缓释氮肥与尿素掺混对玉米生理特性和氮素吸收的影响

【目的】研究不同施氮量下尿素与缓释氮肥掺混对大田玉米生理特性、氮素吸收和土壤硝态氮残留的影响,以期探索减少土壤硝态氮淋失、提高氮肥利用效率的高效施氮管理模式。【方法】试验在西北农林科技大学节水灌溉试验站进行,供试土壤质地为壤土,玉米品种为郑单958。设置了3种氮肥类型为尿素(U)、缓释氮肥(S)、尿素和缓释氮肥以3∶7比例掺混(SU); 4个施氮(N)水平为90 kg/hm^2 (N1)、120 kg/hm^2 (N2)、180kg/hm^2 (N3)、240 kg/hm^2 (N4),以不施氮肥(N0)为对照,共13个处理。在生育期内对玉米的产量和生理指标进行观测,并测定玉米主要生育期植株养分和土壤硝态氮含量。【结果】尿素掺混缓释氮肥(SU)处理的玉米生长后期叶绿素总量最大值分别比尿素(U)处理和缓释氮肥(S)处理最大值提高7.7%和1.3%。各生育期尿素掺混缓释氮肥(SU) N3处理的净光合速率和蒸腾速率最高,分别高于其他处理6.9%~88.6%和3.4%~90.3%。尿素掺混缓释氮肥(SU)处理能够更好地促进玉米对氮素的吸收利用,其中尿素掺混缓释氮肥(SU) N3处理氮素吸收量和籽粒的氮素分配量达最大,分别为156.0 kg/hm^2和79.7 kg/hm^2,高于其他处理8.1%~67.3%和6.2%~54.1%。尿素(U) N3处理与缓释氮肥(S) N2处理的氮素吸收量和籽粒的氮素分配量无显著差异;尿素掺混缓释氮肥(SU)在N3施氮量下,产量达到最高为6200.4 kg/hm^2,比尿素(U) N3处理和缓释氮肥(S) N2处理的产量分别增加了20.7%和19.8%。与单施尿素(U)和缓释氮肥(S)处理相比,尿素掺混缓释氮肥(SU)处理能充分利用0—40 cm土层养分,减少土壤氮素向更深土层淋失,提高氮肥利用率,降低土壤环境污染的风险。【结论】尿素与缓释氮肥掺混条件下,施氮量180 kg/hm^2是提高试验区玉米叶绿素含量和光合作用,促进氮素吸收,减少硝态氮向土壤深层淋失的最佳施肥管理模式。

关中平原冬小麦临界氮稀释曲线建模

临界氮稀释曲线可诊断植株氮营养状况,针对国内目前普遍存在的建模品种单一,可能造成模型普适性偏差的问题,以陕西关中平原主栽的6个冬小麦品种为研究对象,分别设置4个(0、105、210 kg·hm^-2 和315 kg·hm ^-2 )施氮量水平,以两季4个冬小麦品种田间数据,建立了冬小麦花期前地上部干物质临界氮稀释曲线,曲线服从负幂指数函数;进一步通过另外2个冬小麦品种共计两季数据对模型进行了验证,验证结果表明,采用临界氮稀释曲线可以较好地区分独立样本中的氮营养亏缺和氮营养过剩数据。依据临界氮稀释曲线建立的氮营养指数和累计氮亏缺模型,可分别用于诊断植株的氮营养状况和量化氮素盈亏量,诊断结果表明施氮量为0 kg·hm^-2 和105 kg·hm^-2 条件下植株氮营养亏缺,210 kg·hm ^-2 和315 kg·hm ^-2 条件下小麦氮营养盈余,0~315 kg·hm^-2 施氮量下的累计氮亏缺量-33.2~50.9 kg·hm ^-2 。通过建立氮营养指数与施氮量之间的线性关系,得出关中平原冬小麦适宜施氮量约为162 kg·hm ^-2 。

