温度对不同生态系统土壤甲烷氧化过程和甲烷氧化细菌的影响

温室气体的大量人为排放导致了近百年来的全球气候变化。甲烷是重要的温室气体,随着全球气温升高,甲烷排放量会随之增加,进一步加剧了全球温室效应。土壤是甲烷重要的源和汇,土壤中的甲烷氧化细菌在平衡甲烷的释放过程中发挥着关键作用。探究温度变化对土壤甲烷氧化能力的影响成为近年来的研究热点。本文综述了温度对土壤甲烷氧化过程以及甲烷氧化细菌的影响,分析了在不同温度下,各生态系统中的土壤甲烷氧化及甲烷氧化细菌响应特点和规律,比较了不同生态系统中土壤发生甲烷氧化的温度范围以及甲烷氧化菌株的生长温度范围。综述结果表明,不同生态系统能够发生甲烷氧化的温度范围不同;在能发生甲烷氧化的温度范围内,甲烷氧化速率随温度升高而增加;培养温度与土壤原位温度越相近时,甲烷氧化响应较为灵敏。与温度对甲烷氧化过程的影响类似,甲烷氧化细菌的丰度也随着温度升高而增加,并与增温幅度、优势甲烷氧化细菌的原位生长温度密切相关。土壤中的II型甲烷氧化细菌对温度较敏感,随着温度升高,II型甲烷氧化细菌丰度增加,因此,温度会通过影响甲烷氧化细菌的丰度和群落结构,从而影响甲烷氧化过程。但温度是否仅通过调控优势菌种更替来改变土壤甲烷氧化能力目前还尚未定论,未来需要进一步探究。本文讨论了土壤甲烷氧化过程对温度的响应及其微生物机制,可为全面解析全球变暖下的土壤甲烷氧化过程的变化提供参考。     

水稻物质生产对稻田甲烷排放的影响

以研究水稻物质生产对稻田甲烷排放影响为目的的大田与盆栽试验于１９９４￣１９９５年在美国德克萨斯州进行。对同期观测的稻田甲烷排放量与水稻干物质积累资料的分析表明,在类似的气候,土壤及水稻栽培管理条件,稻田甲烷排放的季节总量随水稻生产力水平的提高而增加;甲烷日排放通量与水稻干物质积累呈正相关,水稻生长中,后期的物质生产对甲烷排放的贡献大于前期。     

氮肥对土壤氧化甲烷的影响研究

阐述了N肥用量、品种对土壤氧化甲垸(CH_4)的影响以及高浓度CH_4对这一影响的反作用,土壤可通过固定一定量的外源N确保土壤具有相对稳定的氧化大气CH_4能力,N含量低的土壤适量施用N肥可刺激甲烷氧化菌繁殖和功能的发挥,促进大气CH_4氧化。但当外源N用量超出一定范围时甲烷氧化菌Type Ⅰ对环境变化十分敏感,会产生抑制作用并表现为长期和短期2种效应,铵态氮具有短期更具长期效应,其直接结果是引起土壤中甲炕氧化菌尤其是Type Ⅰ数量的减少和作用的减弱,该抑制作用是单向、不可逆的。由于甲烷氧化菌Type Ⅰ和Ⅱ可被高浓度CH_4激活,不易受N肥的长期影响,有些水田土壤施用N肥甚至促进甲烷氧化菌繁殖,即N的影响是双向且可逆的。     

水肥管理对稻田土壤甲烷和氧化亚氮排放的影响

就稻田水肥管理以甲烷和氧化亚氮排放的影响研究进行了综述，文章分析表明，甲烷和氧化亚氮的排放条件存在明显的反位关系，即有利于甲烷排放的水分条件往往不利于氧化亚氮的排放，稻田温室气体的排放与水分管理的历史有明显的关系，不同的肥料施用对甲烷和氧化亚氮排放影响的机制不同。因此，要真正有效地控制温室气体的排放必须首先弄清甲烷和氧化亚氮在不同条件下的排放关系。     

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。     

土壤质地、温度和Eh对稻田甲烷排放的影响

本文报道在田间条件下,土南地,温度和Ｅｈ影响稻田ＣＨ４排放通量的研究结果。中国科学院封丘生态试验站的小区试验表明,在当地常规水分管理即间歇灌溉条件下,供试小区和妥田的ＣＨ４平均排放通量仅为０．１６－１．８６ｍ ｇＣＨ４／ｍ＾２ｈ。     

封闭系统水稻土甲烷氧化的模拟

Methane oxidation by paddy soils in a closed system could be simulated by the equation x=k1xo/(k1 k2x0)exp(k2t)-k2x0 where x0 and x are the CH4 concentrations at time zero and t,respectively;k1 and k2 are constants related to the constant of first-order-kinetics.According to the equation the change of soil ability to oxidize CH4 could be estimated by the equation Ac=k2/k1(x0-x)x0k2/k1-1.The results showed that the soil ability to oxidize CH4 varied,depending on the initial CH4 concentration.High initial CH4 concentration stimulated soil ability to consume CH4,while low concentration depressed the ablility.This characteristic of paddy soil seemed to be of considerable significance to self-adjusting CH4 emission from flooded rice fields if there exist oxic microsites in the soil.     

