施肥对稻田N2O排放的影响

肥料施用是影响稻田N20排放的重要因素之一。以国内外相关文献为基础,综述了肥料的种类、施用量、施用方式和施用时间对稻田N2O排放的影响,指出了有待研究的内容：加强对土壤N2O排放机理的研究;进一步研究肥料施用对稻田N2O排放的影响;进一步研究施肥管理措施对稻田温室气体（CH4和N2O）排放的交互影响,寻求科学合理、切实可行的减排措施。     

尿素施用对稻田土壤甲烷产生、氧化及排放的影响

通过田间和培养试验研究了不施尿素(N0kg/hm2)和施用尿素(N300kg/hm2)对水稻生长期稻田土壤CH4产生潜力、氧化潜力和排放通量的影响。结果表明,水稻全生育期内,施用尿素降低土壤CH4产生潜力,并推迟其达到最大值的时间;尿素作为基肥和穗肥施用抑制土壤CH4氧化,而作为分蘖肥施用短暂地促进然后抑制土壤CH4氧化;施用尿素降低稻田CH4排放量。施用尿素通过同时影响CH4产生潜力和氧化潜力来影响稻田CH4排放。     

不同耕作方式下稻田土壤CH4和CO2的排放及碳收支估算

二氧化碳（CO2）和甲烷（CH4）是重要的温室气体,研究免耕稻田CO2和CH4排放有助于评价稻田免耕技术对全球气候变化及碳循环的影响。本文通过运用静态箱技术和田间原位碱液吸收法研究了免耕稻田土壤CO2和CH4的排放规律和排放量,及其稻田碳（C）的收支状况。研究表明,施肥提高了CH4排放,而不影响CO2的排放;免耕显著影响稻田CH4排放,而CO2的排放不受耕作影响。对稻田C收支及平衡的分析表明,施肥提高了稻田系统C的输入,同时,相对于翻耕处理,免耕处理表现为大气C的“汇”,表明了稻田免耕能将更多的碳累积于农田土壤碳库中,有利于提高稻田生态系统在减缓气温上升过程中所发挥的作用。     

冬季秸秆还田对冬灌田水稻生长期CH4产生、氧化和排放的影响

有机肥施用和土壤水分管理是影响稻田CH4排放最重要的2个因素。本文通过室内培养和田间试验研究了冬季秸秆还田对冬灌田水稻生长期CH4的产生、氧化和排放的影响。结果表明:淹水混施处理CH4产生潜力在水稻移栽后35和51天显著大于淹水不施肥处理(p0.05),其余时间则无显著差异(p0.05);冬季秸秆还田对CH4氧化潜力无显著影响(p0.05),水稻生长期土温和稻田施用氮肥可能是较其更重要的影响因素;淹水混施处理CH4平均排放通量(CH426.7mg/(m2·h))显著大于淹水不施处理(CH420.3mg/(m2·h))(p0.05)。     

长期不同施肥下太湖地区稻田净温室效应和温室气体排放强度的变化

利用田间观测和模型预测方法对太湖地区一个长期不同施肥处理的稻田生态系统进行了稻季温室气体排放观测和净温室气体排放强度分析。结果表明,不同施肥管理下,稻田土壤有机碳含量不同程度提高,有机无机肥料配施较单施化肥处理显著提高有机碳库储量,并且秸秆处理略高于猪粪处理。与不施肥处理相比,长期施用肥料显著提高了稻田生态系统CH4和CO2的排放量,有机肥料与化肥配施较单纯施用化学肥料下土壤碳（CO2和CH4）排放增加,但化肥配施秸秆与化肥配施猪粪下稻田生态系统CH4和CO2的排放没有显著差异。不同施肥处理下,稻田生态系统净温室效应表现为CFM≈CFS〉CF〉NF,但水稻生产的净温室气体排放强度并没有显著性差异。因此,在提高水稻产量的同时,有机无机配合施肥并没有提高净温室气体的排放强度。     

