设施菜田不同施氮处理对硝酸盐迁移和积累的影响

在设施菜地条件下,研究了氮肥减施及配施抑制剂处理在黄瓜生长期对土壤NO3--N迁移累积的影响。结果表明,氮肥减施处理可显著降低土壤表层和整个土体的NO3--N含量。常规施氮量时0~40 cm土层的NO3--N含量均高于其它处理,减氮30%后0~40 cm土层未出现NO3--N显著积累现象;氮肥配施抑制剂处理不同程度降低了土壤NO3--N含量,且抑制硝态氮向下层土壤淋失,其中抑制剂组合的效果最好。氮肥配施抑制剂,可以有效控制NO3--N在土壤和植物体内的过量累积,减少硝态氮淋溶损失。     

设施菜地土壤次生盐渍化分类与分级标准

近三十年来,我国设施蔬菜栽培发展迅速,已成为我国农业中最有活力的新兴产业之一。但在长期的设施蔬菜生产过程中,普遍存在着不合理施肥、养分比例失调、肥效下降和资源浪费严重等问题,致使土壤养分富集,盐分积累现象日趋严重。本文对我国设施菜地土壤次生盐渍化的现状、发生原因及其对作物的危害进行综述和分析,在此基础上制定设施菜地土壤次生盐渍化分类与分级的标准的建议及初步构架,旨在为防治设施菜地土壤次生盐渍化,实现设施菜地土壤的质量调控与可持续利用提供理论指导和科学依据。     

不同形态氮肥对设施土壤盐分含量和离子组成的影响

通过室内模拟培养实验,研究了尿素、碳酸氢铵和硝酸钙对设施土壤盐分含量和离子组成的影响.结果表明:(1)随着培养时间延长,不同形态氮肥处理土壤含盐量总体呈先升高后降低再升高的趋势.施肥处理的土壤含盐量较对照(CK)明显增加,但不同氮肥处理与未施氮肥处理(N0)间的土壤含盐量在整个培养期间内总体差异不显著.且氮肥用量对含盐量的影响也不显著.(2)设施土壤中尿素和碳酸氢铵处理的电导率与含盐量呈极显著正相关,硝酸钙处理电导率与含盐量呈显著正相关.且随培养时间的延长呈波浪状变化.其电导率显著高于相同氮用量时的其他两种氮肥处理;电导率与氮肥用量呈极显著正相关.(3)不同形态氮肥处理的土壤盐分离子组成相近,均以阴离子为主.设施土壤阴离子占盐分总量的76.29%～93.81%,露地土壤为75.16%～96.63%,以SO_4~(2-)含量最高,分别占67.37%和67.28%,NO_3~-含量次之;土壤中阳离子含量较少,以Ca~(2+)为主,K~+,Na~+,Ca~(2+),Mg~(2+)的含量随氮肥用量的增加而增加.(4)土壤电导率受阳离子的影响较大.阴离子的影响较小.设施土壤的电导率与Ca~(2+),Mg~(2+),K~+.NO_3~-含量呈极显著正相关,与Cl~-1呈显著正相关.露地土壤电导率与Ca~(2+),Mg~(2+)含量呈极显著正相关,与HCO_3~-呈显著负相关.     

田间管理对华北平原冬小麦产量土壤碳及温室气体排放的影响

选取华北平原冬小麦为研究对象,针对（1）秸秆移除;（2）秸秆表覆;（3）免耕;（4）秸秆深施;（5）施农家肥这5种典型的田间管理,使用农田自动温室气体测定系统对冬小麦农田全生育期进行了原位长期观测,并采用^13C自然丰度法对土壤碳的转化进行了监测,同时对冬小麦产量及生物量、土壤有机碳的变化进行了监测。结果表明,冬小麦产量及生物量高低顺序为施农家肥、秸秆深施、秸秆表覆、秸秆移除和免耕,而且土壤有机碳的更新也有同样的趋势;施农家肥能显著增加土壤有机碳而秸秆移除和免耕则会导致土壤有机碳的轻微下降;冬小麦甲烷的排放或吸收只占总增温潜势的不到1％,在进行统计总排放当量时基本可以忽略,N2O在总排放当量中的比例在2．55％-11．62％范围内;N2O的大量排放主要来自于拔节期及开花期,秸秆移除、施农家肥和秸秆深施会导致N2O排放在总当量中的份额增加至10％左右,而秸秆覆盖和免耕N2O排放在总排放当量中的份额只有3％左右,冬小麦农田总的温室气体排放88％以上来自于CO2的排放,特别是秸秆表覆和免耕95％以上来自土壤碳的损失而释放的CO2。总体来看,秸秆深施能保证较高的产量,减少碳的损失,增加土壤碳并产生相对较少的总温室气体排放量,是较好的固碳减排方式。     

