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.     

基于Century模型和1:500 000土壤数据库的华东旱地土壤有机碳动态模拟

Changes in soil organic carbon (SOC) in agricultural soils influence soil quality and greenhouse gas concentrations in the atmosphere. Dry farmland covers more than 70% of the whole cropland area in China and plays an important role in mitigating carbon dioxide (CO2) emissions. In this study, 4109 dry farmland soil polygons were extracted using spatial overlay analysis of the soil layer (1:500000) and the land use layer (1:500000) to support Century model simulations of SOC dynamics for dry farmland in Anhui Province, East China from 1980 to 2008. Considering two field-validation sites, the Century model performed relatively well in modeling SOC dynamics for dry farmland in the province. The simulated results showed that the area-weighted mean soil organic carbon density (SOCD) of dry farmland increased from 18.77 Mg C ha1 in 1980 to 23.99 Mg C ha1 in 2008 with an average sequestration rate of 0.18 Mg C ha1 year?1. Approximately 94.9% of the total dry farmland area sequestered carbon while 5.1% had carbon lost. Over the past 29 years, the net SOC gain in dry farmland soils of the province was 19.37 Tg, with an average sequestration rate of 0.67 Tg C year1. Augmentation of SOC was primarily due to increased consumption of nitrogen fertilizer and farmyard manure. Moreover, SOC dynamics were highly differentiated among dry farmland soil groups. The integration of the Century model with a fine-scale soil database approach could be conveniently utilized as a tool for the accurate simulation of SOC dynamics at the regional scale.     

中国西北地区膜下滴灌对棉田土壤CO2通量和浓度的影响

In northwestern China,there has been a change from traditional cultivation system (TC) with no mulching and flood irrigation to a more modern cultivation system (MC) using plastic film mulching with drip irrigation.A field study was conducted to compare soil CO 2 concentrations and soil surface CO 2 fluxes between TC and MC systems during a cotton growing season.CO 2 concentrations in the soil profile were higher in the MC system (3 107-9 212 μL L-1) than in the TC system (1 275-8 994 μL L-1) but the rate of CO 2 flux was lower in the MC system.Possible reasons for this included decreased gas diffusion and higher soil moisture due to the mulching cover in the MC system,and the consumption of soil CO2 by weathering reactions.Over the whole cotton growing season,accumulated rates of CO2 flux were 300 and 394 g C m-2 for the MC and TC systems,respectively.When agricultural practices were converted from traditional cultivation to a plastic film mulching system,soil CO 2 emissions could be reduced by approximately 100 g C m-2 year-1 in agricultural lands in arid and/or semi-arid areas of northern and northwestern China.     

盐碱地土壤：氧化亚氮和二氧化碳排放的潜在来源？

Increasing salt-affected agricultural land due to low precipitation,high surface evaporation,irrigation with saline water,and poor cultural practices has triggered the interest to understand the influence of salt on nitrous oxide(N_2O) and carbon dioxide(CO_2)emissions from soil.Three soils with varying electrical conductivity of saturated paste extract(EC_e)(0.44-7.20 dS m~(-1)) and sodium adsorption ratio of saturated paste extract(SARe)(1.0-27.7),two saline-sodic soils(S2 and S3) and a non-saline,non-sodic soil(S1),were incubated at moisture levels of 40%,60%,and 80%water-filled pore space(WFPS) for 30 d,with or without nitrogen(N)fertilizer addition(urea at 525 μg g~(-1) soil).Evolving CO_2 and N2 O were estimated by analyzing the collected gas samples during the incubation period.Across all moisture and N levels,the cumulative N_2O emissions increased significantly by 39.8%and 42.4%in S2 and S3,respectively,compared to S1.The cumulative CO_2 emission from the three soils did not differ significantly as a result of the complex interactions of salinity and sodicity.Moisture had no significant effect on N_2O emissions,but cumulative CO_2 emissions increased significantly with an increase in moisture.Addition of N significantly increased cumulative N_2O and CO_2 emissions.These showed that saline-sodic soils can be a significant contributor of N_2O to the environment compared to non-saline,non-sodic soils.The application of N fertilizer,irrigation,and precipitation may potentially increase greenhouse gas(N2O and CO_2) releases from saline-sodic soils.     

