Effect of soil water status and mulching on N<Subscript>2</Subscript>O and CH<Subscript>4</Subscript> emission from lowland rice field in China

Cultivation of rice in unsaturated soils covered with mulch is receiving more attention in China because of increasingly serious water shortage; however, greenhouse gas emission from this cultivation system is still poorly understood. A field experiment was conducted in 2001 to compare nitrous oxide (N₂O) and methane (CH₄) emission from rice cultivated in unsaturated soil covered with plastic or straw mulch and the traditional waterlogged production system. Trace gas fluxes from the soil were measured weekly throughout the entire growth period using a closed chamber method. Nitrous oxide emissions from unsaturated rice fields were large and varied considerably during the rice season. They were significantly affected by N fertilizer application rate. In contrast, N₂O emission from the waterlogged system was very low with a maximum of 0.28 mg N₂O m^–2 h^–1. However, CH₄ emission from the waterlogged system was significantly higher than from the unsaturated system, with a maximum emission rate of 5.01 mg CH₄ m^–2 h^–1. Our results suggested that unsaturated rice cultivation with straw mulch reduce greenhouse gas emissions.     

垄沟集雨对紫花苜蓿草地土壤水分、容重和孔隙度的影响

在旱作条件下, 将垄沟集雨措施应用于紫花苜蓿种植, 研究沟垄宽比和覆膜方式对2年龄紫花苜蓿草地土壤水分状况、土壤容重及孔隙度的影响。结果表明: 全越冬期, 膜垄和土垄处理0~120 cm土壤水分平均散失量分别低于CK(平作)28.43 mm和13.61 mm。膜垄处理整个集雨期的蓄墒增加率为59.03%~99.27%, 产流效率为53.43%~91.72%; 2009年集雨前期(4月上旬~6月上旬)土垄处理的蓄墒增加率、产流效率分别为1.92%~2.74%和1.71%~2.55%, 2009年集雨中后期(6月中旬~9月下旬)土垄处理的蓄墒增加率、产流效率较集雨前期显著升高, 分别为8.85%~36.77%和8.01%~35.82%; 膜垄和土垄处理的蓄墒增加率、产流效率均随垄面宽度增加而显著增加, 且膜垄的蓄墒增加率、产流效率显著高于土垄处理。垄沟集雨种植能够显著降低0~40 cm土壤层容重, 且0~20 cm土壤层容重降幅表现为膜垄大于土垄。垄沟集雨种植也能够显著增加0~40 cm土壤层孔隙度, 且0~20 cm土壤层孔隙度增幅表现为膜垄大于土垄。     

土壤消毒措施对土壤物理特性及黄瓜生长发育的影响

采用田间试验方法,研究了垄沟式太阳能消毒、石灰氮麦秸、垄鑫3种土壤消毒方法对日光温室土壤物理特性及黄瓜生长发育的影响。结果表明,垄沟式太阳能消毒处理对土壤物理特性未产生较大影响,处理后粗粉粒含量较对照降低9.5%,砂粒两个粒径(0.1～0.5mm、0.5～1.0mm)含量较对照分别增加39.4%、117.7%,其余组分无明显变化;石灰氮麦秸处理后黏粒含量增加163%,细粉粒两粒径(0.001～0.005mm、0.005～0.01mm)含量较对照分别增加52.1%和116.8%;施用垄鑫处理后土壤黏粒含量较对照降低65.8%,细粉粒两个粒径含量较对照分别降低33.0%、32.2%。不同处理对土壤微团聚体的形成均有一定阻碍作用,其中石灰氮麦秸处理对土壤团聚体的形成影响最大,其次是垄鑫处理,垄沟式太阳能消毒处理影响最小。3个土壤消毒处理都能提高黄瓜平均叶片数、平均株高、叶绿素含量和黄瓜产量,其中垄沟式太阳能消毒处理能显著提高黄瓜生物学指标,有良好的增产效果。     