设施和露天栽培下有机菜地土壤氮素矿化和硝化作用的比较研究

矿化作用和硝化作用是土壤氮素转化的主要途径,通过室内培养试验,对设施和露天栽培方式下有机菜地土壤氮素的矿化与硝化作用进行了比较研究。结果表明,除培养第1d外,设施有机菜地土壤氮素矿化量、矿化率在整个培养期间都显著高于露天有机菜地土壤;设施有机菜地土壤硝化量、硝化率在培养前两周内高于露天有机菜地土壤;设施有机菜地土壤矿化与硝化作用总体比露天有机菜地土壤强烈。矿化作用可能与全氮、C/N、微生物活性关系密切,而硝化作用强弱可能与微生物活性有关。无论施肥与否,设施有机菜地土壤N2O排放速率在培养期间总体高于露天有机菜地土壤,前者N2O累积排放量显著高于后者,这可能与土壤C/N有关。     

种植年限对设施菜田土壤剖面磷素累积特征的影响

以山东寿光集约化设施菜田为研究对象,分析了不同种植年限设施菜田土壤磷素投入和土壤磷素累积的差异,比较不同种植年限土壤剖面中无机磷、有机磷、Olsen-P和CaCl2-P含量的变化特征。结果表明：磷素过量积累是设施菜田的显著特征,主要由于有机肥以粪肥投入为主,复合肥中P素比例偏高,收获作物带走量仅占磷素投入的7.2%;随着种植年限增加,P素累积现象明显,过量的磷素盈余导致了土壤剖面中不同形态磷含量的上升,其中以无机磷尤其明显;用来表征土壤有效磷指标的Olsen-P与CaCl2-P有显著的相关性,研究区域中当土壤（Olsen-P）达到80.7mg·kg-1时,土壤CaCl2-P开始显著升高,增大了设施菜田磷素淋溶风险。     

甲基硫茵灵及其代谢物在不同种植模式黄瓜和土壤中的残留

采用液质联用仪比较分析了3个不同种植区域（江苏南京、广西南宁和湖南长沙）露地和大棚两种种植条件下黄瓜和土壤中甲基硫菌灵及其代谢物多菌灵的残留动态,同时对黄瓜中的最终残留量进行了比较分析。施药后,甲基硫菌灵在黄瓜和土壤中均能很快转化为多菌灵[施药后1 d甲基硫菌灵未检出（〈0.01 mg·kg-1）],多菌灵在露地黄瓜和土壤中的原始沉积量均低于大棚。3个试验点露地黄瓜中的半衰期分别为2.3、1.4 d和1.4 d,在大棚黄瓜中的半衰期分别为2.6、1.7 d和2.0 d。在3个试验点露地土壤中的半衰期分别为1.6、1.7 d和2.3 d,在大棚土壤中的半衰期分别为2.3、2.0 d和2.3 d。最终残留试验在最后一次施药后1 d采样时,大棚、露地黄瓜中的甲基硫菌灵均未检出（〈0.01 mg·kg-1）,多菌灵在3个试验点露地黄瓜中的最终残留量为0.014~0.162 mg·kg-1,而在3个试验点大棚黄瓜中的最终残留量为0.121~0.561 mg·kg-1。参照我国所制定的黄瓜中多菌灵的MRL（0.5 mg·kg-1）,露地种植方式下所有处理黄瓜中甲基硫菌灵代谢物多菌灵的最终残留量均符合国家标准的规定,但大棚种植方式下其残留量有超标的风险。     

