土壤有机碳对沼渣或牛粪施用后温室气体排放潜力的影响—盆栽试验结果

A change in the European Union energy policy has markedly promoted the expansion of biogas production.Consequently,large amounts of nutrient-rich residues are being used as organic fertilizers.In this study,a pot experiment was conducted to simulate the high-risk situation of enhanced greenhouse gas (GHG) emissions following organic fertilizer application in energy maize cultivation.We hypothesized that cattle slurry application enhanced CO2 and N2O fluxes compared to biogas digestate because of the overall higher carbon (C) and nitrogen (N) input,and that higher levels of CO2 and N2O emissions could be expected by increasing soil organic C (SOC) and N contents.Biogas digestate and cattle slurry,at a rate of 150 kg NH4+-N ha-1,were incorporated into 3 soil types with low,medium,and high SOC contents (Cambisol,Mollic Gleysol,and Sapric Histosol,termed Clow,Cmedium,and Chigh,respectively).The GHG exchange (CO2,CH4,and N2O) was measured on 5 replicates over a period of 22 d using the closed chamber technique.The application of cattle slurry resulted in significantly higher CO2 and N2O fluxes compared to the application of biogas digestate.No differences were observed in CH4 exchange,which was close to zero for all treatments.Significantly higher CO2 emissions were observed in Chigh compared to the other two soil types,whereas the highest N2O emissions were observed in Cmedium.Thus,the results demonstrate the importance of soil type-adapted fertilization with respect to changing soil physical and environmental conditions.     

不同氮素水平下有机物料添加对陇中黄土高原旱作农田N2O排放特征的影响

为了探究不同用量氮肥配施生物质炭或小麦秸秆对旱作农田N₂O排放通量的影响,在陇中黄土高原半干旱区连续进行4年不同氮素水平配施不同有机物料的田间定位试验,试验以3种施氮用量（不施氮肥、50 kg（N）·hm^-2氮肥、100 kg（N）·hm^-2氮肥）配施2种有机物料（小麦秸秆S、生物质炭B）及无有机物料 (C)共组成9个处理,于2016年11月—2017年10月,采用静态箱-气相色谱法,对N₂O通量进行全年内连续观测。研究结果表明：观测期内,各处理N₂O年平均通量大小排序SN100>CN100>SN50>CN50>BN100>SNO>BN50>CN0>BN0,各处理N₂O排放通量变化趋势一致;相较N0处理（CN0、SN0、BN0）的年平均排放通量,N50（CN50、SN50、BN50）和N100（CN100、SN100、BN100）处理分别增加了6.92%和10.03%。相较CN0、CN50和CN100,与其相同氮素水平配施生物质炭后,N₂O年平均排放通量分别降低了0.49%、3.15%和4.67%;配施秸秆后,N₂O年平均排放通量分别增加了6.37%、3.44%和2.73%。单施氮肥或小麦秸秆配施氮肥均增加了N₂O排放的增温潜势,生物质炭配施氮肥减少了N₂O排放的增温潜势。主效应分析表明,氮素、秸秆均对提升N₂O排放通量发挥显著效应,而生物质炭具有降低效应。相关分析表明,土壤温度与N₂O通量表现为显著正相关关系,土壤含水量与N₂O通量表现为显著负相关关系（P<5%）。通径分析表明,土壤温度对N₂O通量的增大作用远大于土壤含水量对N₂O通量的减小作用。秸秆或生物质炭与氮素无交互效应,N₂O排放通量随氮素水平的增加而增大,秸秆还田促进了N₂O排放而生物质炭抑制了N₂O排放。因此,添加生物质炭对旱作农田固氮减排具有较大的潜力。     