水分状态、土壤类型和氮素种类对氧化亚氮和甲烷排放的影响

Specific management of water regimes, soil and N in China might play an important role in regulating N2O and CH4 emissions in rice fields. Nitrous oxide and methane emissions from alternate non-flooded/flooded paddies were monitored simultaneously during a 516-day incubation with lysimeter experiments. Two N sources （^15N-（NH4）2SO4 and ^15N-labeled milk vetch） were applied to two contrasting paddies： one derived from Xiashu loess （Loess） and one from Quaternary red clay （Clay）. Both N2O and CH4 emissions were significantly higher in soil Clay than in soil Loess during the flooded period. For both soil, N2O emissions peaked at the transition periods shortly after the beginning of the flooded and non-flooded seasons. Soil type affected N2O emission patterns. In soil Clay, the emission peak during the transition period from non-flooded to flooded conditions was much higher than the peak during the transition period from flooded to non-flooded conditions. In soil Loess, the emission peak during the transition period from flooded to non-flooded conditions was obviously higher than the peak during the transition period from non-flooded to flooded conditions except for milk vetch treatment. Soil type also had a significant effect on CH4 emissions during the flooded season, over which the weighted average flux was 111 mg C m^-2 h^-1 and 2.2 mg C m^-2 h^-1 from Clay and Loess, respectively. Results indicated that it was the transition in the water regime that dominated N2O emissions while it was the soil type that dominated CH4 emissions during the flooded season. Anaerobic oxidation of methane possibly existed in soil Loess during the flooded season.     

生物炭与氮肥对稻田甲烷氧化菌和产甲烷菌数量和潜在活性的影响

基于稻田中氮肥配施生物炭的田间定位试验,研究了施用生物炭与氮肥对旱季稻田土壤理化性质、甲烷氧化与产生潜势及甲烷氧化菌和产甲烷菌丰度的影响。田间试验共设置5个处理：单施生物炭、单施氮肥、氮肥配施生物炭（生物炭设置两个水平）以及对照。结果表明：施用生物炭三年后显著提高了有机碳和微生物生物量碳含量（p﹤0.05）,与单施氮肥处理相比,氮肥配施生物炭后可显著提高土壤pH。与对照相比,单施生物炭显著提高土壤甲烷氧化潜势。在施氮条件下,甲烷氧化潜势与生物炭施用量之间存在正相关关系,与氮肥配施20 t hm-2处理相比,40 t hm-2生物炭处理甲烷氧化潜势增长53.8%。氮肥配施高倍生物炭与配施低倍生物炭处理相比产甲烷潜势由0.001提高至0.002 mg kg-1 h-1;氮肥施用一定程度上抑制了甲烷氧化菌数量的增长,单施氮肥处理中产甲烷菌数量较对照处理显著增加了3.0%;单施或配施低水平生物炭显著增加土壤甲烷氧化菌数量。氮肥显著降低了甲烷氧化菌与产甲烷菌基因丰度比（pmoA/mcrA）。而在同氮肥水平下施加生物炭显著增加了土壤pmoA/mcrA比值,即生物炭对甲烷氧化菌的促进作用显著高于产甲烷菌,提高了旱季稻田土壤的甲烷氧化能力,因此有助于减少稻田土壤甲烷的排放。     