Effects of ridge‐furrow and plastic mulching planting patterns on microflora and potato tuber yield in continuous cropping soil

Planting patterns have distinctive effects on the soil micro‐ecological environment and soil quality. To explore the effects of film mulch ridge‐furrow (FMRF) cropping on soil microbial properties and potato yield, a study was conducted in 2013 and 2014 in a continuously cropped field under nonfilm‐mulched flat plot (CK), half‐mulched flat plot (T1), fully mulched ridge cropping (T2), fully mulched furrow cropping (T3), half‐mulched ridge cropping (T4) and half‐mulched furrow cropping (T5) planting patterns. Our results indicate that T3 increased the average bacteria/fungi (B/F) ratio by 253% compared to CK. On average, half‐mulched ridge cropping increased the bacteria population and aerobic Azotobacter by 9 and 19%, respectively, compared with CK. On average, T3 had the greatest inhibitory effect on fungi populations. Half‐mulched furrow cropping had the most anaerobic Azotobacter and nitrifying bacteria. The study showed that FMRF increased soil bacteria, especially Azotobacter but reduced fungi and actinomycetes. Treatment T2 gave the greatest potato yield, followed by T4, whereas the greatest biomass yield was recorded in T4. Full‐mulch furrow cropping methods produced the greatest nutrient use efficiency. The findings of this study enhance our understanding of soil microbe and plant responses to plastic mulch and planting patterns under semi‐arid conditions.     

Soil respiration, N2O, and CH4 emissions from an Andisol under conventional-tillage and no-tillage cultivation for 4 years

No-tillage (NT) management is a promising method to sequester soil C and mitigate global warming caused by agricultural activities. Here, we report 4 years of continuous soil respiration rates and weekly nitrous oxide (N₂O) and methane (CH₄) emissions in NT and conventional-tillage (CT) plots in a typical Japanese volcanic soil. Overall, the soil respiration, N₂O emission, and CH₄ uptake decreased significantly in the NT plot. A difference in soil respiration and N₂O emission between the two plots began after the tillage treatment and the incorporation of crop residues and fertilizers, whereas the CH₄ uptake did not vary significantly during the fallow period after the treatments. The N₂O emission was higher from the CT than from the NT plot during the fall. The overall lower CH₄ uptake in the NT than in the CT plot likely resulted from a combination of decreased soil gas diffusivity and higher mineral N content at the soil surface. Higher soil respiration and N₂O emission occurred in the NT plot in the summer of 2003 and were plausibly caused by an increase in the soil moisture content that resulted from lower temperatures during July and August; the higher soil moisture must have accelerated the decomposition of organic matter accumulated in the topsoil. These results indicate that NT management is generally effective for the mitigation of the total GWP by reducing soil respiration and N₂O emission in temperate regions; however, NT management may increase rather than decrease these emissions when fields experience cool summers with frequent rainfall.     

旱地雨养农业覆膜体系及其土壤生态环境效应

覆膜技术作为一项有效提高粮食产量的重要手段,在中国西北地区雨养农业中得到广泛的推广应用。本文综述了地膜覆盖体系关于作物产量、土壤水分、土壤温度、土壤养分转化和迁移以及微生物数量和活性等方面的研究进展,以期为旱地雨养农业发展和完善覆膜技术体系提供理论支撑。研究表明:玉米、小麦和马铃薯覆膜处理增产显著,其平均增产率分别为26.2%、37.1%和29.8%;同时,增产受到覆膜方式影响,全覆膜处理增产效果最好,其玉米、小麦和马铃薯平均产量分别比半覆膜处理高30.0%、5.1%和26.4%。覆膜下玉米、小麦与马铃薯的水分利用效率分别比不覆膜处理高42.8%、10.9%和92.8%。覆膜处理影响硝酸盐在土体的空间分布,硝酸盐在膜下出现表聚现象;同时覆膜能够提高氮肥利用效率,减少氮素淋溶损失,降低氨挥发。但关于覆膜下反硝化过程的研究结论不一,还需进一步深入的探讨。覆膜对有机碳的影响与气候、土壤、作物、覆膜年限等有关,其研究结论尚有争议。另外,覆膜增加了农田土壤微生物量,改变土壤物理性状。尽管覆膜显著提高作物产量,其对生态环境却可能存在一定的影响,比如"奢侈耗水"现象,温室气体排放增加,土壤有机质耗竭,农膜残留等问题。因此,进一步系统研究覆膜对土壤生态环境的影响机理,完善覆膜技术体系与应用,全面评估覆膜体系的生态环境影响,对其在中国干旱地区农业生产的可持续发展具有重要意义。     