浅埋滴灌水氮运筹对春玉米产量及水分利用效率的影响

采用二因素二次饱和D-最优设计,于2016-2017年在辽西半干旱区移动遮雨棚内进行了水氮精量控制试验,设灌溉量和施氮量2个因素,灌溉量分别设145.4、271.7、348.2、436.2 mm 4个水平,施氮量分别设0、84.6、136.1、195.0 kg·hm^-2 4个水平,共6个处理。试验分析了水氮交互作用对春玉米产量和水分利用效率的影响,建立了产量回归模型。研究结果表明：浅埋滴灌条件下,灌溉量在145.4~350.5 mm时,春玉米产量随灌溉量的增加而增高至11 005.60 kg·hm^-2;灌溉量在350.5~436.2 mm时,产量随灌溉量的增加而降低至10 730.09 kg·hm^-2;施氮量在0~146.9 kg·hm^-2时,产量随施氮量的增加而增高至10 983.19 kg·hm^-2,施氮量在146.9~195.0 kg·hm^-2时,产量随施氮量的增加而降低至10 862.39 kg·hm^-2。灌溉量因素的影响大于施氮量,水氮之间有明显的正向交互效应,当灌溉量为373.1 mm,施氮量为165.6 kg·hm^-2时产量最高。作物耗水量在拔节-抽雄期和灌浆-收获期较大,分别为115.64、127.50 mm;水分利用效率随灌溉量的增加呈逐渐降低趋势,降低幅度达到52.21%,随着施氮量的增加则呈先升高后降低趋势,增幅为14.73%~20.08%;其中处理6（灌溉量348.2 mm,施氮量195.0 kg·hm^-2)最利于水分利用效率的提高。综合产量和水分利用效率两方面的因素,初步建立了春玉米浅埋滴灌水氮施用优化模式,参数组合为灌溉量348.2 mm、施氮量165.6 kg·hm^-2。     

施氮量对棉田主要害虫种群动态的影响

通过不同施氮肥量对棉田主要害虫种群动态影响的研究结果表明,在低、中、高3种施氮肥水平处理条件下,随着氮肥量的增加,棉田棉铃虫落卵量增加,棉苗蚜、棉叶螨种群数量减少,发生为害减轻,但棉伏蚜种群数量增加。中等施氮肥条件下,第二、三代棉铃虫幼虫数量高于低和高施氮肥处理,对棉铃虫幼虫的生长发育和存活较为有利。     

局部涂抹纳米碳与尿素溶液对桃树梢叶生长及氮素吸收、分配的影响

以7年生的鲁星油桃为试材,采用15 N同位素示踪技术进行田间涂抹试验,研究不同浓度纳米碳与相同浓度尿素溶液(0μg/mL+0.2%,50μg/mL+0.2%,100μg/mL+0.2%,200μg/mL+0.2%,分别以CK、NC50、NC100、NC200表示)涂抹部分叶片对桃树局部梢叶生长、氮素吸收及分配的影响,以期为桃树栽培过程中施用碳纳米提供新的思路和有益的参考。结果表明:与对照相比,施用纳米碳后桃树涂抹叶片单叶面积明显增加,叶绿素含量显著提高,NC200处理下叶片的净光合速率、蒸腾速率和气孔导度比对照提高了15.8%,30.0%,12.4%;纳米碳的施用提高了桃树新梢的干物质积累量,NC100、NC200处理比对照增加了10.5%和12.9%,提高了新梢各部位的全氮含量;高浓度的纳米碳(NC200处理)提高了新生器官对氮素的吸收征调能力(Ndff值);随纳米碳浓度的增大氮素的利用效率显著提高,NC50、NC100、NC200处理的氮素利用率比对照提高了13.6%,29.5%,40.0%;此外,新生嫩叶部分以NC200处理的氮素分配率最高,达19.55%,NC50、NC100、NC200处理氮素分配率比对照提高了4.5%,16.2%,17.1%,差异显著。以上结果表明,纳米碳能够促进新梢叶片对氮素的吸收利用,有效提高叶绿素含量、光合作用效率及新梢局部氮素利用率,影响氮素在梢叶各部位间的分配,促进氮素向生长中心(新生嫩叶)的转移。     

