop productivity. However, their excessive use has detrimental effects on the environment. Therefore, it is necessary to develop crop varieties with improved nitrogen use efficiency (NUE) that require less N but have substantial yields. Orphan crops such as millets are cultivated in limited regions and are well adapted to lower input conditions. Therefore, they serve as a rich source of beneficial traits that can be transferred into major crops to improve their NUE. This review highlights the tremendous potential of systems biology to unravel the enzymes and pathways involved in the N metabolism of millets, which can open new possibilities to generate transgenic crops with improved NUE.     

气候变化对甘肃省粮食生产的影响研究进展

甘肃省气候自1986年起向整体暖干化、局部暖湿化转型突变.与1960年相比,转型后2010年平均气温升高了1.1 ℃,平均降水量减少了28 mm,干旱半干旱区南移约50 km.气候变暖使甘肃省主要作物生育期有效积温增加,生长期延长,熟性、布局和种植制度改变,宜种区和种植海拔增加,多熟制北移,夏粮面积缩小,秋粮面积增大.弱冬性、中晚熟品种逐步取代强冬性、中早熟品种,有利于提高光温利用率,增加产量.暖湿型气候增加了绿洲灌区作物的气候生产力,暖干型气候降低了雨养农业区的气候产量,水分和肥力条件是决定因素.以提高有限降水利用率和利用效率、改善和提升土壤质量及肥力为核心,选育强抗逆、弱冬性、中晚熟、高水分利用效率的作物新品种,建立适温、适水的种植结构和种植制度,是甘肃省应对气候变化进行粮食生产的主要发展方向.     

农田水氮关系及其协同管理

作物施氮反应及其氮肥利用率不仅取决于氮肥管理,还与水资源管理有关,并且受到地区气候因素的影响。针对中国灌溉农区氮肥环境污染问题日益突出,协调农田水氮管理,如通过改善水资源管理,发挥水氮协同效应,以提高水分利用效率来改善氮肥利用率,实现水氮利用率双赢,是当前农业水氮管理中亟待探讨和回答的问题。通过对农田水氮协同相关研究文献资料的综述,以华北平原集约种植体系水氮管理为例,根据历年统计数据,分析了该区年水热条件下粮食产量与水、氮及水氮利用效率之间的关系。研究表明,水和氮与作物产量在一定范围表现为水氮的协同效应。水分利用效率一般随灌溉水量减少及氮肥用量增加而提高;氮肥利用效率随氮用量增加而下降。适量节水和减氮分别有助水分利用效率和氮肥利用效率的改善。在气候变暖、变干条件下,适量施氮成为改善水氮利用效率的关键对策。     

Quantifying irrigation cooling benefits to maize yield in the US Midwest

Irrigation is an important adaptation strategy to improve crop resilience to global climate change. Irrigation plays an essential role in sustaining crop production in water‐limited regions, as irrigation water not only benefits crops through fulfilling crops' water demand but also creates an evaporative cooling that mitigates crop heat stress. Here we use satellite remote sensing and maize yield data in the state of Nebraska, USA, combined with statistical models, to quantify the contribution of cooling and water supply to the yield benefits due to irrigation. Results show that irrigation leads to a considerable cooling on daytime land surface temperature (?1.63°C in July), an increase in enhanced vegetation index (+0.10 in July), and 81% higher maize yields compared to rainfed maize. These irrigation effects vary along the spatial and temporal gradients of precipitation and temperature, with a greater effect in dry and hot conditions, and decline toward wet and cool conditions. We find that 16% of irrigation yield increase is due to irrigation cooling, while the rest (84%) is due to water supply and other factors. The irrigation cooling effect is also observed on air temperature (?0.38 to ?0.53°C) from paired flux sites in Nebraska. This study highlights the non‐negligible contribution of irrigation cooling to the yield benefits of irrigation, and such an effect may become more important in the future with continued warming and more frequent droughts.     

Film mulch with irrigation and rainfed cultivations improves maize production and water use efficiency in Ethiopia