Plastic mulching increased soil CO2 concentration and emissions from an oasis cotton field in Central Asia

Although previous researchers suggest that carbon dioxide (CO₂) emissions are influenced by plastic mulching, the effects of this method on soil CO₂ concentration and emissions remain uncertain. Soil CO₂ concentration and emissions from ridge and furrow soils under mulched and nonmulched treatments in 2014 and 2015 were measured. The soil CO₂ concentration was observed using modified diffusion equilibrium samplers, and the soil CO₂ emissions were measured using a closed‐chamber method. In the ridge soil, although the plastic mulching increased the CO₂ concentration by 49% (0–40 cm), no significant difference in CO₂ emissions was found between the mulched and nonmulched treatments. Accordingly, the relationship between soil CO₂ concentration and CO₂ emissions was affected by plastic mulching, with a lower slope of the linear equation found in the mulched treatment compared to the nonmulched treatment. In the furrow soil, the plastic mulching increased the CO₂ concentration and emissions by 15% and 21%, respectively. In conclusion, plastic mulching significantly increased the CO₂ concentration in both the ridge and furrow soils and increased the cumulative CO₂ emissions by 8%. The temperature sensitivity of the soil CO₂ concentration increased with soil depth, whereas the plastic mulching only influenced the temperature sensitivity of the soil CO₂ concentration in both the ridge and furrow soils at a depth of 40 cm. Our results suggest that the temperature sensitivity of the soil CO₂ concentration not only reflects the effects of temperature on CO₂ production but also indicates poor diffusion in the deep profile.     

新疆地区全生物降解膜降解特征及其对棉花产量的影响

针对残膜污染已经成为新疆棉田最严重的生态环境问题,以广东上九公司提供的3种淀粉基全生物降解地膜为供试材料,在我国西北内陆棉区（新疆石河子）开展了田间试验评价研究。结果表明,由于配方的不同,3种降解膜的降解特性、增温保墒性能以及对棉花产量的影响存在显著的差异性。从地表覆盖试验与填埋试验的结果看,与日本的生物降解地膜（CK2）相比,国内的3种供试地膜品种都表现为降解过快,特别是A膜和B膜,降解最为迅速,C膜降解相对较慢。过快的降解速率显著地影响了3种供试降解膜的增温保墒性能,特别是A膜和B膜,与普通膜（CK1）相比,土壤温度平均低2～3℃,土壤水分低3～5个百分点,3种供试降解膜比较,C膜的增温保墒效果略好。从产量结果来看,与普通膜相比,国内供试的A膜和B膜对产量影响较大,减产幅度分别为20%以上,供试C膜和对照的日本降解膜都表现为增产趋势,但与普通膜产量结果比较差异并不显著。     