microRNA-124-3p调控H1N1亚型猪流感病毒致小鼠肺损伤的研究

为研究microRNA-124-3p（miR-124-3p）对H1N1亚型猪流感病毒（swine influenza virus,SIV）感染小鼠所致肺损伤的调控作用,本试验构建miR-124-3p腺病毒表达载体,通过小鼠尾部静脉注射法构建miR-124-3p差异表达小鼠模型,试验分3组：过表达组、抑制组和对照组。48 h后,各组小鼠鼻腔接种H1N1亚型SIV,每只10⁵ EID₅₀（50 μL）。连续观察14 d,计算小鼠平均体重变化率、观察病理切片并测定相关炎症因子IL-1β、TNF-α和IL-6 mRNA相对表达量。结果显示,已成功将pre-miR序列及其sponge序列插入腺病毒的穿梭质粒,并将其共转染293A细胞。实时荧光定量PCR检测证实,与对照组相比,过表达组和抑制组小鼠黑色素瘤细胞miR-124-3p表达水平分别极显著升高（P<0.01）和显著降低（P<0.05）,表明成功构建腺病毒表达载体。过表达组、抑制组和对照组小鼠体重变化率分别为－5.5%、－12.4%和－8.6%。抑制组和对照组均可见肺泡壁增厚,其间有多量淋巴细胞浸润,部分肺泡内出现纤维蛋白渗出,且抑制组病理变化更为严重,肺泡中还有大量的红细胞浸润;而过表达组仅有少量的淋巴细胞浸润,肺脏组织较正常。与对照组相比,过表达组检测的炎症因子IL-1β、TNF-α和IL-6 mRNA表达水平均显著降低（P<0.05）;抑制组炎症相关炎症因子mRNA表达水平均显著升高（P<0.05）。本试验结果表明,miR-124-3p对H1N1亚型SIV感染小鼠所致的肺脏炎症因子的表达具有抑制作用,同时能减轻肺脏病理损伤。     

Biochar addition mitigates nitrogen loss induced by straw incorporation and nitrogen fertilizer application

Biochar has been shown to be potentially beneficial for enhancing yields and soil properties, and diminishing nitrogen (N) losses. However, it remains unclear how biochar regulates soil carbon (C) and N to mitigate N losses induced by straw mixing with N fertilizer in dryland soils. Therefore, we investigated the effects of straw mixing (S₁), S₁ with biochar (SB) and no straw inputs (S₀), and routine urea application rates (N₁) and 70% of routine rates (N_0.7) on yields and N losses, and identify the relationship between N losses and soil C and N compounds. Results showed that N_0.7 and N₁ were suitable for the maize and wheat seasons, respectively, contributing to mitigating N losses without reducing crop yields. Moreover, in the maize season, N_0.7-SB significantly mitigated the straw-induced NH₃-N and N₂O-N emissions by 106% and 81%, respectively. In the wheat season, N₁-SB reduced the straw-induced NH₃-N and N₂O-N emissions by 35% and 66%, respectively. In addition, N_0.7-SB sharply reduced soil inorganic N (SIN) storage in the maize season. Furthermore, the NH₃-N and N₂O-N emission rates were negatively correlated with dissolved organic carbon/SIN content (0–20 cm) (DOC/SIN_0-20). N losses (N₂O-N and NH₃-N emissions and SIN storage) were positively correlated with SIN_0-20, but negatively correlated with soil organic carbon / SIN_0-20 (SOC/ SIN_0-20). This study provides further evidence that biochar with an appropriate N application rate decreased SIN_0-20 and increased DOC/SIN_0-20, thus reducing SIN storage and the straw-induced gaseous N emissions without decreasing crop yields.     