三江平原寒地稻田CH_4、N_2O排放特征及排放量估算

利用静态暗箱-气相色谱法,于2003-2006年对三江平原寒地稻田CH4、N2O通量进行了为期4年的田间原位观测研究.结果表明:三江平原寒地稻田CH4和N2O排放具有明显的季节变化,水稻生长季淹水期是CH4排放的强源,稻田排水后CH4排放显著下降,休闲期CH4排放微弱或呈弱吸收汇,整个生长季CH4排放呈现单峰型态,并随水稻植株生长和叶面积指数而变化;水稻生长季和休闲期N2O排放通量都很小,冬季休闲期有时还出现微弱的吸收现象.生长季一般在施肥和表土落干时都会出现不同强度的排放峰,除了几次比较显著的排放峰值外,其它淹水状态下N2O排放很弱;温度和土壤水分状况是影响稻田CH4和N2O排放的重要因子,稻田积水深度和气体排放无明显的相关性;水稻植株对稻田土壤CH4排放起促进作用而对稻田土壤N2O排放起抑制作用;稻田氮肥用量增加可以降低土壤CH4排放,但却增加了N2O的排放.根据试验数据对三江平原地区寒地稻田CH4和N2O排放总量估算值分别为0.1035 Tg/a和0.0021 Tg/a.     

绿肥压青粉垄保护性耕作对稻田土壤温室气体排放的影响

2016-2018年,在广西农业科学院试验田设置粉垄耕作与常规耕作2种耕作模式,并设不施肥、常规施用化肥、单倍绿肥压青+化肥和双倍绿肥压青+化肥4种施肥处理开展连续田间定位实验,2018年早稻插秧5d后开始采用分离式静态箱-气象色谱法连续对稻田温室气体排放通量进行测定,研究绿肥压青下不同耕作模式和施肥处理稻田主要温室气体排放特征及其定位累积效应,分析温室气体累积排放量和增温潜势,以期为粉垄保护性耕作方式和施肥管理模式提供参考依据。结果表明：粉垄耕作模式下常规施用化肥处理中CO2排放通量是常规耕作模式下的2.3倍,施用双倍绿肥处理稻田CH4排放峰值是化肥处理中的2.5～3.9倍。各处理中,粉垄耕作下单倍绿肥加化肥处理稻田CO2和N2O累积排放量均最少,分别为1469.29kg·hm-2和36.61g·hm-2。两种耕作模式下施用单倍绿肥加化肥CH4累积排放量均低于双倍绿肥加化肥的处理。可见,合理配施绿肥加化肥对粉垄耕作下水稻温室气体CO2和N2O减排有一定积极作用,稻田CH4排放量与绿肥压青量相关,温室气体的增温潜势也相应受到影响。在一定时间尺度上,绿肥压青下粉垄保护性耕作是一种减少和遏制农业温室气体排放的有效措施。     

稻田甲烷排放影响因素及其研究进展

CH4是大气中仅次于CO2的最重要的温室气体之一,其温室效应贡献已达15～20%。中国稻田是CH4的重要排放源,对全球大气的CH4排放起着重要的作用。本文较为详细地介绍了近几十年来国内外关于稻田CH4排放的研究进展。对稻田CH4的排放机理、CH4的排放规律及影响稻田CH4排放的各种因素作了详细分析,并相应地提出了控制稻田CH4排放的各种措施,最后提出了今后我国稻田CH4排放研究应加强的几个方面内容。     

生物质炭还田对稻田甲烷的减排效果

为探讨不同生物质炭类型、输入量、还田时间和还田深度等因素作用下的CH4排放特征,采用静态箱-气相色谱法,通过向稻田土壤中施用3种类型的生物质炭（稻秆炭、麦秆炭、竹炭）,开展了水稻一个生长周期的室内观测试验。结果表明,3种类型的生物质炭输入后,对比空白处理,水稻产量显著性增加（P<0.05）,其中竹炭处理每盆实粒质量高达18.12 g,说明施用生物质炭可增加水稻产量;竹炭施用后稻田土壤CH4排放通量（80 mg/m2 h）显著低于稻杆炭和麦杆炭处理（P<0.05）,而稻杆炭和麦杆炭处理无显著性差异（P>0.05）,但都显著高于空白处理（P<0.05）,说明施用生物质炭可有效减少CH4排放。CH4排放通量与生物质炭用量负相关,CH4的排放通量随着生物质炭用量的逐渐增加而降低。同时,水稻移植前施用竹炭CH4排放通量（56.6 mg/m2 h）低于空白（96 mg/m2 h）及水稻成活前后（73.4和76.6 mg/m2 h）,但无显著性差异（P>0.05）,这与土壤氧化还原电位（Eh）变化相一致,说明生物质炭施用时间对稻田土壤CH4排放通量影响不大。此外,不同竹炭还田深度下的土壤CH4排放通量顺序为：中部输入（15 cm处输入）<表层输入（5 cm处输入）<深部输入（25 cm处输入）<空白（不输入生物质炭）,说明生物质炭中部输入更适用微生物生长和CH4气体减排。该研究可为太湖地区苕溪流域稻田增汇和温室气体减排提供参考。     

