行距和播种量对冬小麦冠层光合有效辐射垂直分布、生物量和籽粒产量的影响

为明确行距和播种量对冬小麦冠层光合有效辐射(PAR)垂直分布、生物量和籽粒产量的影响,在不增加水肥等投入的基础上,设置等行距(R₁,20 cm+20 cm)、宽窄行(R₂,12 cm+12 cm+12 cm+24 cm)两种行距方式和低(D₁,120 kg·hm^-2)、中(D₂,157.5 kg·hm^-2)、高(D₃,195 kg·hm^-2)3个播种量水平,分析不同处理组合下冬小麦主要生育时期冠层PAR的截获率及利用率、群体光合能力、生物量和产量差异。结果表明: 冬小麦冠层总PAR截获率、上层PAR截获率均表现为R₁行距显著大于R₂,而中层和下层PAR截获率则表现为R₂大于R₁,且在中层差异显著;从小麦开花至成熟期,相同播种量下R₂行距光合势(LAD)、群体光合速率(CAP)、PAR转化率和利用率都显著高于R₁,并以R₂D₂处理最大;冬小麦的群体生物量(BA)和不同层次叶片生物量(BL)均表现为随播种量增加而增加,但单株生物量(BP)则相反。在同一播种量下,BA、BL和BP均在开花期之后表现为R₂行距高于R₁,其中,BA、BP在成熟期行距间差异显著,中层和下层BL在D₂、D₃播种量下行距间差异显著;不同处理组合间冬小麦的穗数、穗粒数、千粒重、籽粒产量分别以R₂D₃、R₂D₁、R₂D₁、R₂D₂最大,其中,R₂行距下千粒重、穗粒数和籽粒产量显著大于R₁。综上,改变行距可以改善小麦冠层中下层PAR的截获量,增强冬小麦单株和群体光合能力、光合有效辐射的利用及转化效率,提高生物量和籽粒产量。在冬小麦高产栽培中,应重视通过优化田间结构,塑造麦田理想的群体光合结构,以充分利用单位土地面积上光照资源,挖掘作物自身的光合生产潜力,达到高产高效的目的。在本试验条件下,以R₂D₂配置群体光合能力、光合有效辐射利用率和产量最佳。

Effects of row spacing and sowing rate on vertical distribution of photosynthetically active radiation,biomass, and grain yield in winter wheat canopy.

To clarify the effects of row spacing and sowing rate on the vertical distribution of canopy PAR, biomass, and grain yield in winter wheat, a field experiment was conducted without increa-sing water and fertilizer input. There were two row spacing modes, R₁ (equal spacing, 20 cm+20 cm) and R₂(wide and narrow row spacing, 12 cm+12 cm+12 cm+24 cm), and three sowing rates, D₁ (low, 120 kg·hm^-2), D₂ (medium, 157.5 kg·hm^-2), D₃ (high, 195 kg·hm^-2). The canopy photosynthetically active radiation (PAR) interception and utilization rate in different heights, population photosynthetic capacity, biomass, and grain yield were measured during the main growth stages of winter wheat. The results showed that both total PAR interception and upper layer PAR interception of winter wheat canopy under R₁ treatment were significantly higher than those in R₂ treatment, but those of the middle layer and lower layer were higher in R₂ than in R₁, and with significant difference in the middle layer. From flowering to maturity, the photosynthetic potential (LAD), population photosynthetic rate (CAP), PAR conversion rate, and utilization rate in R₂ were all significantly higher than those in R₁ under the same sowing rate, with the highest value under R₂D₂ treatment. With the increasing sowing rate, the population biomass (BA) and leaf biomass (BL) at different layers increased, but the individual biomass (BP) showed an opposite trend. Under the same sowing rate, BA, BL and BP in R₂ were higher than that in R₁ after the flowering stage. Among them, BA and BP had significant difference in row spacing treatments at the maturity stage, with significant difference between the two row spacing treatments being observed in BL of the middle and lower layers under D₂ and D₃ sowing rates. The spike number, grain number per spike, 1000-kernel weight, and grain yield of winter wheat among different treatments were the highest in R₂D₃, R₂D₁, R₂D₁, and R₂D₂, respectively. The 1000-kernel weight, grain number per spike and grain yield in R₂ treatment were significantly higher than R₁. In summary, the PAR interception in the middle and lower layers of winter wheat canopy was improved by changing row spacing, with positive consequence on the photosynthetic capacity of individual plant and population, PAR utilization and transformation efficiency, which finally increased biomass and grain yield. Therefore, optimizing the field structure and shaping the ideal population photosynthetic structure should pay more attention during the high-yield cultivation of winter wheat. Making full use of light resources per unit land area and excavating the photosynthetic production potential of crops were also critical to achieve high yield and efficiency. In this experiment, the population photosynthetic capacity, photosynthetic effective radiation utilization rate, and yield were the highest under the treatment of R₂D₂.