等高绿篱--坡地农业复合系统土壤N2O排放特征

N2O是一种重要的温室气体, 具有很强的温室效应。当前全球变化条件下, 人类活动和农业生产行为产生的N₂O排放增加是当前倍受关注的问题。本研究于2008年11月-2009年10月, 利用静态箱 气相色谱技术对亚热带地区紫穗槐(Amorpha fruticosa L.)绿篱枝叶还田条件下冬小麦 夏玉米轮作田土壤N₂O排放通量进行原位监测, 观测紫穗槐枝叶移出(AR)、翻施(AI)、表施(AC)及作物单作(CK)4种处理下整个生长季土壤N₂O的排放量, 对等高绿篱 坡地农业复合生态系统土壤N₂O排放通量变化及其影响机制进行研究。结果表明, 整个冬小麦 夏玉米轮作期, 4个处理土壤N₂O排放通量呈现出相似的季节变化特征, AR、AI、AC、CK处理全生长季的排放总量为127.62 mg·m^-2、209.66 mg·m^-2、208.73 mg·m^-2、77.52 mg·m^-2。作物不同生育阶段N₂O日均排放通量在冬小麦季表现为: 开花-成熟期>拔节-开花期>出苗-拔节期; 在夏玉米季表现为: 拔节-抽雄期>播种-拔节期>抽雄-成熟期。本试验综合评估了等高绿篱 坡地农业复合生态系统土壤N2O排放通量变化及其影响机制。研究显示, 土壤N₂O排放通量在冬小麦季与土壤温度相关性显著, 在夏玉米季与土壤水分相关性显著。在复合生态系统中紫穗槐复合种植及枝叶还田显著促进土壤N2O排放, 翻施处理产生的N2O量大于表施处理。     

中国农业温室气体排放量测算及影响因素研究

农业生产过程所产生的温室气体在全球生产活动温室气体排放总量中占有很大比例,因此对农业温室气体的排放量进行测算并分析其影响因素,对实现农业节能减排有重要意义。本文基于1993―2011年中国农业生产的相关统计数据,借鉴前人关于农业生产中各种温室气体排放源排放系数的研究成果,测算了中国农业生产过程中的CH4、N2O和CO2排放量,并分析了影响因素。结果表明,CH4排放量基本平稳波动不大,N2O排放量从1993年的93.21万t波动增加到2011年的120.51万t,农业生产资料CO2排放量由15 626.98万t增加到31 258.10万t。种植业CO2排放主要分为土壤排放和生产资料排放,土壤CO2排放与大气温度、土壤温度、地表温度和土壤水分有关,生产资料CO2排放主要是由化肥和农药造成的;种植业CH4、N2O排放原因较为复杂,还有待进一步研究;动物肠道发酵CH4、N2O排放的影响因素主要取决于动物种类、饲料特性、饲养方式和粪便管理方式等。     

垄沟耕作条件下液膜覆盖对土壤水热状况及玉米生长的影响

[目的]研究垄沟耕作和液膜覆盖集成技术在旱地作物中的应用效果,为旱田高产高效种植方式的选用提供理论支撑。[方法]应用田间小区试验的方式,进行不同耕作方式下的液态地膜、塑料地膜覆盖及不覆膜种植玉米对比试验。[结果]和不覆膜种植相比,垄沟耕作条件下,覆盖种植显著增加了0—40cm土层含水量,提高了5cm,10cm深土壤温度;覆盖种植较好地促进了玉米前期生长,显著增加了玉米产量,提高了水分利用效率(WUE)(p0.05)。随着覆膜时间的延长,液膜、塑膜覆盖的集水保温效果逐渐减弱。液膜覆盖种植的蓄水保温及增产效果低于塑膜覆盖,但显著优于不覆膜种植。试验前期,降水较少,垄沟耕作的集雨效果不明显,但有明显的增温效应。[结论]与塑膜覆盖种植可能会造成"白色污染"问题相比较,垄沟耕作条件下液膜覆盖是一种较为理想的旱作覆盖栽培技术。     