生物质炭提高稻田甲烷氧化活性

为了揭示生物质炭输入对稻田根际土壤产甲烷和甲烷氧化活性的影响,该文通过1a 的田间试验,研究了2种原料制备的生物质炭（竹炭和水稻秸秆炭）对水稻根际土壤产甲烷和甲烷氧化活性的影响。结果表明,2种生物质炭因理化性质的不同,对水稻根际土壤产甲烷活性和甲烷氧化活性的影响存在较大差别。秸秆炭的输入可以显著提高水稻苗期根际土壤产甲烷活性,而竹炭在水稻的整个生长期对根际土壤产甲烷活性均没有显著性影响。竹炭和秸秆炭不稳定易降解组分含量的差异,使其对稻田土壤产甲烷微生物产生不同程度的影响,进而导致稻田根际土壤产甲烷活性响应差别。除抽穗期竹炭处理和成熟期秸秆炭处理,尿素施加并未显著改变生物质炭对根际土壤产甲烷活性的影响趋势。在水稻整个生长期,秸秆炭和竹炭对稻田土壤甲烷氧化活性都有促进作用,但只有秸秆炭在苗期和成熟期表现出显著性的差异。尿素对苗期和抽穗期根际土壤甲烷氧化活性有促进作用。与竹炭相比,秸秆炭输入在改善土壤通气条件、提高土壤pH值和电导率EC、以及K、P元素含量等方面更为有效,同时可能是秸秆炭对水稻根际土壤甲烷氧化活性产生显著性促进作用的潜在机理。     

Effects of different application timings of methane fermentation digested liquid to paddy plots on soil nitrogen and rice yield

Treatment of animal and food wastes using a methane fermentation technique is drawing considerable public attention as a suitable option for the utilization of biomass resources. The application of a fermentation byproduct (methane fermentation digested liquid) as an agricultural fertilizer has been investigated. Determining the appropriate timing required for applying digested liquid on a rice (Oryza sativa L.) paddy plot is important. The concentrations of soil nitrogen (N) components and rice yield should be considered because digested liquid contains both inorganic and organic N. This study compares the N transformation and the rice yield and growth at different application times over a period of 3 y. The effects of the timing of basal application on soil N were different and the timing that maximized the rice yield was different in each year. Days before ponding (DBP) affected soil N before mid-summer drainage, and rice growth rates at the panicle formation stage and the ear emergence stage. The effects of DBP disappeared before harvest. The results indicated that sufficient potentially mineralizable N existed regardless of DBP, and the effect of DBP lessened after the mid-summer drainage, which coincides with the period when N uptake is most active.     

水稻田中氮肥损失研究进展

综述了水稻田中氮肥损失及减少氮肥损失的措施。主要涉及稻田中氮肥的损失途径、损失程度、测试方法及减少氮肥损失的主要措施。这些措施有实施生态农业政策、优化氮肥管理,包括确定适宜的施氮量,氮肥深施,根据水稻生育期需肥特点合理运筹,平衡施肥,控施(缓施)肥料的应用等。     

土壤含水率和含盐量对盐渍土甲烷吸收能力的影响

甲烷（CH4）是一种强效温室气体,准确认识特定类型土壤CH4源汇特征及影响因子调控作用,对于提升土壤CH4吸收潜力以减缓全球气候变化具有重要意义。该研究以盐渍土为研究对象,在土壤室内培养试验中,设置了3个土壤含水率处理,分别为田间持水率（Field Capacity,FC）的50%（50%FC）,75% FC和100% FC,并在每个含水率下设置了6个含盐量处理,电导率分别为0.3、1.0、2.0、3.2、4.9和6.2 dS/m,研究不同土壤含水率和含盐量条件下盐渍土CH4吸收特征。在田间测坑试验中,观测了0.3、1.0和5.0 dS/m 3种含盐量土壤的CH4吸收特征及其对水分动态的响应。室内土壤培养试验结果表明,100%FC下6种盐分水平土壤CH4累积吸收量分别是75%FC下的1.08～1.39倍和50%FC的1.27～1.72倍,表明在田间持水率范围内,含水率升高促进了土壤CH4吸收;在3种含水率下,土壤CH4累积吸收量均随着处理含盐量升高而降低,6.2 dS/m最高含盐量处理的CH4累积吸收量相比0.3 dS/m最低含盐量处理显著降低了42.6%、52.3%和55.1%（P<0.05）;相比50%FC,100%FC含水率下高含盐量对土壤CH4吸收具有更强的抑制作用,土壤含水率和含盐量对CH4吸收的影响存在显著的交互作用。田间测坑试验在野外田间条件下进一步验证了室内培养试验的结果,试验观测期内所有含盐量处理土壤CH4吸收速率均与土壤含水率呈显著正相关关系（P<0.01）;1.0和5.0 dS/m含盐量处理的累积CH4吸收量分别为0.3 dS/m非盐渍土处理的82.6%和59.8%,高含盐量抑制了土壤对CH4的吸收。研究结果表明盐渍土是CH4的汇,并受到土壤含水率和含盐量显著影响,在盐渍土开发利用中应考虑通过合理的水盐调控以提高土壤CH4汇的能力。     