施肥处理和环境因素对华北平原春玉米田N2O排放的影响——以山西晋中为例

采用静态箱自动采样监测系统,对生长季内华北平原春玉米田在不同施肥处理下（化肥、有机肥、有机无机配施和不施肥）的土壤N2O排放通量进行监测,分析各处理的土壤N2O排放量和变化规律,探讨土壤温度、水分和有效氮含量对土壤N2O排放通量的影响,并在相同施氮量条件下寻求既能增产又能减少N2O排放的施肥措施。结果表明：不同施肥处理下N2O排放通量存在显著差异（P〈0.05）,其中施肥处理的农田N2O-N排放总量为0.99～1.17kg.hm-2,占总施氮量的0.45%～0.55%;N2O通量与土壤铵态氮含量呈极显著正相关（P〈0.01）;土壤含水量是影响农田N2O排放的一个主要因子,N2O通量与土壤含水量呈显著正相关;在产量无显著下降的情况下,有机无机配施的减排效果最好。     

土壤N2O和NO产生机制研究进展

N2O和NO是大气中两种重要的活性氮气体,强烈影响着全球变化和生态环境。土壤是N2O和NO的重要排放源,生物和非生物途径均可产生N2O和NO。本文详细论述了自养硝化、异养硝化、生物反硝化、化学反硝化、硝化细菌反硝化和硝态氮异化还原成铵作用产生N2O和（或）NO的机制,并对研究中存在的一些问题进行了探讨。     

菜地土壤CO2与N2O排放特征及其规律

为了解不同集约化类型菜地土壤CO2和N2O排放特征及影响因子,选取京郊20年露地老菜地(OV20)、3年菜地种植历史的露地新菜地(OV3)、3年大棚菜地(GV3),以及相邻的当地典型粮田玉米地(Maize)4个类型地块,研究了春黄瓜生育期间土壤CO2和N2O排放特征及影响因子。结果表明:1)春黄瓜生育期间的土壤CO2排放通量主要受土壤5 cm处温度(指数关系)和土壤水分(对数关系或二次抛物线关系)影响;期间玉米地土壤CO2平均排放通量为(346.8±56.5)mg.m-2.h-1,20年露地菜地、3年露地菜地有机肥处理、3年露地菜地配施处理、3年大棚菜地的土壤CO2平均排放通量分别是玉米地的1.38、1.21、1.39和1.56倍。2)土壤N2O排放通量与施肥活动密切相关,排放高峰都出现在氮肥施用后,并受土壤温度和水分的影响。基肥后土壤温度低(15～20℃),排放峰出现在第5 d,排放峰持续时间(长达20 d)与施肥量相关;追肥后土壤温度高(>20℃),排放高峰发生早(追肥后第3 d),但因追肥用量低,因此持续时间短(仅一周)。3)黄瓜生长期内玉米地N2O累积排放量为N(1.95±0.10)kg.hm-2,20年老菜地、3年大棚菜地和3年新菜地N2O累积排放量分别是同期大田玉米地的1.67、1.95和1.99倍。4)本实验中春黄瓜生长季菜地土壤化肥氮N2O排放系数在1.86%～4.71%之间,显著高于IPCC旱地排放缺省值1%。其中,新菜地排放系数高于老菜地,设施菜地排放系数高于露地菜地;但有机肥氮的N2O排放系数则远远低于化肥氮的排放系数,仅为0.11%。     

Greenhouse gas emissions from Silphium perfoliatum and silage maize cropping on Stagnosols

Background

The sustainability of bioenergy is strongly affected by direct field-derived greenhouse gas (GHG) emissions and indirect emissions form land-use change. Marginal land in low mountain ranges is suitable for feedstock production due to small impact on indirect land-use change. However, these sites are vulnerable to high N₂O emissions because of their fine soil texture and hydrology.