Threshold of Soil Olsen-P in Greenhouses for Tomatoes and Cucumbers

Phosphorus (P) accumulation is a common phenomenon in greenhouse soil for vegetables. Excessive P accumulation in soil usually decreases the yield and quality of vegetables as well as potentially polluting water environments. Ninety-eight tomato and 48 cucumber greenhouses were investigated in the eight main vegetable production areas of Hebei Province, China. Soil Olsen-P, the electrical conductivity (EC), the pH value, the organic matter of the soil, and the cropping years of these greenhouses were investigated and analyzed in order to better understand the status of soil P accumulation and positively find effective ways to solve the excessive phosphate accumulation problem. The investigation showed that the ratio was above 70% for all of the greenhouses where the soil Olsen-P exceeded 90 mg·kg^?1 (upper bound of soil Olsen-P optimum value in greenhouse) in the 0–20 cm surface soil in the investigated greenhouses. There was a significant positive correlation between the soil Olsen-P content and the soil EC, between the soil Olsen-P and the cropping years, and the Olsen-P had a significant negative correlation with the soil pH value. It is concluded that supplying phosphate fertilizer excessively induced the soil EC to ascend and the pH value to descend, which increases the possibility of the soil secondary salinization and soil degeneration. The significant positive correlation between the soil organic content and the soil Olsen-P contents suggests that supplying organic fertilizer might mobilize soil residual phosphate. This also provides a good way to solve the problem of soil P accumulation. In order to further explore the threshold content of soil Olsen-P demanded by tomato and cucumber under the high soil Olsen-P condition, two tomato greenhouses (T1, T2) in Dingzhou and two cucumber greenhouses (C1, C2) in Wuqiang were researched. All of the greenhouses had ranges of soil Olsen-P content that were between 150 and 300 mg·kg^?1, which far exceeded the 90 mg·kg^?1 ideal. The P fertilizer application rates showed positive correlations with the soil Olsen-P contents and EC values in cucumber and tomato greenhouses in the current season. Analyzing T1 and T2 results showed that tomato was sensitive to the high soil Olsen-P contents ranging from 230.64 to 729.42 mg kg^?1 at the seedling stage (15 days after transplanting; DAT) and from 199.41 to 531.42 mg kg^?1 at the fruiting stage (90 DAT), because the yields correlated negatively with soil Olsen-P contents at each growth stage. It is suggested that the maximum soil Olsen-P threshold content for tomato should be lower than 230 mg·kg^?1 at the seedling stage and lower than 199 mg·kg^?1 at the fruiting stage. But cucumber yield did not change significantly as soil Olsen-P content rose from 248.75 to 927.62 mg kg^?1, 212.40 to 554.07 mg kg^?1, 184.48 to 455.90 mg kg^?1, and 128.42 to 400.96 mg kg^?1 at the seedling stage (15 DAT), early fruiting stage (50 DAT), middle fruiting stage (140 DAT), and late fruiting stage (235 DAT), respectively, suggesting that the maximal soil Olsen-P threshold content was lower than 249, 212, 185, and 128 mg·kg^?1 at each growth stage, respectively. The relationship between fruit qualities and soil Olsen-P contents at each growth stage was not evident. Activities of soil alkaline phosphatase (ALP) decreased as soil Olsen-P supply was raised in T1, T2, and C1 at the seedling stage. It is concluded that in an excess soil Olsen-P condition tomato yield decreases strongly as soil ALP activity decreases, whereas ALP activity has little direct effect on cucumber yield.     

相变蓄热砌块墙体在日光温室中的应用效果

日光温室墙体的保温蓄热性能直接影响温室内气温和作物的生长。该文选用石蜡与硬脂酸正丁酯按质量比为5∶5制成复合相变材料,以稻壳为载体采用自然吸附法进行吸附得到相变骨料。相变骨料与建筑材料混合制成相变蓄热砌块,并以其为墙体建造相变蓄热温室。采用差示扫描量热法测试复合相变材料和稻壳骨料DSC（热流-温度）曲线,相变温区为15～45℃;复合相变材料的熔解潜热为116.2 kJ/kg,凝固潜热为118.5 kJ/kg,相变稻壳的凝固潜热值为70.63 kJ/kg,熔解潜热值为58.14 kJ/kg。用多点温度计测量相变温室和普通温室室内外气温和墙体内外表面温度,相变温室室内气温波动幅度比对照温室小4.1℃,最低气温比对照高1.7℃,而最高气温则比对照低2.4℃。通过在温室内栽培金鹏一号番茄试验,表明相变温室中番茄的生长状况明显优于普通温室。因此,该文采用的相变蓄热砌块墙体建成的日光温室比普通温室具有更好的蓄热保温性能,更有利于冬季作物生长。     

常规灌溉条件下施氮对温室土壤氨挥发的影响

为明确温室土壤的氨挥发特征,探讨适宜的减量施氮措施对氨挥发损失量及黄瓜产量的影响,在常规灌溉条件下设置了3个施氮（尿素）处理,采用通气法测定了冬春季黄瓜地中的氨挥发速率。结果表明：温室土壤在氮肥基施后7 d出现氨挥发速率峰值,但在氮肥追施后,施肥带与非施肥带的氨挥发速率峰值分别在第1 d与第5 d出现,氨挥发速率的峰值比氮肥基施时下降了8.6%～46.3%,施肥带的累积氨挥发量是非施肥带的0.91～1.54倍。冬春季黄瓜地的氨挥发损失量为16.7～26.6 kg/hm2,其中减施氮25%处理N900（900 kg/hm2）与减施氮50%处理N600（600 kg/hm2）与习惯施氮处理N1200（1 200 kg/hm2）相比,氨挥发损失量分别降低了22.1%和37.2%。而2 a黄瓜产量的平均值以处理N600（600 kg/hm2）最高,比处理N1200（1 200 kg/hm2）增加了6.52%。综合考虑氨挥发损失量、黄瓜产量及施氮量,在河北省的温室冬春季黄瓜生产中,比农民习惯氮用量（1 200 kg/hm2）减少25%～50%的措施是可行的。