贵州农业发展现状及对策

定量化分析了新世纪以来贵州农业的发展,揭示了贵州农业新世纪以来在稳定粮食生产的基础上,在调整产业结构、经济作物生产上取得了长足的进展,2003-2012年贵州的蔬菜、水果产量分别增加了110.7%和84.4%。同时,分析了单产提高不快、化肥和农药用量增幅较快等当前存在的主要问题,并对未来贵州农业的发展提出了初步的对策。     

Impact of High Night‐Time and High Daytime Temperature Stress on Winter Wheat

High temperature is a major environmental factor that limits wheat (Triticum aestivum L.) productivity. Climate models predict greater increases in night‐time temperature than in daytime temperature. The objective of this research was to compare the effects of high daytime and high night‐time temperatures during anthesis on physiological (chlorophyll fluorescence, chlorophyll concentration, leaf level photosynthesis, and membrane damage), biochemical (reactive oxygen species (ROS) concentration and antioxidant capacity in leaves), growth and yield traits of wheat genotypes. Winter wheat genotypes (Ventnor and Karl 92) were grown at optimum temperatures (25/15 °C, maximum/minimum) until the onset of anthesis. Thereafter, plants were exposed to high night‐time (HN, 25/24 °C), high daytime (HD, 35/15 °C), high daytime and night‐time (HDN, 35/24 °C) or optimum temperatures for 7 days. Compared with optimum temperature, HN, HD and HDN increased ROS concentration and membrane damage and decreased antioxidant capacity, photochemical efficiency, leaf level photosynthesis, seed set, grain number and grain yield per spike. Impact of HN and HD was similar on all traits. Greater impact on seed set, grain number and grain yield per spike was observed at HDN compared with HN and HD. These results suggest that HN and HD during anthesis cause damage of a similar magnitude to winter wheat.     

双季稻最佳磷肥和钾肥用量与密度组合研究

【目的】为明确磷肥、钾肥用量和移栽密度对双季稻的施用效果,在田间试验条件下研究了不同磷肥用量、钾肥用量和移栽密度组合对江西双季稻产量、产量构成要素及磷肥和钾肥利用率的影响。【方法】本研究采用裂区试验设计研究了不同施磷量和移栽密度、不同施钾量和移栽密度对双季稻产量、磷肥和钾肥利用率的影响。磷肥用量和移栽密度试验中,设4个施磷水平(P2O5 0、60、90、120 kg/hm2,以P0、P60、P90和P120表示)和4种移栽密度(21×104、27×104、33×104、39×104 穴/hm2,以D21、D27、D33和D39表示)组合。钾肥用量和移栽密度试验中,设4个施钾水平(K2O 0、90、120、150 kg/hm2,以K0、K90、K120和K150表示),密度设置同磷肥试验。在水稻成熟期对产量以及产量构成要素进行测定,并分析其磷素和钾素的吸收量和利用率等指标。【结果】磷肥与密度试验中,同一施磷水平下,早稻产量和地上部磷素吸收量随着移栽密度的增加而增加,当施磷量超过60 kg/hm2时,产量和磷素吸收量不再随密度增加而显著增加,磷素吸收利用率(REP)、磷素农学效率(AEP)和磷素偏生产力(PFPP)逐步降低,以P60D39处理组合的产量和磷素吸收利用率最高,分别为5303.9 kg/hm2和24.4%,AEP为29.4 kg/kg; 晚稻则以施磷量在60 kg/hm2和33×104 穴/hm2密度组合的产量和磷素吸收利用率最高,分别为7246.9 kg/hm2和42.4%,AEP为36.2 kg/kg。钾肥与密度试验中,早稻的钾素吸收量随着施钾量的增加而增加,施钾量在120 kg/hm2和39×104 穴/hm2密度组合的处理产量和钾素吸收利用率(REK)最高,分别为6376.3 kg/hm2和67.2%,此时钾素农学效率(AEK)为15.6 kg/kg; 晚稻则以施钾量在90 kg/hm2和33×104 穴/hm2密度组合的处理产量和REK最佳,分别为7025.6 kg/hm2和74.0%,AEK为21.7 kg/kg。【结论】合理的磷肥、钾肥用量和移栽密度可以显著增加水稻单位面积有效穗数和养分累积量,进而增加水稻产量和肥料利用率,但过高的磷肥和钾肥施用会抑制产量的进一步增加。建议本研究区域的早稻采用施磷量在60 kg/hm2、施钾量120 kg/hm2和39×104穴/hm2的密度组合,而晚稻采用施磷量60 kg/hm2、施钾量90 kg/hm2和33×104 穴/hm2的密度组合。     

Effects of cover crop growth and decomposition on the distribution of aggregate size fractions and soil microbial carbon dynamics