施肥对稻田温室气体排放及土壤养分的影响

【目的】农业活动引起的温室气体排放对全球变暖的影响日益得到关注,本试验研究不同施肥处理对稻田温室气体排放、 产量和土壤养分的影响,以期为农田可持续利用和温室气体减排提供依据。【方法】在长江中下游地区稻麦轮作区进行田间试验,设置不施氮肥(CK)、 当地习惯施肥(FP)、 推荐N肥(OPT)、 有机无机配施(OPT+M)、 秸秆还田(OPT+S)5个处理,采用静态箱/气相色谱(GC)法测定了稻季CH4、 N2O和CO2的排放情况,调查了不同施肥措施对稻田温室气体增温潜势以及产量,测定了土壤养分,并综合产量和增温潜势对温室气体排放强度进行分析,提出该区域稻田减排增产的合理施肥措施。【结果】 1) 不同处理CH4季节排放总量为OPT+SOPT+M FP OPT CK,排放量为99.02~143.69 kg/hm2; N2O季节排放量为FPOPT+MOPT OPT+S CK,排放量范围为0.95~3.57 kg/hm2; CO2排放顺序与CH4季节排放趋势一致,排放量为7231.64~13715.24 kg/hm2。2)根据稻季CH4和N2O季节排放量以及在100年尺度上的CO2当量计算,不同处理温室气体全球增温潜势大小顺序为OPT+SOPT+M FP OPT CK。在CK、 FP、 OPT、 OPT+M和OPT+S的全球增温潜势中,N2O占的比重分别为10.31%、 26.39%、 21.51%、 22.91% 和11.58%,CH4所占比重分别为89.69%、 73.61%、 78.49%、 77.09%和88.42%。稻田N2O的排放量很少,排放以甲烷为主,因此不同施肥措施所排放的N2O对综合温室效应的贡献远低于CH4。相对于当地习惯施肥处理,OPT、 OPT+M和OPT+S 3种优化施肥措施均在减少化肥施用量的情况下增加了水稻产量,增产率分别为3.6%、 14.3%和 8.5%,其中以有OPT+M处理增产效果最明显。3)不同施肥处理下,CO2排放强度为FP(0.56)OPT+S(0.52) OPT(0.50)OPT+M(0.49),OPT和OPT+M显著低于当地习惯施肥处理,OPT+M CO2排放强度最低。4)有机碳、 全氮、 速效磷和速效钾含量均在OPT+S处理中最高。【结论】不同施肥措施影响稻季温室气体排放,施用有机肥和氮肥均增加了CO2、 CH4、 N2O的排放,秸秆还田增加了CO2和CH4排放,减少了N2O排放。稻田减排应以减少CH4排放为主,推荐氮肥量配施有机肥为碳强度评价体系下最优处理。秸秆还田对土壤养分的改善趋势明显,虽然增加了CO2排放,但考虑到其可避免因焚烧造成大量CO2的排放,总体上依然减少了CO2的排放,但对秸秆还田的适宜量需要进一步研究。     