肥料添加剂降低N2O排放的效果与机理

如何降低氮肥施入农田后的N2O排放,实现氮肥增产效应的同时降低其对环境的负面影响是全球集约化农业生产中重要的科学问题,氮肥添加剂是有效途径之一。本研究采用室内静态培养法,在调节土壤水分含量和温度等环境因素的条件下,研究不同肥料添加剂对华北平原典型农田土壤N2O排放的影响及其机制。结果表明,N2O排放通量的峰值大约出现在施氮后的第24 d,肥料混施较肥料表施的出峰时间提前。与单施尿素处理相比,添加硝化抑制剂DMPP或DCD能分别降低N2O排放总量99.2%和97.1%; 添加硫酸铜对N2O排放的抑制作用不显著; 添加秸秆会增加N2O排放总量60.7%,而在添加秸秆的土壤中施加硝化抑制剂DMPP能够显著降低N2O排放量至无肥对照水平。说明华北平原农田土壤中N2O的产生主要是由硝化作用驱动,同时也可看出,添加硝化抑制剂是N2O减排的有效措施。     

Nitrous oxide emission derived from soil organic matter decomposition from tropical agricultural peat soil in central Kalimantan,Indonesia

Our previous research showed large amounts of nitrous oxide (N₂O) emission (>200?kg?N?ha^?1?year^?1) from agricultural peat soil. In this study, we investigated the factors influencing relatively large N₂O fluxes and the source of nitrogen (N) substrate for N₂O in a tropical peatland in central Kalimantan, Indonesia. Using a static chamber method, N₂O and carbon dioxide (CO₂) fluxes were measured in three conventionally cultivated croplands (conventional), an unplanted and unfertilized bare treatment (bare) in each cropland, and unfertilized grassland over a three-year period. Based on the difference in N₂O emission from two treatments, contribution of the N source for N₂O was calculated. Nitrous oxide concentrations at five depths (5–80?cm) were also measured for calculating net N₂O production in soil. Annual N fertilizer application rates in the croplands ranged from 472 to 1607?kg?N?ha^?1?year^?1. There were no significant differences in between N₂O fluxes in the two treatments at each site. Annual N₂O emission in conventional and bare treatments varied from 10.9 to 698 and 6.55 to 858?kg?N?ha^?1?year^?1, respectively. However, there was also no significant difference between annual N₂O emissions in the two treatments at each site. This suggests most of the emitted N₂O was derived from the decomposition of peat. There were significant positive correlations between N₂O and CO₂ fluxes in bare treatment in two croplands where N₂O flux was higher than at another cropland. Nitrous oxide concentration distribution in soil measured in the conventional treatment showed that N₂O was mainly produced in the surface soil down to 15?cm in the soil. The logarithmic value of the ratio of N₂O flux and nitrate concentration was positively correlated with water filled pore space (WEPS). These results suggest that large N₂O emission in agricultural tropical peatland was caused by denitrification with high decomposition of peat. In addition, N₂O was mainly produced by denitrification at high range of WFPS in surface soil.     

Nitrous Oxide Production and Consumption Potential in an Agricultural and a Forest Soil

Both a laboratory incubation experiment using soils from an agricultural field and a forest and field measurements at the same locations were conducted to determine nitrous oxide (N₂O) production and consumption (reduction) potentials using the acetylene (C₂H₂) inhibition technique. Results from the laboratory experiment show that the agricultural soil had a stronger N₂O reduction potential than the forest soil, as indicated by the N₂O/N₂ ratio in denitrification products. Without C₂H₂ inhibition, N₂O could reach a maximum concentration of 51 and 296 ppmv in headspace of the agricultural and forest soil slurries, respectively. Addition of glucose decreased the maximum N₂O concentration to 22 ppmv in headspace of the agricultural soil slurries, but increased to 520 ppmv in the forest soil slurries. Addition of exogenous N₂O did not change such N₂O accumulation maxima during the incubations. The field measurements show that average N₂O emission rates were 0.56 and 0.59 kg N ha^?1 in the agricultural field and forest, respectively. When C₂H₂ was provided in the field measurements, N₂O emission rates from the agricultural field and forest increased by 38 and 51%, respectively. Nitrous oxide consumption under elevated N₂O condition (about 300 ppmv) was found in all five agricultural field measurements, but only in three of the six forest measurements under the same conditions. Field measurements agreed with the laboratory experiment that N₂O reduction activity, which plays a critical role in abating N₂O emissions from soils, largely depended on soil characteristics associated with land use.     