Although the effects of cover crops (CC) on various soil parameters have been fully investigated, less is known about the impacts at different stages in CC cultivation. The objective of this study was to quantify the influence of CC cultivation stages and residue placement on aggregates and microbial carbon (C_mic). Additionally, the influence of residue location and crop species on CO₂ emissions and leached mineralized nitrogen (N_min) during the plant degradation period was also investigated. Within an incubation experiment, four CC species were sown in soil columns, with additional columns being kept plant‐free. After plant growth, the columns were frozen (as occurs in winter under field conditions) and then incubated with the plant material either incorporated or surface‐applied. With CC, concentrations of large and medium macroaggregates were twice that of the fallow, confirming positive effects of root growth. Freezing led to a decrease in these aggregate size classes. In the subsequent incubation, the large macroaggregates decreased far more in the samples with CC than in the fallow, leading to similar aggregate size distributions. No difference in C_mic concentration was found among the CC cultivation stages. CO₂ emissions were roughly equivalent to the carbon amounts added as plant residues. Comparison of columns with incorporated or surface‐applied residues indicated no consistent pattern of aggregate distribution, CO₂ emission or C_mic and N_min concentrations. Our results suggest that positive effects of CC cultivation are only short term and that a large amount of organic material in the soil could have a greater influence than CC cultivation.     

粮食生产潜力短期预测的“趋势-波动模型”的验证

应用全国、31个省、6个典型地区和16个典型县的数据对粮食生产潜力短期预测的"趋势-波动模型"进行了系统性的验证和讨论。研究结果表明:(1)预测误差大小反映短期生产潜力的预测精度,预测误差大的主要原因是经济发达地区高产农田被大量占用和(或)蔬菜、水果种植面积大幅度增加而短期内使粮食单产下降;(2)小趋势修正方法是"趋势-波动模型"中不可缺少的一部分,它能将大趋势预测不能包括的短期如气象因素、科技投入、社会因素等影响纳入预测中,提高预测精度;(3)就我国近些年来的实际情况而言,越是经济发达的地区短期生产潜力的波动越大;同样发达地区短期潜力存在增加-下降-回升阶段;(4)就短期生产潜力预测精度而言:国家级大于省级、省级大于地区级、地区级大于县级;不同省、不同地区、不同县之间预测精度差别比较大,这与境内气候的互补性和农田抗御自然灾害的能力有关。     

磁化水在农作物上应用的研究进展

针对磁化水对农业生产的影响,简述了国内外关于磁化水应用的研究动态和发展趋势,介绍了磁化水在促进作物种子萌发、增强抗逆性以及提高产量和改善品质方面的研究进展。     

Single season effects of mixed-species cover crops on tomato health (cultivar Celebrity) in multi-state field trials

Cover crop use can help mitigate the deleterious effects of common cropping practices (e.g., tillage) and is, therefore, an important component of soil health maintenance. While known to be beneficial in the long-term, the short-term effects of cover crops, specifically mixed-species cover crops in organic systems are less clear. Cover crop effects on tomato productivity and disease severity were recorded over three field seasons (2010, 2011 and 2012) at sixteen field sites in three states, Maryland, New York and Ohio (MD, NY and OH), each with distinct soilborne disease pressure. Plots of five state-specific cover crop treatments were established the season prior to tomato production; the resulting plant residue was incorporated the following spring approximately four weeks before tomato planting. Total fruit yields along with early-season shoot height and fresh weight were used to compare treatment effects on productivity. Treatment disease severity ratings relied on natural inoculum. Interestingly, the effect of a single season of cover cropping on total yield was significant in no more than 25% of all site years. Similarly, cover crop effects on tomato disease levels were significant in 0–44% of the sixteen field sites. However, significant field-specific patterns were observed in every state across multiple years for some treatments. For example, in New York in 2010, tomato yields following all mixed cover crops were greater than the single rye cover crop in one field, but this pattern was reversed in the adjacent field. Thus, no general recommendation of a specific cover crop mixture can be made for near-term enhancement of tomato productivity or for reduction of disease. Therefore, growers should focus on location and operation-specific variables when choosing cover crops.     

Drought Tolerance and Water‐Use Efficiency of Biogas Crops: A Comparison of Cup Plant,Maize and Lucerne‐Grass

The cup plant (Silphium perfoliatum L.) is discussed as an alternative energy crop for biogas production in Germany due to its ecological benefits over continuously grown maize. Moreover, a certain drought tolerance is assumed because of its intensive root growth and the dew water collection by the leaf cups, formed by fused leaf pairs. Therefore, the aim of this study was to estimate evapotranspiration (ET ), water‐use efficiency (WUE ) and the relevance of the leaf cups for the cup plant's water balance in a 2‐year field experiment. Parallel investigations were conducted for the two reference crops maize (high WUE ) and lucerne‐grass (deep and intensive rooting) under rainfed and irrigated conditions. Root system performance was assessed by measuring water depletion at various soil depths. Transpiration‐use efficiency (TUE ) was estimated using a model approach. Averaged over the 2 years, drought‐related above‐ground dry matter reduction was higher for the cup plant (33 %) than for the maize (18 %) and lucerne‐grass (14 %). The WUE of the cup plant (33 kg ha^?1 mm^?1) was significantly lower than for maize (50 kg ha^?1 mm^?1). The cup plant had a lower water uptake capacity than lucerne‐grass. Cup plant dry matter yields as high as those of maize will only be attainable at sites that are well supplied with water, be it through a large soil water reserve, groundwater connection, high rainfall or supplemental irrigation.