南繁区稻瘟病菌遗传多样性和群体遗传结构的AFLP分析

【目的】为了明确南繁区稻瘟病菌(Magnaporthe oryzae)的遗传分化情况,【方法】采用AFLP分子标记技术对南繁核心区(三亚、乐东和保亭)和非核心区(琼中、屯昌和定安)共60个稻瘟病菌菌株的遗传多样性和群体遗传结构进行了比较分析。【结果】聚类分析表明,几乎所有菌株都聚在同一个谱系里,并且该谱系没有明显的亚群;群体遗传结构分析表明,核心区群体的多态性位点百分率、Shannon信息指数和基因流分别为87.89%、0.2738和4.2897,高于非核心区群体的81.37%、0.2703和3.5892;然而,核心区群体的Nei基因多样性指数和基因分化系数分别为0.1657和0.1044,低于非核心区群体的0.1662和0.1223。【结论】这些结果表明核心区和非核心区菌株都存在丰富的遗传多样性,不同群体间均存在较多的基因交流,但遗传变异均主要来自群体内;相比之下,核心区菌株的遗传多样性和遗传分化程度较高。     

产粮大省玉米秸秆综合利用的困局与对策研究

农作物秸秆作为"另一半农业",是一种重要的可供开发和综合利用的生物质资源。以吉林省2005~2014年间玉米产量为基础,测算出吉林省玉米秸秆理论资源量和可收集量,对该地区玉米秸秆综合利用途径现状和障碍因素进行简要评价。促使玉米秸秆综合利用得到更好的发展应该重视宣传引导,努力转变农民对秸秆综合利用的认识;加大政府财政支持力度,优化机制;建立秸秆技术研发体系,促进产业发展,以项目带动产业发展规模化;搞好示范推广作用,积极挖掘秸秆文化产业等。     

我国农作物病虫害化学防控技术的社会成本分析

农作物病虫害化学防控技术的负外部效应产生了环境和社会成本。评价化学防控技术的社会成本,具有十分重要的理论和现实意义。本文分析了农作物病虫害化学防控技术社会成本产生的原因与类别,指出农药中毒、接触农药导致的慢性疾病、农产品农药残留超标、农药包装废弃物回收处理、农药及农药残留管理行政事业费用、农药市场检测和监控、农药残留检测和监控是主要的社会成本类别。初步分析了各类别社会成本的经济影响额度,测算出我国使用化学农药防控农作物病虫害的所产生的社会成本至少在11.72～87.74元/kg(折百)。     

温室番茄结果期产量和品质对水分亏缺的响应

试验以甘肃武威市凉州区传统灌水量为对照(CK),设计3个灌水量水平CK、2/3CK、1/2CK,在番茄结果期研究亏缺灌溉对日光温室番茄累计产量及平均单果质量、品质、干物质分配及水分利用效率的影响。结果表明,随着灌水量的减少,水分利用率显著提高,番茄果实中的可溶性固形物、可溶性蛋白、有机酸和Vc含量均增加,果实的累计采收...     

Yield and soil system changes from conservation tillage in dryland farming: A case study from North Eastern Tanzania

Yield levels in smallholder farming systems in semi-arid sub-Saharan Africa are generally low. Water shortage in the root zone during critical crop development stages is a fundamental constraining factor. While there is ample evidence to show that conservation tillage can promote soil health, it has recently been suggested that the main benefit in semi-arid farming systems may in fact be an in situ water harvesting effect. In this paper we present the result from an on-farm conservation tillage experiment (combining ripping with mulch and manure application) that was carried out in North Eastern Tanzania from 2005 to 2008. Special attention was given to the effects of the tested treatment on the capacity of the soil to retain moisture. The tested conservation treatment only had a clear yield increasing effect during one of the six experimental seasons (maize grain yields increased by 41%, and biomass by 65%), and this was a season that received exceptional amounts of rainfall (549 mm). While the other seasons provided mixed results, there seemed to be an increasing yield gap between the conservation tillage treatment and the control towards the end of the experiment, and cumulatively the yield increased with 17%. Regarding soil system changes, small but significant effects on chemical and microbiological properties, but not on physical properties, were observed. This raises questions about the suggested water harvesting effect and its potential to contribute to stabilized yield levels under semi-arid conditions. We conclude that, at least in a shorter time perspective, the tested type of conservation tillage seems to boost productivity during already good seasons, rather than stabilize harvests during poor rainfall seasons. Highlighting the challenges involved in upgrading these farming systems, we discuss the potential contribution of conservation tillage towards improved water availability in the crop root zone in a longer term perspective.     

Comparisons of energy balance and evapotranspiration between flooded and aerobic rice fields in the Philippines