基于熵权法和TOPSIS法优化马铃薯钾肥种类和滴灌量组合

【目的】探寻滴灌施肥条件下实现沙土马铃薯高产优质和水肥高效的管理方式,为陕北马铃薯滴灌水钾管理提供科学依据。【方法】以‘青薯9号’为试验材料,于2020年马铃薯生长季,在陕北榆林风沙区设置W1 (60%ET_(c),198.4 mm,ET_(c)为作物需水量)、W2 (80%ET_(c),246.2 mm)和W3 (100%ET_(c),294 mm) 3个灌水水平及不施钾肥(K0)、KCl、K_(2)SO_(4)和KNO_(3)4种钾肥处理,调查了马铃薯的生长状况、产量、品质,计算了水分利用效率(WUE)和肥料偏生产力(PFP)。【结果】钾肥种类与滴灌量及其交互作用对马铃薯产量及其构成要素、WUE和PFP有显著影响。相同钾肥处理下,W3灌溉水平的马铃薯块茎产量、淀粉含量、净收益平均分别比W1水平提高了19.8%、3.8%、33.9%,分别比W2水平提高了8.1%、1.6%、15.8%。不同灌水量下,不同钾肥的增产效果不同。W1水平下,KCl处理的马铃薯干物质累积量、产量显著低于K_(2)SO_(4)和KNO_(3)处理;W2和W3水平下,KNO_(3)处理的马铃薯干物质累积量、产量、商品薯重和净收益显著高于KCl和K_(2)SO_(4)处理,而K2SO4和KCl处理之间无显著差异。就水钾交互而言,W3+KNO_(3)处理的产量显著高于其他处理9.2%~55.0%;W3+K_(2)SO_(4)处理的淀粉含量最高,还原糖含量最低;W3+KCl处理的产投比最大,W1+KNO3处理的WUE最大。基于熵权法和TOPSIS分析得出各处理优劣顺序为W3+KNO_(3)>W3+KCl>W2+KNO3>W3+K2SO4>W2+K_(2)SO_(4)>W3K0>W2+KCl>W1+KNO3>W1+K_(2)SO_(4)>W1+KCl>W2K0>W1K0。【结论】基于熵权法和TOPSIS分析,在陕北沙土马铃薯种植系统中兼顾高产、优质和水肥高效的组合为硝酸钾肥配合100%作物需水量。

Determination of critical nitrogen dilution curve based on leaf area index for winter wheat in the Guanzhong Plain, Northwest China

Excessive use of nitrogen (N) fertilizers in agricultural systems increases the cost of production and risk of environmental pollution. Therefore, determination of optimum N requirements for plant growth is necessary. Previous studies mostly established critical N dilution curves based on aboveground dry matter (DM) or leaf dry matter (LDM) and stem dry matter (SDM), to diagnose the N nutrition status of the whole plant. As these methods are time consuming, we investigated the more rapidly determined leaf area index (LAI) method to establish the critical nitrogen (Nc) dilution curve, and the curve was used to diagnose plant N status for winter wheat in Guanzhong Plain in Northwest China. Field experiments were conducted using four N fertilization levels (0, 105, 210 and 315 kg ha?1) applied to six wheat cultivars in the 2013–2014 and 2014–2015 growing seasons. LAI, DM, plant N concentration (PNC) and grain yield were determined. Data points from four cultivars were used for establishing the Nc curve and data points from the remaining two cultivars were used for validating the curve. The Nc dilution curve was validated for N-limiting and non-N-limiting growth conditions and there was good agreement between estimated and observed values. The N nutrition index (NNI) ranged from 0.41 to 1.25 and the accumulated plant N deficit (Nand) ranged from 60.38 to –17.92 kg ha?1 during the growing season. The relative grain yield was significantly affected by NNI and was adequately described with a parabolic function. The Nc curve based on LAI can be adopted as an alternative and more rapid approach to diagnose plant N status to support N fertilization decisions during the vegetative growth of winter wheat in Guanzhong Plain in Northwest China.