Inoculation with N2-generating denitrifier strains mitigates N2O emission from agricultural soil fertilized with poultry manure

Pelleted poultry manure is recommended for use with agricultural soil as a replacement for chemical fertilizers; however, application of the manure stimulates nitrous oxide (N₂O) emission from the soil through denitrification. To mitigate the N₂O emission caused by application of pelleted poultry manure, soil microcosms were set up; each microcosm was inoculated with one of the following N₂-generating denitrifier strains previously been isolated from paddy soil: Azoarcus, Dyella, Dechloromonas, Niastella, and Burkholderia. When pelleted poultry manure was incubated on its own, N₂O was produced by denitrification. In contrast, N₂O emission was significantly lowered when the manure was inoculated with most of the N₂-generating strains. In soil microcosms, N₂O was emitted during incubation after application of the pelleted manure, while N₂O flux was significantly lowered when the soil was inoculated with Azoarcus sp. KS11B, Niastella sp. KS31B, or Burkholderia sp. TSO47-3 on the 12th day of incubation. In addition, when pelleted manure was inoculated with the strains prior to application in the soil microcosms, the level of N₂O emission was significantly lowered to ca. 40–60 % that from the non-inoculated control. Our study provides the prototype of a technique that uses microbial technology to mitigate N₂O emission from agricultural soil fertilized with pelleted poultry manure.     

农业土壤中的氧化亚氮排放: 为减排综述时空变化

This short review deals with soils as an important source of the greenhouse gas N2O. The production and consumption of N2O in soils mainly involve biotic processes: the anaerobic process of denitrification and the aerobic process of nitrification. The factors that significantly influence agricultural N2O emissions mainly concern the agricultural practices (N application rate, crop type, fertilizer type) and soil conditions (soil moisture, soil organic C content, soil pH and texture). Large variability of N2O fluxes is known to occur both at different spatial and temporal scales. Currently new techniques could help to improve the capture of the spatial variability. Continuous measurement systems with automatic chambers could also help to capture temporal variability and consequently to improve quantification of N2O emissions by soils. Some attempts for mitigating soil N2O emissions, either by modifying agricultural practices or by managing soil microbial functioning taking into account the origin of the soil N2O emission variability, are reviewed.     

Primed N2O emission from native soil nitrogen: A 15N‐tracing laboratory experiment

Soils can naturally be a source of the potent greenhouse gas nitrous oxide (N₂O). By contrast, the largest anthropogenic source of N₂O is the application of nitrogen (N) fertilizer on agricultural soil, but it is unclear if fertilizer‐supported N₂O emission only originates from the fertilizer N directly or through additionally stimulated N₂O production from native soil N. Even though native soil N also includes mineral N already in soil before fertilizer application, organic N is the principal native N pool and thereby provides for mineral N cycling and N₂O emission. Here, we tested (1) the contribution of native soil N to N₂O emission after mineral N fertilizer application and (2) whether it is affected by different soil organic matter (SOM) contents by conducting a laboratory ¹⁵N‐tracing experiment with agricultural soil from a long‐term field trial with two treatments. Both field treatments are fertilized with mineral N, whereas only one of the two receives liquid manure causing higher SOM content. Soil sampling was conducted in March 2016 shortly before fertilizer application in the field. The application of ¹⁵N‐labeled fertilizer more than doubled the N₂O production from native N sources compared to the non‐fertilized control incubations. This primed N₂O production contributed by 5–8% to the fertilizer‐induced N₂O emission after one week of incubation and was similar for both field treatments regardless of liquid manure application. Therefore, further research is needed to link N₂O priming to its potential production pathways and sources. While the observed effect may be important in soils, the amount of applied N fertilizer remains the largest concern being responsible for the majority of N₂O emission.     

