填闲种植和施氮量对旱作冬小麦农田土壤水分及作物产量的影响

田间试验研究了填闲种植和施氮对旱作冬小麦农田土壤水分和作物产量的影响。试验设双因素处理随机区组设计,填闲作物采用黑麦草单播(R)、长武怀豆单播(S)、黑麦草与怀豆混播(SR)以及裸地休闲(NC),氮肥水平设0、60、120 kg·hm-2三个水平。结果表明,与裸地休闲相比,长武怀豆单播和与黑麦草混播夏闲期降水贮存效率分别降低了9.2%和7.7%,小麦播前土壤含水量减少了19 mm和15 mm,进而导致后续小麦产量的显著下降;而黑麦草单播对土壤水分和后续小麦产量没有显著影响;种植小麦前施加氮肥可以提高粮食作物产量、收获指数和千粒重,同时可增加次年填闲作物生物量,但会加速土壤水分消耗、降低降水储存效率。从土壤水分和作物生产角度考虑,旱作冬小麦种植系统休闲期间可以考虑种植黑麦草以增加覆盖,提高肥力,但不建议填闲种植耗水量较高的怀豆等作物。

绿肥填闲种植对旱作冬小麦农田耕层土壤物理性质的影响

[目的]探讨绿肥填闲种植对旱作冬小麦农田耕层土壤物理性质的影响,为其在黄土高原旱作农业区的推广提供科学依据。[方法]基于4 a田间定位试验,研究了夏闲期种植长武怀豆、苏丹草、怀豆/苏丹草混播以及裸地休闲(CK)对旱作冬小麦收获期农田耕层(0—20 cm)土壤容重、孔隙度、持水量和团聚体的影响。[结果]在0—10 cm土层,与CK相比,苏丹草和混播处理显著降低了土壤容重,怀豆,苏丹草和混播处理显著提高了土壤毛管孔隙度、总孔隙度、饱和持水量、毛管持水量、大团聚体(>5 mm)所占比例和团聚体平均重量直径(MWD);在10—20 cm土层,苏丹草处理大团聚体所占比例和MWD均显著高于CK。土壤容重与土壤有机碳含量呈显著负相关,毛管孔隙度和团聚体平均重量与绿肥生物量呈显著正相关,而土壤总孔隙度、饱和持水量和毛管持水量与绿肥生物量和土壤有机碳均呈显著正相关。[结论]在黄土高原地区,夏闲期单播种植长武怀豆、苏丹草及混播均能显著改善耕层土壤物理性质,综合来看,苏丹草单播的效果优于长武怀豆单播和二者混播。

绿肥填闲种植对旱作冬小麦农田土壤团聚体有机碳含量的影响

依托黄土塬区4 a绿肥填闲种植田间定位试验,开展不同填闲作物对土壤团聚体组成及各组分有机碳在团聚体中分布影响的研究,为阐明填闲种植措施下土壤有机碳库的物理保护机制提供依据。试验设置4个处理,即冬小麦夏闲期种植长武怀豆(SB)、苏丹草(SG)、怀豆/苏丹草混播(Mix)和裸地休闲(CK)。利用干筛法将全土筛分为>5 mm、2~5 mm、0.25~2 mm和<0.25 mm等4个粒级,分别测定土壤和各粒级团聚体中有机碳和颗粒有机碳含量,进而计算团聚体平均重量直径及有机碳贡献率。结果表明:绿肥种植对土壤团聚体分布有显著影响,各绿肥处理均有利于0~10 cm土层土壤团聚体的形成,但对亚表层土壤团聚结构影响较小。与CK相比,在0~40 cm各土层,SB、SG和Mix处理均显著提高土壤有机碳含量、颗粒有机碳含量及团聚体平均重量直径,提高幅度分别为7.9%、8.0%和7.9%,其中SB更有利于表层土壤有机碳的固存,且土壤有机碳和颗粒有机碳含量之间呈显著正相关关系,这两者与团聚体平均重量直径之间均呈显著负相关关系。不同处理下土壤团聚体各有机碳组分含量存在差异,与CK相比,SB和Mix均显著提高了0~10 cm土层团聚体各粒径有机碳和颗粒有机碳含量,而SG更有利于提高10~20 cm土层团聚体有机碳含量。各粒级团聚体有机碳含量均以<0.25 mm团聚体最高,但80%以上的各组分有机碳来自于>0.25 mm团聚体。此外,绿肥种植均提高了>5 mm团聚体有机碳和颗粒有机碳贡献率,使更多的有机碳保存在>5 mm团聚体中,有利于提高土壤供肥能力。综上所述,在黄土高原旱作农业区,冬小麦夏闲期种植绿肥作物可以有效提升土壤碳储量,同时促进团聚体有机碳库的分布及固持,且长武怀豆单播方式的表层固碳效果最优。

Characteristics of Nutrient Salt Uptake Associated with Water Use of Corn as a Catch Crop at Different Plant Densities in a Greenhouse

Dent corn, as a catch crop used for salt removal, was cultivated at different densities, i.e., 7.3 （low density）, 59.7 （normal density）, and 119.5 plants m-2 （high density）, during a 50 d fallow period after cultivation of a commercial crop in a greenhouse, to analyze the characteristics of nutrient salt （N, K, Mg, and Ca） uptake by roots and to study the effect of plant density on the characteristics associated with crop water use. Leaf area index for the high and normal density treatments reached extremely high values of 24.3 and 14.9, respectively. These values induced higher transpiration rates that were estimated using the Penman-Monteith model with the incorporation of specific parameters for crop and greenhouse conditions. The total N, K, Mg, and Ca contents in the crop canopy at harvest were 26.8, 13.0, 1.0, and 1.7 g m-S, respectively, under the high density treatment. The dynamics of salt uptake rates for high, normal, and low density treatments were evaluated by assessing weekly changes in salt content, and were subsequently compared against the transpiration rate. A positive linear relationship was obtained between these 2 parameters for all 3 density treatments and all tested salts. Hence, higher transpiration rates caused higher salt uptake rates through water absorption. On the other hand, salt uptake efficiency per unit water use by cultivation was lower in the low density treatment. Therefore, management procedures with dense planting that induce higher transpiration rates and lower evaporation rate are extremely important for the effective cultivation of corn catch crops.