中国三类典型稻田CH4排放的稳定性碳同位素变化

Little is known about the stable carbon isotopes of methane(CH4) emitted(δ~(13)CH_(4emitted)) from permanently flooded rice fields and double rice-cropping fields.The CH4 emission and corresponding δ~(13)CH_(4emitted) under various field managements(mulching,water regime,tillage,and nitrogen(N) fertilization) were simultaneously measured in three typical Chinese rice fields,a permanently flooded rice field in Ziyang City,Sichuan Province,Southwest China,a double-rice cropping field in Yingtan City,Jiangxi Province,Southeast China,and a rice-wheat rotation field in Jurong City,Jiangsu Province,East China,from 2010 to 2012.Results showed different seasonal variations of δ~(13)CH_(4emitted) among the three fields during the rice-growing season.The values of δ~(13)CH_(4emitted) were negatively correlated with corresponding CH4 emissions in seasonal variation and mean,indicating the importance of CH_4 production,oxidation,and transport associated with isotopic fractionation effects to the δ~(13)CH_(4emitted).Seasonal variations of δ~(13)CH_(4emitted) were slightly impacted by mulching cultivation,tillage,and N application,but highly controlled by drainage.Meanwhile,tillage,N application,and especially mulching cultivation had important effects on seasonal mean CH4 emissions and corresponding δ~(13)CH_(4emitted) with low emissions accompanied by high values of δ~(13)CH_(4emitted).Seasonal mean values of δ~(13)CH_(4emitted) from the three fields were similar,mostly ranging from —60‰ to — 50‰,which are well in agreement with previously published data.These demonstrated that seasonal variations of δ~(13)CH_(4emitted) mainly depended on the changes in CH4 emission from rice fields and further indicated the important effects of methanogenic pathways,CH4 oxidation,and CH4 transport associated with isotope fractionation effects influenced by field managements on δ~(13)CH_(4emitted).     

Degradability of black carbon and its impact on trace gas fluxes and carbon turnover in paddy soils

Rice paddy soils are characterized by anoxic conditions, anaerobic carbon turnover, and significant emissions of the greenhouse gas methane. A main source for soil organic matter in paddy fields is the rice crop residue that is returned to fields if not burned. We investigated as an alternative treatment the amendment of rice paddies with rice residues that have been charred to black carbon. This treatment might avoid various negative side effects of traditional rice residue treatments. Although charred biomass is seen as almost recalcitrant, its impact on trace gas (CO₂, CH₄) production and emissions in paddy fields has not been studied. We quantified the degradation of black carbon produced from rice husks in four wetland soils in laboratory incubations. In two of the studied soils the addition of carbonised rice husks resulted in a transient increase in carbon mineralisation rates in comparison to control soils without organic matter addition. After almost three years, between 4.4% and 8.5% of the black carbon added was mineralised to CO₂ under aerobic and anaerobic conditions, respectively. The addition of untreated rice husks resulted in a strong increase in carbon mineralisation rates and in the same time period 77%-100% of the added rice husks were mineralised aerobically and 31%-54% anaerobically. The ¹³C-signatures of respired CO₂ gave a direct indication of black carbon mineralisation to CO_2. In field trials we quantified the impact of rice husk black carbon or untreated rice husks on soil respiration and methane emissions. The application of black carbon had no significant effect on soil respiration but significantly enhanced methane emissions in the first rice crop season. The additional methane released accounted for only 0.14% of black carbon added. If the same amount of organic carbon was added as untreated rice husks, 34% of the applied carbon was released as CO₂ and methane in the first season. Furthermore, the addition of fresh harvest residues to paddy fields resulted in a disproportionally high increase in methane emissions. Estimating the carbon budget of the different rice crop residue treatments indicated that charring of rice residues and adding the obtained black carbon to paddy fields instead of incorporating untreated harvest residues may reduce field methane emissions by as much as 80%. Hence, the production of black carbon from rice harvest residues could be a powerful strategy for mitigating greenhouse gas emissions from rice fields.     

Effect of the long-term application of anaerobically digested residual slurry on methane emissions in a rice paddy field

ABSTRACT

The anaerobic digestion of livestock manure is an environmentally compatible technology used for the production of renewable energy. Anaerobically digested residual slurry has been used worldwide as a liquid fertilizer in both upland and paddy fields. However, a controversial question remains as to whether the application of slurry to rice paddy fields increases methane emissions; although methane is one of the most prevalent greenhouse gases, little is known about the effects of the long-term application of residual slurry on methane emission. In this study, we repeatedly applied slurry to a paddy field for six years at different application rates (10, 15, and 20 g N m^?2 based on ammonium-nitrogen content). At the fifth and sixth years of application, we evaluated the effect in terms of methane flux and soil total carbon content. The effect of the long-term application of the slurry (10 g N m^?2) on grain yield was equivalent to that of chemical fertilizer (10 g N m^?2). The application of the residual slurry was likely to increase the cumulative methane emissions during rice growing season in both 2006 and 2007. On the other hand, we observed that soil total carbon did not accumulate significantly in the soil. Thus, we cannot rule out the potential risk of additional methane emissions caused by the application of the residuary slurry to paddy fields.     