Aims

The perennial cup plant (Silphium perfoliatum L.) might outperform silage maize (Zea mays L.) on cold, wet low mountain ranges sites regarding yield and ecosystem services. The aim of this study was to assess whether the cultivation of cup plant also provides GHG mitigation potential compared to the cultivation of maize.

Methods

A t-year field experiment was conducted in a low mountain range region in western Germany to compare area and yield-scaled GHG emissions from cup plant and maize fields. GHG emissions were quantified using the closed chamber method.

Results

Cup plant fields emitted an average of 3.6 ± 4.3 kg N₂O-N ha^–1 year^–1 (–85%) less than maize fields. This corresponded to 74.0 ± 94.1 g CO_2-eq kWh^–1 (–78%) less emissions per produced electrical power. However, cup plant had a significantly lower productivity per hectare (–34%) and per unit of applied nitrogen (–32%) than maize.

Conclusion

Cup plant as a feedstock reduces direct field-derived GHG emissions compared to maize but, due to lower yields cup plant, likely increases emissions associated with land-use changes. Therefore, the increased sustainability of bioenergy from biogas by replacing maize with cup plant is heavily dependent on the performance of maize at these sites and on the ecosystem services of cup plant in addition to GHG savings.     

加气灌溉水氮互作对温室芹菜地N2O排放的影响

为揭示加气条件下不同灌溉和施氮量对设施菜地N2O排放的影响,提出有效的N2O减排措施,该研究以温室芹菜为例,设置充分灌溉(1.0 Ep,I1;Ep为2次灌水间隔内φ20 cm标准蒸发皿的累计蒸发量)和亏缺灌溉(0.75 Ep,I2)2个灌溉水平和0 (N0)、150 (N150)、200 (N200)、250 kg/hm2 (N250)4个施氮水平,采用静态箱-气相色谱法对各处理土壤N2O的排放进行监测,并分析不同灌溉和氮肥水平下土壤温度、湿度、矿质氮(NH4+-N和NO3--N)、硝化细菌和反硝化细菌的变化,以及对土壤N2O排放的影响.结果表明:充分灌水温室芹菜地N2O排放显著(P＜0.05)高于亏缺灌溉;施氮显著(P＜0.05)增加了土壤N2O排放,N150、N200和N250处理的N2O累积排放量分别是N0处理的2.30、4.14和7.15倍.设施芹菜地N2O排放与土壤温度、湿度和硝态氮含量呈指数相关关系(P＜0.01),与硝化细菌和反硝化细菌数量呈线性相关关系(P＜0.01),而与土壤铵态氮没有显著相关关系.灌水和施氮提高芹菜产量的同时,显著增强了土壤N2O排放.综合考虑产量和温室效应,施氮量150 kg/hm2、亏缺灌溉为较佳的管理模式.该研究为设施菜地N2O减排及确定合理的水氮投入量提供参考.     

免耕方式下土壤温室气体排放及影响因素的研究进展

综述了免耕方式下农田土壤中3种主要温室气体(CO2、N2O和CH4)的排放情况及影响因素。分析发现,这些温室气体的排放受到诸多因子的影响,如免耕农作持续时间、土壤特性、秸秆(种类、粉碎长短和施用方式)、降水和土壤温度等等。大多数研究都认为,免耕方式下CO2和CH4的释放有所降低,N2O的释放会加强,但这种结果并不是不变的,它会随着影响因素的变化而变化,有时甚至出现相反的结果。因此,免耕方式下,温室气体的排放情况是由不同免耕地区的环境条件决定的,只有结合当地实际情况才能对温室气体的排放做出正确的评价。最后指出了目前研究的不足,并对今后的研究提出了展望。     

Effect of cattle slurry application techniques on N2O and NH3 emissions from a loamy soil