Improving productivity of maize (Zea mays L.) and water use efficiency is of great significance for agriculture in Ethiopia. In this study, the effects of ridge‐furrow with film mulch cultivation were tested on maize yields in Melkassa, Ethiopia. Three field experiments (drip irrigation, furrow irrigation and rainfed) were conducted each with randomised complete block design with three replicates. The drip irrigation experiment was conducted in the dry season and constituted three film mulch methods (non‐mulch, transparent film mulch and black film mulch) with three irrigation levels (357, 435 and 515 mm). The furrow irrigation experiment was also conducted in the dry season and constituted two film mulches (non‐mulch and transparent film mulch) with three irrigation levels (484, 674 and 865 mm). The rainfed experiment was conducted in the rainy season and constituted three mulches (non‐mulch, transparent film mulch and black film mulch) with two farming methods (ridge‐furrow farming and flat farming). In the drip irrigation experiment, the highest maize yields (5.9 ± 0.6 t ha^?1) and irrigation water use efficiency (9.6 ± 1 kg ha^?1 mm^?1) were recorded in the treatment using black film mulch with high irrigation, with increases of 68% and 68.4% compared to using non‐mulch treatment at that irrigation level. In the furrow irrigation experiment, maize yields and irrigation water use efficiency reached 7 (± 0.8) t ha^?1 and 9.1 (± 1.9) kg ha^?1 mm^?1 in the treatment using transparent film mulch with medium irrigation (674 mm), with increases of 46% and 46.8% compared to that with non‐mulch treatment. In the rainfed experiment, the film mulch rather than farming method had positive effects on the maize yields and rainwater use efficiency. The average maize yield reached 8.5 (± 0.7) t ha^?1 in the film mulch treatments, with an increase of 39% than using the non‐mulch treatment. Compared with that of non‐mulch treatment, the net income in the film mulch treatments increased by 94% in the furrow experiment and 31% in the rainfed experiment. Our results indicate that the ridge‐furrow with film mulch system can be recommended for water‐saving irrigation with low cost in dry seasons, and film mulch with flat farming can be recommended in rainy seasons for maize production in Ethiopia. This study provides strong evidence that maize productivity can be effectively improved in Ethiopia and other similar areas of the world using this simple and cost‐effective technology.     

播期播量对旱地小麦土壤水分消耗和植株氮素运转的影响

为解决旱地小麦等雨播种的生产现状,明确播量对土壤水分利用和产量形成的调控机制,于2015—2017年在山西闻喜试验基地开展大田试验,以早播(9月20日,EB)、晚播(10月10日,LB)两个播期为主区,以低密度(67.5 kg·hm^-2,LD)、中密度 (90 kg·hm^-2,MD)、高密度(112.5 kg·hm^-2,HD)3个播量为副区,研究播期播量对旱地小麦土壤水分消耗和植株氮素运转的影响.结果表明: 早播较晚播生育期土壤总耗水量增加11～22 mm;随播种密度的增加,生育期土壤总耗水量增加2～20 mm,且早播条件下,花前土壤耗水量增加,晚播条件下,花后土壤耗水量显著增加.早播较晚播在低、中密度条件下花前氮素运转量、花后氮素积累量增加,高密度条件下降低.早播条件下,花前氮素运转量,茎秆+叶鞘、穗轴+颖壳花前氮素运转量对籽粒的贡献率以及花后氮素积累量均以低密度条件下最高;晚播条件下,花前氮素运转量和花后氮素积累量随播种密度增加而增加.早播较晚播产量显著提高163～996 kg·hm^-2,提高幅度达5%～26%,水分利用效率提高幅度达2%～21%,氮素吸收效率提高幅度达3%～36%,氮素收获指数提高幅度最高达11%.早播条件下产量、水分利用效率、氮素吸收效率、氮素收获指数以低密度条件下最高;晚播条件下以高密度条件下最高.此外,花前氮素运转量与花前100～200 cm土壤耗水量显著相关,尤其是茎秆+叶鞘、穗轴+颖壳;花后植株氮素积累量与花后100～300 cm土壤耗水量呈显著相关.总之,旱地小麦9月20日配套播量67.5 kg·hm^-2、10月10日配套播量112.5 kg·hm^-2有利于增产增效.     

Second generation bioenergy crops and climate change: a review of the effects of elevated atmospheric CO2 and drought on water use and the implications for yield

Second-generation, dedicated lignocellulosic crops for bioenergy are being hailed as the sustainable alternative to food crops for the generation of liquid transport fuels, contributing to climate change mitigation and increased energy security. Across temperate regions they include tree species grown as short rotation coppice and intensive forestry (e.g. Populus and Salix species) and C₄ grasses such as miscanthus and switchgrass. For bioenergy crops it is paramount that high energy yields are maintained in order to drive the industry to an economic threshold where it has competitive advantage over conventional fossil fuel alternatives. Therefore, in the face of increased planting of these species, globally, there is a pressing need for insight into their responses to predicted changes in climate to ensure these crops are 'climate proofed' in breeding and improvement programmes. In this review, we investigate the physiological responses of bioenergy crops to rising atmospheric CO₂ ([Ca]) and drought, with particular emphasis on the C₃ Salicaceae trees and C₄ grasses. We show that while crop yield is predicted to rise by up to 40% in elevated [Ca], this is tempered by the effects of water deficit. In response to elevated [Ca] stomatal conductance and evapotranspiration decline and higher leaf–water potentials are observed. However, whole-plant responses to [Ca] are often of lower magnitude and may even be positive (increased water use in elevated [Ca]). We conclude that rising [Ca] is likely to improve drought tolerance of bioenergy crop species due to improved plant water use, consequently yields in temperate environments may remain high in future climate scenarios.     