生物炭施用下中国农田土壤N2O排放的Meta分析

为明确施加生物炭对中国农田土壤N_2O排放的影响和主要控制因素,以公开发表的试验数据为研究对象,采用Meta-analysis法定量分析了施加生物炭条件下,气候、土壤性质、田间管理方式、生物炭性质与施加量对土壤N_2O排放的影响,并对各影响因素进行通径分析。结果表明,当年降雨量≥600 mm时,生物炭显著降低土壤N_2O排放量(P0.05),且随年降雨量的增加而增强;当年日照时数大于1 000 h时,生物炭对土壤N_2O的减排效果随年日照时数的增加而减弱。当土壤p H≥6.5时,生物炭对土壤N_2O的减排效果随土壤p H的增加呈先增后减趋势;在壤土中施加生物炭对N_2O的减排效果显著(P0.05),而砂土和黏土不显著(P0.05)。生物炭对覆膜土壤N_2O的减排效果优于不覆膜土壤;生物炭对土壤N_2O的减排效果随施氮肥量增加而减弱,而随生物炭比表面积的增加而增强。当生物炭C/N处于30~500时,生物炭施用下土壤N_2O排放量显著降低(P0.05);当生物炭施加量处于20~160 t×hm-2时,生物炭对土壤N_2O的减排效果随施加量增加而增强。生物炭对土壤N_2O减排的影响存在显著的区域性特征,对华南、华东、华中和东北地区影响显著(P0.05),而对西北地区不显著(P0.05);施氮肥量、生物炭施加量、年均温和年降雨量是影响生物炭减排效果的最主要因素,这些因素的相互作用共同影响生物炭对土壤N_2O的减排效果。该研究可为生物炭在我国农区的推广应用和农田N_2O减排提供参考。     

Elevated carbon dioxide stimulates nitrous oxide emission in agricultural soils: A global meta-analysis

Elevated carbon dioxide (CO₂)(e CO₂) has been shown to affect the nitrous oxide (N₂O) emission from terrestrial ecosystems by altering the interaction of plants,soils,and microorganisms.However,the impact of e CO₂ on the N₂O emission from agricultural soils remains poorly understood.This meta-analysis summarizes the effect of e CO₂ on N₂O emission in agricultural ecosystems and soil physiochemical and biological characteristics using 50 publications selected.The e CO₂ effect values,which equal to the percentage changes of N₂O emission under e CO₂,were calculated based on the natural logarithm of the response ratio to e CO₂.We found that e CO₂ significantly increased N₂O emission (by 44%),which varied depending on experimental conditions,agricultural practices,and soil properties.In addition,e CO₂ significantly increased soil water-filled pore space (by 6%),dissolved organic carbon content (by11%),and nitrate nitrogen content (by 13%),but significantly reduced soil p H (by 1%).Moreover,e CO₂ significantly increased soil microbial biomass carbon(by 28%) and soil microbial biomass nitrogen (by 7%) contents.Additionally,e CO₂ significantly increased the abundances of ammonia-oxidizing bacteria(AOB) amo A (by 21%),nir K (by 15%),and nir S (by 15%),but did not affect the abundances of ammonia-oxidizing archaea (AOA) amo A and nos Z.Our findings indicate that e CO₂ substantially stimulates N₂O emission in agroecosystems and highlight that optimization of nitrogen management and agronomic options might suppress this stimulation and aid in reducing greenhouse effect.     

农业土壤排放氧化亚氮的影响因素分析

氧化亚氮（N₂O）是重要的温室气体之一。本文从施肥、灌溉、耕作、种植作物及土地用途改变等方面论述了农业活动对土壤排放氧化亚氮的影响，并总结了减排措施。