We determined N₂O fluxes from an unfertilized control (CON), from a treatment with mineral N‐fertilizer (MIN), from cattle slurry with banded surface application and subsequent incorporation (INC), and from slurry injection (INJ) to silage maize (Zea mays, L.) on a Haplic Luvisol in southwest Germany. In both years, amount of available N (total N fertilized + N_min content before N application) was 210 kg N ha^?1. In the slurry treatment of the 1^st year, 140 kg N ha^?1 were either injected or incorporated, whereas 30 kg N ha^?1 were surface applied to avoid destruction of the maize plants. In the 2^nd year, all fertilizers were applied with one single application. We calculated greenhouse gas emissions (GHG) on field level including direct N₂O emissions (calculated from the measured flux rates), indirect N₂O emissions (NH₃ and ${\mathrm{NO}}_3^{-}$ induced N₂O emission), net CH₄ fluxes, fuel consumption and pre‐chain emissions from mineral fertilizer. NH₃ losses were measured in the 2^nd year using the Dräger‐Tube Method and estimated for both years. NH₃ emission was highest in the treatment without incorporation. It generally contributed less than 5% of the greenhouse gas (GHG) emission from silage maize cultivation. The mean area‐related N₂O emission, determined with the closed chamber method was 2.8, 4.7, 4.4 and 13.8 kg N₂O‐N ha^?1 y^?1 for CON, MIN, INC, and INJ, respectively. Yield‐related N₂O emission showed the same trend. Across all treatments, direct N₂O emission was the major contributor to GHG with an average of 79%. Trail hose application with immediate incorporation was found to be the optimum management practice for livestock farmers in our study region.     

Application of the DNDC model to predict N2O emissions from sandy arable soils with differing fertilization in a long‐term experiment

Modeling crop growth and soil N dynamics is difficult due to the complex nature of soil–plant systems. In several studies, the DNDC model has been claimed to be well‐suited for this purpose whereas in other studies applications of the model were less successful. Objectives of this study were to test a calibration and validation scheme for DNDC‐model applications to describe a field experiment with spring wheat on a sandy soil near Darmstadt (SW Germany) using different fertilizer types (either application of mineral fertilizer and straw—MSI; or application of farmyard manure—FYM) and rates (low—MSI_L, FYM_L; and medium—MSI_M, FYM_M). The model test is based on a model parameterization to best describe the case MSI_L and applies this parameterization for a retrospective simulation of the other cases (MSI_M, FYM_L, FYM_M) including crop growth and N₂O emissions. Soil water contents were not accurately simulated using either the DNDC default values for a loamy sand or for the next finer texture class or using results from the pedotransfer function provided by ROSETTA. After successful calibration of the soil water flow model using a soil texture class that led to the best fit of the measured water content data, grain yield of spring wheat and cumulative N₂O emission were slightly underestimated by DNDC and were between 91% and 86% of the measured data. A subsequent calibration of the yields and cumulative N₂O emissions from soils of the MSI_L treatment gave a good prediction of crop growth and N₂O emissions in the MSI_M treatment, but a marked underestimation of yields of the FYM treatments. Cumulative N₂O emissions were predicted well for all MSI and FYM treatments, but seasonal dynamics were not. Overall, our results indicated that for the sandy soil in Germany, site‐specific calibration was essentially required for the soil hydrology and that a calibration was useful for a subsequent prediction where greater amounts of the same fertilizer were used, but not useful for a prediction with a different fertilizer type.     

Effects of substituting chemical fertilizers with manure on rice yield and soil labile nitrogen in paddy fields of China: A meta-analysis

Substituting chemical fertilizers with manure is an important method for efficient nutrient management in rice cropping systems of China.Labile nitrogen(N) is the most active component of the soil N pool and plays an essential role in soil fertility.However,the effects of manure substitution on soil labile N in rice cropping systems and their relationships with soil properties,fertilization practices,and climatic conditions remain unclear and should be systematically quantified.Here,we investiga...