Leaf carbohydrates assimilation and metabolism affect seed yield of rapeseed with different waterlogging tolerance under the interactive effects of nitrogen and waterlogging

Waterlogging is a main factor causing rapeseed (Brassica napus L.) yield loss, and reasonable nitrogen (N) applications can compensate for this loss. To investigate the effects of N rates on seed yield of waterlogged rapeseed, the waterlogging-tolerant rapeseed variety ZS 9 and sensitive variety GH01 were waterlogged for 0 and 10 days with five leaves at the seedling stage under four N rates (0, 90, 180 and 270 kg/ha). Waterlogging significantly decreased seed yield, while N application can alleviate the yield loss. The yield decrease rate of waterlogged GH01 was greater than that of ZS 9 under the same N rate. During the seedling and bolting stage, the leaf photosynthetic rate (Pn) and ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) activity increased, while activities of adenosine diphosphate glucose pyrophosphorylase (AGPase), sucrose synthase (SuSy) and sucrose phosphate synthase (SPS) decreased with more N under the same watering conditions. Compared to the plants without waterlogging, the leaf Pn and Rubisco activity, starch and sucrose contents of waterlogged rapeseed decreased at the two stages; activities of AGPase, SuSy and SPS of waterlogged rapeseed decreased at the seedling while increased at the bolting stage for both the two varieties. At the flowering stage, the Pn, the activities of Rubisco, AGPase, SuSy, SPS and contents of sucrose, starch increased with more N application for both ZS 9 and GH01. Compared to the plants without waterlogging, the Pn and Rubisco activity for waterlogged plants of the two varieties increased; the waterlogged plants of tolerant variety had higher activities of AGPase, SuSy and SPS, while those of sensitive variety was significantly lower. However, the decreased starch and sucrose content were found in both tolerant and sensitive varieties. The activities of AGPase, SuSy and SPS at flowering were highly positively correlated with yield under the interactive effects of N and waterlogging. These results suggested that the flowering stage is the most important stage that N had the positive regulation on waterlogged rapeseed growth. The carbohydrates translocation from leaves to seeds of the tolerant variety were enhanced after waterlogging, while that of the sensitive variety was still inhibited. This was the main reason for the difference in yield between the two waterlogged varieties.     

应用~(15)N示踪探究楸树无性系对氮素的吸收和分配

为探讨楸树无性系对氮素的吸收、分配及利用特性,以2年生楸树无性系015-1、1-3、7080、1-4和004-1组培苗为试验材料,应用15N示踪技术对楸树无性系进行施肥试验。结果表明,5个楸树无性系氮肥的吸收率、利用率及分配率具有较强的一致性,氮肥利用率介于27.14%~31.24%之间。楸树无性系根和叶的肥料氮比例(Ndff)明显大于茎,楸树无性系根和叶对氮肥的竞争力较强,茎对氮肥的竞争力最弱。015-1茎部氮素分配率及无性系7080根部氮素分配率明显高于其他4个无性系;氮素分配率在各个器官中差异显著,叶片氮素的分配率最高,总体趋势为叶根茎。本研究结果为楸树氮肥的合理施用提供了理论依据。     

Residual nitrogen effect of clover-ryegrass swards on yield and N uptake of a subsequent winter wheat crop as studied by use of N methodology and mathematical modelling

The residual effect of 2-year-old swards of clover-ryegrass mixture and ryegrass in monoculture on yield and N uptake in a subsequent winter wheat crop was investigated by use of the ¹⁵N dilution method and by mathematical modelling. The amount of N in the wheat crop, derived from clover-ryegrass residues was 25–43% greater than that derived from residues of ryegrass which had been growing in monoculture. Expressed in absolute values, the N uptake in the subsequent winter wheat crop was 23–28 kg N ha ⁻¹ greater after clover-ryegrass mixture than after ryegrass in monoculture. Up to about 54 kg N ha⁻¹ of the N mineralised from the clover-ryegrass crop was calculated to be leached, whereas only 11 kg N ha⁻¹ was leached following ryegrass in monoculture.