Global agricultural intensification during climate change: a role for genomics

Agriculture is now facing the ‘perfect storm’ of climate change, increasing costs of fertilizer and rising food demands from a larger and wealthier human population. These factors point to a global food deficit unless the efficiency and resilience of crop production is increased. The intensification of agriculture has focused on improving production under optimized conditions, with significant agronomic inputs. Furthermore, the intensive cultivation of a limited number of crops has drastically narrowed the number of plant species humans rely on. A new agricultural paradigm is required, reducing dependence on high inputs and increasing crop diversity, yield stability and environmental resilience. Genomics offers unprecedented opportunities to increase crop yield, quality and stability of production through advanced breeding strategies, enhancing the resilience of major crops to climate variability, and increasing the productivity and range of minor crops to diversify the food supply. Here we review the state of the art of genomic‐assisted breeding for the most important staples that feed the world, and how to use and adapt such genomic tools to accelerate development of both major and minor crops with desired traits that enhance adaptation to, or mitigate the effects of climate change.     

Deficit irrigation affects seasonal changes in leaf physiology and oil quality of Olea europaea (cultivars Frantoio and Leccino)

The olive tree is a traditionally nonirrigated crop that occupies quite an extensive agricultural area in Mediterranean-type agroecosystems. Improvements in water-use efficiency of crops are essential under the scenarios of water scarcity predicted by global change models for the Mediterranean region. Recently, irrigation has been introduced to increase the low land productivity, but there is little information on ecophysiological aspects and quality features intended for a sagacious use of water, while being of major importance for the achievement of high-quality products as olive oil. Therefore, deficit irrigation programmes were developed to improve water-use efficiency, crop productivity and quality in a subhumid zone of Southern Italy with good winter–spring precipitation. The response of mature olive trees to deficit irrigation in deep soils was studied on cultivars Frantoio and Leccino by examining atmospheric environment and soil moisture, gas exchange and plant water status, as well as oil yield and chemical analysis. Trees were not irrigated (rainfed) or subjected to irrigation at 66% and 100% of crop evapotranspiration (ET_C), starting from pit hardening to early fruit veraison. Improvements in the photosynthetic capacity induced by increasing soil water availability were only of minor importance. However, plant water status was positively influenced by deficit irrigation, with 66% and 100% of ET_C treatments hardly differing from one another though consistently diverging from rainfed plants. The effect of water stress on photosynthesis was mainly dependent on diffusion resistances in response to soil moisture. Leccino showed higher instantaneous water-use efficiency than Frantoio. Crop yield increased proportionally to the amount of seasonal water volume, confirming differences between cultivars in water-use efficiency. The unsaturated/saturated and the monounsaturated/polyunsaturated fatty acid ratios of the oil also differed between cultivars, while the watering regime had minor effects. Although irrigation can modify the fatty acid profile, polyphenol contents were scarcely affected by the water supply. Irrigation to 100% of ET_C in the period August–September might be advisable to achieve high-quality yields, while saving consistent amounts of water.     

秸秆还田和秋施肥对旱地玉米生长发育及水肥效应的影响

在我国北方半湿润偏旱区的晋东豫西(寿阳)旱农试验区,持续10年进行了多种方式秸秆还田与秋季深施肥配合定位试验。探讨秸秆还田秋施肥对旱地玉米生长发育、产量、土壤水肥高效利用和土壤肥力变化的影响。结果表明,秸秆还田秋施肥较好地解决了深施肥与春季保墒捉全苗的矛盾,以及秸秆腐解与幼苗争夺水分养分而影响玉米幼苗生长的矛盾,秸秆资源丰富的区域优势得以充分利用,土壤微生物活动更为活跃,土壤水肥状况得到明显改善。表现为玉米苗全苗壮,根系发达,植株叶片光合速率、蒸腾速率提高,水分利用效率年平均提高了3．26～4．51kg·hm^-2·mm^-1,生育期耗水量累计减少8．1～264．5mm,氮、磷肥利用率分别提高了3．9％～13．9％和3．0％～9．1％,水肥资源得到了高效利用,10年累计增加12．10～17．27t·hm^-2玉米籽粒,增产幅度达25．6％～36．5％。玉米产量年际间波动减小,同时维持了较高的土壤肥力和生产力。     

绿肥在我国旱地农业生态系统中的服务功能及其应用

旱地农业分布面积广、增产潜力大,在保障我国粮食安全方面占有重要地位,但也面临着水资源短缺、土壤贫瘠、水土流失严重和不可再生资源利用效率低等问题。绿肥不仅具有提高土壤质量、调节土壤养分和增强土壤水分蓄纳能力,从而改善作物生长环境,促进作物持续高产稳产的作用,而且在增加农田生态系统生物多样性、提高地表覆盖度、减少养分向环境中的无效损失、增强农田系统气体调节功能、提高病虫草害的生物防控等方面也具有显著的生态效益。在全球气候变化加剧、生态环境恶化和农产品需求改变等新形势下,以肥用为主要目的的传统绿肥种植应用技术已不能满足当前农业发展的需求,需要加强旱地绿肥种质资源的选育工作,通过研制新的适应新形势的全国绿肥区划,构建适应不同区域的绿肥种植模式,优化和研发适应现代化生产水平的耕作栽培技术,探究绿肥综合效益评价体系,为旱地农业区改善生态环境、提高经济效益,构建资源节约、生态保育型的绿肥应用模式,充分挖掘绿肥效益提供科学依据和技术支撑。