玉米/大豆和玉米/甘薯模式下玉米光合特性差异及氮肥调控效应

Differences in maize photosynthetic characteristics and nitrogen regulation effects in maize/soybean and maize/sweet potato relay strip intercropping

  • 摘要: 玉米与大豆或甘薯套作是西南地区玉米种植的两种主要模式, 为探讨两种套作模式下玉米光合特性差异及施氮效应, 于2008―2010年在四川省2个玉米主栽区, 开展了玉米/大豆和玉米/甘薯两种模式的定位试验, 对比两种模式下玉米光合特性的差异; 在此基础上于2011年采用两因素裂区设计, 在两种模式上分别设5个施氮量0 kg(N)·hm-2 (N0)、90 kg(N)·hm-2 (N90)、180 kg(N)·hm-2 (N180)、270 kg(N)·hm-2 (N270)和360 kg(N)·hm-2 (N360), 通过分析不同处理玉米叶面积指数、叶绿素相对值、穗位叶叶片含氮量、光合速率和荧光参数动态变化, 研究施氮水平对两种模式下玉米光合特性的影响。结果表明: 种植模式和施氮量对玉米光合特性具有明显的调节作用。与玉米与甘薯套作相比, 玉米与大豆套作显著减缓了玉米灌浆期到成熟期单株叶面积、叶绿素相对值的下降速率, 提高了穗位叶片PSⅡ活性及其光化学效率, 从而提高了光合速率, 成熟期单株生物量较玉米/甘薯模式增加10.49 g。换带轮作后, 从抽雄吐丝期开始, 玉米光合特性各指标在两模式间差异达显著水平, 玉米/大豆模式下玉米单株叶面积、净光合速率、穗位叶片Fv/Fm、ФPSⅡ花后各生育时期平均较玉米/甘薯模式高941 cm2、4.81 ?mol·m-2·s-1、0.017和0.020; 灌浆期到成熟期各指标下降速率玉米/大豆模式较玉米/甘薯模式也明显减缓, 成熟期玉米单株生物量玉米/大豆模式较玉米/甘薯模式平均高26.83 g。玉米/大豆模式下以180 kg·hm-2、玉米/甘薯模式下以270 kg·hm-2施氮处理, 提高了玉米的单株叶面积、叶绿素荧光动力学参数, 有利于玉米灌浆期间光系统Ⅱ反应中心维持较高比例的开放程度, 从而提高光合速率, 增加生物积累量。过量施氮(270~360 kg·hm-2), 叶绿素含量、叶片的Fv/Fm、ФPSⅡ下降, 光合速率降低。

     

    Abstract: Maize/soybean and maize/sweet potato relay strip intercropping systems are the two main intercropping systems in Southwest China. In two main maize production areas in Sichuan Province, differences in photosynthetic characteristics of maize under maize/soybean and maize/sweet potato relay strip intercropping systems were investigated based on long-term experiment (2008-2010). Also the data for 2011 was used to investigated the effects of nitrogen application rates on maize photosynthetic characteristics with the split-plot design experiment of different nitrogen application rates 0 kg(N) hm-2 (N0), 90 kg(N) hm-2 (N90), 180 kg(N) hm-2 (N180), 270 kg(N) hm-2 (N270) and 360 (N360) kg(N) hm-2 in maize/soybean and maize/sweet potato relay strip intercropping systems. Differences in photosynthetic characteristics in maize were determined based on analysis of leaf area index, relative content of chlorophyll, nitrogen content in ear leaf, photosynthetic rate and chlorophyll fluorescence parameters. Results showed that different planting patterns and nitrogen managements had fine adjustment effects on photosynthetic characteristics of maize. Compared with the traditional relay strip intercropping pattern ― maize/sweep potato relay intercropping system, maize/soybean relay intercropping system significantly slowed down the decreasing rates of leaf area per plant and the relative content of chlorophyll from filling stage to maturity stage, increased the activity of PSⅡ in ear-leaf and photochemical efficiency. Consequently, under maize/soybean relay intercropping, maize photosynthetic rate increased, and biomass per plant at maturity stage was higher by 10.49 g over that under maize/sweet potato relay intercropping. After strip crop rotation, the differences in all the indexes of photosynthetic characteristics since tasseling stage between the two cropping patterns were significant. Under maize/soybean relay strip intercropping, leaf area per plant, net photosynthetic rate, and ear-leaf Fv/Fm and ФPSⅡ were higher after flowering stage respectively by 941 cm2, 4.81 ?mol·m-2·s-1, 0.017 and 0.020 than those under maize/sweet potato system. From filling to maturity stages, the decreasing rates of all the indexes of maize/soybean relay intercropping were obviously lower than those of maize/sweet potato relay intercropping. Maize biomass per plant at maturity stage of maize/soybean relay intercropping was higher by 26.83 g than that of maize/sweet potato relay intercropping. Maize leaf area per plant and chlorophyll fluorescence parameters increased under treatment N180 for maize/soybean relay intercropping system, and under treatment N270 for maize/sweet potato relay intercropping system, with both treatments having increased photosynthetic rate and biomass accumulation. Excessive application of nitrogen (270-360 kg·hm-2) deceased chlorophyll content, leaf Fv/Fm and ФPSⅡ and photosynthetic rate in both intercropping systems.

     

/

返回文章
返回