Enhanced iron reduction by iron supplement: A strategy to reduce methane emission from paddies

As an option for mitigating methane emissions from rice paddies the effects of ferrihydrite application to an experimental field plot at the beginning of the growth season was studied. Methane emissions during the vegetation period of rice were significantly lower (50%) in the fertilized plot compared to the non-supplemented control plot. Although toxic effects of iron are known to occur with wetland plants including rice, our field experiment showed no deterioration of agrophysiological data. Grain yield, harvest index, and iron content of grains were not different in the two plots. Therefore, we propose that iron application is a suitable strategy to reduce methane emission from rice paddies.     

长期施肥对湖南稻田甲烷排放的影响

采用静态箱-气相色谱法对长期不同施肥处理的稻田甲烷排放进行了手动观测。结果表明，不同施肥处理的稻田甲烷排放具有一致的规律，混施有机肥的处理甲烷排放大于单施氮肥的处理，同施用稻草相比，发酵猪粪处理的甲烷排放较少。文章还对影响稻田甲烷排放的因素进行了讨论。     

Effect of silicate fertilizer on reducing methane emission during rice cultivation

Slag-type silicate fertilizer, which contains high amount of active iron oxide, a potential source of electron acceptor, was applied at the rate of 0, 2, 6, 10, and 20 Mg ha⁻¹ to reduce methane (CH₄) emission from rice planted in potted soils. Methane emission rates measured by closed chamber method decreased significantly with increasing levels of silicate fertilizer application during rice cultivation. Soil redox potential (Eh) decreased rapidly after flooding, but floodwater pH and soil pH increased significantly with increasing levels of silicate fertilizer application. Iron concentrations in potted soils and in percolated water significantly increased with the increasing levels of silicate fertilizer application, which acted as oxidizing agents and electron acceptors, and thereby suppressed CH₄ emissions. Silicate fertilization significantly decreased CH₄ production activity, while it increased carbon dioxide (CO₂) production activity. Rice plant growth, yield parameters, and grain yield were positively influenced by silicate application levels. The maximum increase in grain yield (17% yield increase over the control) was found with 10 Mg ha⁻¹ silicate application along with 28% reduction in total CH₄ flux during rice cultivation. It is, therefore, concluded that slag-type silicate fertilizer could be a suitable soil amendment for reducing CH₄ emissions as well as sustaining rice productivity and restoring the soil nutrient balance in rice paddy soil.     

硅基材料包膜肥对红壤区双季稻生长和土壤肥力的影响

选择了高肥力田、低肥力田,通过早、晚双季稻连续2年4季的大田试验,研究了施用硅基材料包膜肥对双季稻动态生长、产量、土壤肥力、微生物量、酶活性的影响。结果表明:不论是高肥力田还是低肥力田,与传统施肥相比,一次性基施硅基材料包膜肥能提高双季稻的最大分蘖数3~6枝·兜~(-1),提高成熟期叶片的叶绿素含量,提高成熟期双季稻的生物产量7.8%~22.4%,提高年均产量3.0%~14.7%,并且在低肥力田上效果显著。与传统施肥处理相比较,施硅基材料包膜肥可以显著提高双季稻成熟期土壤中的矿质态氮含量,提高幅度为28.3%~37.7%。包膜肥对土壤中微生物群落没有影响,在低肥力田施用80%的包膜肥其土壤酶活性综合指数最高。由此可见,施用硅基材料包膜肥在南方水稻上完全可以替代分次施用常规肥料,并且在高肥力田减少20%肥料用量的情况下仍然等效,达到了减肥增效和节本省工的目的。     

施氮水平对杂交晚粳“浙优12”产量及氮素利用效率的影响

为探讨杂交粳稻"浙优12"最佳施氮量,采用田间试验研究了不同施氮水平对浙北平原黄松田水稻产量和氮素利用率的影响。结果表明,水稻产量、氮肥生理效率(PEN)、氮肥回收率(REN)均以施氮量210 kg/hm2处理最高,分别比无氮肥区提高了54.4%、34.1 kg/kg和58.6%;与无氮肥区相比,在施N 150 kg/hm2基础上,配施适量有机肥有助于提高氮素利用率和产量,其PEN和REN分别提高33.1 g/g和50.6%,水稻增产61.2%。本试验条件下,综合稻谷产量、生态效应和经济效益三项因素,合理的水稻施氮量为N 234.8～241.0 kg/hm2,相应的经济生态产量为9796.4～9801.9 kg/hm2。