河北低平原区冬小麦夏玉米产量提升的理论与技术研究
Research on exploiting wheat-maize grain yield theory and technology in the eastern low plain of Hebei Province
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摘要:作为渤海粮仓主要增粮区的河北东部低平原中低产农田, 冬小麦夏玉米的产量主要受制于土壤肥力水平低、淡水资源短缺和气候异常造成产量的大幅波动。通过选择适宜的品种、播期与收获期的合理搭配、优化的种植方式和配套的耕作与田间管理技术, 提高作物生育期内对地上光热资源和地下水肥资源的利用潜力和效率, 平抑气候变化带来不利影响, 有着巨大的增产空间。该研究通过田间小区试验, 结合示范区试验示范, 研究了冬小麦与夏玉米生育期的优化、夏玉米种植方式调整、夏玉米深松播种、夏玉米增施钾肥与冬小麦增施磷肥及有机肥等措施对冬小麦、夏玉米产量的影响。主要研究结果如下: 冬小麦适期晚播(不迟于10月15日), 同时适当增加播量, 不影响生育期群体构建和产量水平。早熟品种‘小偃81’提早进入灌浆期, 受后期干热风的危害小, 在不降低品质的同时粒重与产量稳定。夏玉米提早播10 d(6月10日与6月20日相比)平均增产17.2%, 晚收获8 d(10月2日与9月24日相比)粒重增加19.5%。根据冬小麦和夏玉米的品种特性, 合理搭配生育期, 在实现冬小麦稳产提质的同时, 使充分发挥夏玉米的产量潜力成为可能。改变夏玉米的种植方式, 适当增加种植密度, 明显地改善和提高了夏玉米产量, 更为适宜的种植方式是40 cm与80 cm大小行种植和38 cm等行距种植, 不适宜的是20 cm与100 cm大小行种植, 更为适宜的种植方式下产量提高15%以上。长期旋耕机械压实了犁底层, 通过夏玉米深松播种种植, 产量提高达31.3%, 后茬小麦增产5.6%, 但连续深松没有明显的增产效果。夏玉米播种时增施钾肥产量提高2.6%。冬小麦增施磷肥产量提高7.4%, 增施有机底肥增产6.8%, 增施有机底肥和施磷肥产量提高8.8%, 但无明显的累加效果。因此, 通过适宜的品种选择与适期的生育期搭配、种植方式调整、适时深松打破犁底层的耕作措施、速效肥与有机肥合理施用等栽培和管理技术, 可实现冬小麦夏玉米产量的逐步提高和稳定, 充分利用玉米生长季丰富且集中的降水与光热资源, 挖掘夏玉米产量, 稳夏增秋的粮食增产模式更符合该地区未来发展需求。Abstract:Medium and low-yield fields in the low plains of East Hebei Province are critical for “Bohai Granary” project for increasing grain yields at national level. Winter wheat-summer maize double cropping system is the main planting pattern for agricultural production in the area. The growth of winter wheat and summer maize is seriously restricted by water deficit, soil fertility and climate fluctuations, which results in the decreasing of grain yield. Summer maize growth season is accompanied by sufficient rain and heat, while winter wheat season is deficit in both rain and heat. There is a high potential to increase grain yield by selecting suitable cultivars, reasonable date of sowing matching with harvesting, optimization of planting, cultivation and management modes and technologies. The main aim of this research was to exploit increasing measures of winter wheat and summer maize grain yields with enhanced potential and use efficiency of resources such as water and fertilizer (by underground roots) and light and heat (by over-ground canopy). A total of eight field experiments were designed in the research, which included winter wheat seeding date, winter wheat cultivar, summer maize seeding date, summer maize harvesting date, summer maize planting pattern adjustment, deep scarification of summer maize planting, potassium fertilizer dose for summer maize, and phosphorus and organic fertilizer doses for winter wheat. The results showed that postponement of sowing date and increased seeding rate of winter wheat did not change grain yield. Early maturity winter wheat cultivar reduced the effect of dry hot wind which in turn stabilized grain yield and quality. Early seeding of summer maize by 10 days increased grain yield by 17.2%, while late harvesting by 8 days increased grain weight by 19.5%. Adjustment of summer maize planting patters improved canopy structure and enhanced the use efficiency of photosynthetically active radiation. Row spacing of 40 cm wiht 80 cm and the same of row and plant spacing of 38 cm were superior to other planting patterns, which increased grain yield by more than 15%. Planting summer maize with deep scarification increased grain yield by 31.3% and improved the next winter wheat grain yield by 5.6%. However, these effects were not observed in successive deep scarification in the following years. Summer maize with increased potassium fertilizer improved grain yield by 2.6%, winter wheat with phosphorus fertilizer improved grain yield by 7.4%, and winter wheat with organic fertilizer improved grain yield by 6.8% compared with that of control. However, when phosphorus and organic fertilizers were used simultaneously, winter wheat grain yield increased by 8.8%, without obvious superposition effect of fertilizers. The steady increase in grain yield was due the selection of suitable cultivars which matched with the sowing periods and other management practices, planting patterns, planting technologies, fertilization schemes, tillage patterns, etc. The planting mode which stabilized winter wheat grain yield and increased the potentials of summer maize grain yield was most suitable in the study area. This mode made the fullest use of local climate factors such as precipitation, sunlight and soil heat.