The seasonal and annual variability of sensible heat flux (H), latent heat flux (LE), evapotranspiration (ET), crop coefficient (K_c) and crop water productivity (WP_ET) were investigated under two different rice environments, flooded and aerobic soil conditions, using the eddy covariance (EC) technique during 2008-2009 cropping periods. Since we had only one EC system for monitoring two rice environments, we had to move the system from one location to the other every week. In total, we had to gap-fill an average of 50-60% of the missing weekly data as well as those values rejected by the quality control tests in each rice field in all four cropping seasons. Although the EC method provides a direct measurement of LE, which is the energy used for ET, we needed to correct the values of H and LE to close the energy balance using the Bowen ratio closure method before we used LE to estimate ET. On average, the energy balance closure before correction was 0.72 ± 0.06 and it increased to 0.99 ± 0.01 after correction. The G in both flooded and aerobic fields was very low. Likewise, the energy involved in miscellaneous processes such as photosynthesis, respiration and heat storage in the rice canopy was not taken into consideration.Average for four cropping seasons, flooded rice fields had 19% more LE than aerobic fields whereas aerobic rice fields had 45% more H than flooded fields. This resulted in a lower Bowen ratio in flooded fields (0.14 ± 0.03) than in aerobic fields (0.24 ± 0.01). For our study sites, evapotranspiration was primarily controlled by net radiation. The aerobic rice fields had lower growing season ET rates (3.81 ± 0.21 mm d⁻¹) than the flooded rice fields (4.29 ± 0.23 mm d⁻¹), most probably due to the absence of ponded water and lower leaf area index of aerobic rice. Likewise, the crop coefficient, K_c, of aerobic rice was significantly lower than that of flooded rice. For aerobic rice, K_c values were 0.95 ± 0.01 for the vegetative stage, 1.00 ± 0.01 for the reproductive stage, 0.97 ± 0.04 for the ripening stage and 0.88 ± 0.03 for the fallow period, whereas, for flooded rice, K_c values were 1.04 ± 0.04 for the vegetative stage, 1.11 ± 0.05 for the reproductive stage, 1.04 ± 0.05 for the ripening stage and 0.93 ± 0.06 for the fallow period. The average annual ET was 1301 mm for aerobic rice and 1440 mm for flooded rice. This corresponds to about 11% lower total evapotranspiration in aerobic fields than in flooded fields. However, the crop water productivity (WP_ET) of aerobic rice (0.42 ± 0.03 g grain kg⁻¹ water) was significantly lower than that of flooded rice (1.26 ± 0.26 g grain kg⁻¹ water) because the grain yields of aerobic rice were very low since they were subjected to water stress.The results of this investigation showed significant differences in energy balance and evapotranspiration between flooded and aerobic rice ecosystems. Aerobic rice is one of the promising water-saving technologies being developed to lower the water requirements of the rice crop to address the issues of water scarcity. This information should be taken into consideration in evaluating alternative water-saving technologies for environmentally sustainable rice production systems.     

用GIS和作物模型对作物生产进行区域模拟方法

简要地介绍了区域模拟及对模拟结果进行检验的方法。基于空间地理信息的模拟既能反映大范围地区内气候、土壤等地理信息的空间变量对作物产量的影响 ,也能反映不同地区社会经济情况、农业耕作方式等对作物生产的影响。在GIS技术支持下 ,对基于站点的作物生长模拟模型进行改造 ,从而对大区域范围进行以特点网格 (如 5 0km× 5 0km)为单元的模拟     

云南玉米需水规律及灌溉效应的试验研究

基于玉米苗期控水试验和玉米需水量田间试验，分析研究了土壤含水量和灌溉对出苗率、成活率、有效株数和玉米产量经济性状的影响，得到了云南玉米生长季内各月平均日需水量和玉米作物系数。研究认为，苗期灌溉或降水条件好能确保基本的有效株数，促进营养生长；在光照条件好但干旱缺水年份，灌溉的增产效益十分突出；但在干旱缺水影响较小的条件下，玉米灌溉的增产效益并不显著。     

成膜保水剂增强土壤保水能力研究

成膜保水剂是一种新型土壤改良剂,通过试验发现:0 2%PAA低浓度的成膜保水剂对大多数作物种子的发芽产生促进作用,可提高作物种子的发芽率;0 2%、0 4%PAA浓度的成膜保水剂对玉米的生长有促进作用。酸碱环境不同成膜保水剂在土壤中的成膜深度不同,酸性越强成膜越浅,而且,具有较好的防渗效果。成膜保水剂对土壤的保水性能有较大改善,尤其对20cm土壤耕层的效果更为明显,田间持水量比对照相对增长达27 5%。生产上应针对不同作物采用不同浓度和pH的成膜保水剂。     

Crop responses to applied soil compaction and to compaction repair treatments

Crop responses to annual compaction treatments (applied to whole plots) and management treatments to ameliorate compacted soil were determined in a field experiment on a Vertisol. Initially, all treatments except a control were compacted with a 10 Mg axle load on wet soil (26% gravimetric water content compared with a plastic limit of 22%). Annually applied axle loads of 10 and 6 Mg on wet soil (25–32% soil water) tended to reduce seedling emergence, grain yield (wheat, sorghum and maize), soil water storage and crop water use efficiency (WUE). Annual applications of an axle load of 6 Mg on dry soil (<22% soil water) had little effect on crop performance. Mean reductions in the yield of five crops (three wheat, one sorghum and one maize) in comparison with the uncompacted control were 23% or 0.79 Mg ha⁻¹ (10 Mg on wet soil), 13% or 0.44 Mg ha⁻¹ (6 Mg on wet soil) and 1% or 0.03 Mg ha⁻¹ (6 Mg on dry soil). Maize grown in the fifth year of treatment application was most affected by compaction of wet soil, its WUE being reduced from 14.3 to 9.7 kg ha⁻¹ mm⁻¹ in response to an axle load of 10 Mg. Reduced WUE was associated with delayed soil water extraction at depth. A 3-year pasture ley was the most successful amelioration treatment. A wheat and a maize crop grown after the ley outyielded the control by 0.33 and 0.90 Mg ha⁻¹, respectively. So the pasture not only ameliorated the initial compaction damage, with respect to crop performance, but resulted in improvements in two subsequent crops.