化肥有机肥配合施用下双季稻田氮素形态变化

为揭示有机无机肥配合施用下稻田氮素的动态及迁移特征,在湘南双季水稻农作区第四纪红土发育的红黄泥稻田上进行了连续6年田间试验。通过比较不施氮肥（PK）、施用有机肥猪粪（M）、化肥（NPK）及有机肥化肥配合（NPKM）,研究稻田表层全氮、无机氮动态变化,不同层次（25—30、55—60、85—90 cm）土壤溶液无机氮动态,耕层土壤无机氮动态等。结果表明,NH4+-N是红壤双季稻田无机氮素存在的主要形态,施用化学肥料处理（NPK）施肥后1～3 d表面水NH4+-N浓度占全氮比例可达0.5～0.9,有机肥处理（M）为0.3左右。不同层次土壤溶液及其土壤氮素浓度呈现一致的特征,即施肥后短期内出现浓度峰值随后迅速下降,且随着往下推移,氮素峰值出现时间延长,表层水全氮及无机氮在施肥后1～2 d出现浓度高峰,耕层土壤及25—30 cm土壤溶液无机氮浓度高峰约在施肥后3～5 d。化肥有机肥配施有利于水稻稳产高产,年产量达12.2 t/hm2,比不施氮肥的对照产量（7.3 t/hm2）增加68%;土壤有机质6年提升18.5%,显著高于化肥。施用有机肥（M）及有机无机肥配合（NPKM）显著降低了稻田表层水全氮及不同层次土壤溶液和耕层土壤NH4+-N峰值浓度,提高水稻产量和培肥土壤,有利于减少当前氮肥过量施用带来的环境负荷。     

氮肥对水田与旱地烤烟烟叶氮浓度和相关酶活性的影响

试验采用裂区设计,以硝态氮和铵态氮两种氮素形态为主处理,5个供氮水平为副处理,在大田条件下研究了水田与旱地烤烟在团棵、旺长、脚叶采烤、腰叶采烤和顶叶采烤等5个生育期烟叶的总氮浓度、硝酸还原酶和谷酰胺合成酶活性的氮肥效应。结果表明,水田与旱地烤烟在各氮肥处理下团棵期烟叶的氮浓度最高,旺长期稍有下降,至脚叶采烤期则迅速降低;烟叶中的硝酸还原酶和谷酰胺合成酶活性从团棵到旺长期迅速升高,进入采烤后逐渐降低。水田烤烟烟叶总氮浓度和硝酸还原酶活性比旱地烤烟大,而谷酰胺合成酶则水田小于旱地,说明烤烟在水田状况下吸氮能力比旱地烤烟强;然而水田烤烟氮同化能力比旱地烤烟弱。试验结果还表明,水田与旱地烤烟烟叶的总氮浓度、硝酸还原酶和谷酰胺合成酶活性分别在09～0.kg/hm2和07～5.kg/hm2范围内随施氮量的增加而提高;由于土壤中铵态氮的转化与硝态氮淋溶损失,导致铵态氮的肥效优于硝态氮。     

Effect of nitrogen fertilization on methane flux in a structured clay soil cultivated with onion in Central Hokkaido,Japan

Abstract

This study was conducted to investigate the effect of N fertilization on the soil CH₄ flux during the growing season of onion in a structured clay soil with stagnant water at depths of 70–80 cm and with a peat-mixed subsoil. The following 4 treatments were analyzed over a period of two years: T1) fertilized, onion growing, T2) fertilized, bare field, T3) unfertilized, onion growing, and T4) unfertilized, bare field. In the fertilized T1 and T2 treatments, fertilizers (mixture of 3 : 1 NH₄NO₃ : (NH₄)₂SO₄) at rates of 322 kg N ha^?1 in 1999 and 242 kg N ha^?1 in 2000 were applied as basal fertilizers before onion was transplanted. CH₄ fluxes among the treatments ranged from ?0.06 to 0.12 mg CH₄-C m^?2 h^?1 in 1999, and from ?0.03 to 0.01 mg CH₄-C m^?2 h^?1 in 2000, which were high after heavy rain in summer. Cumulative CH₄ flux from May to November in the fertilized T1 and T2 treatments was 59 mg CH₄-C m^?2 for both treatments in 1999, and 3.2 and ?0.9 mg CH₄-C m^?2 in 2000, respectively. On the other hand, in the unfertilized T3 and T4 treatments, the cumulative CH₄ flux was 0.2 and ?9.2 mg CH₄-C m^?2 in 1999, and ?26 and ?20 mg CH₄-C m^?2 in 2000, respectively. Although the cumulative CH₄ flux in each treatment was higher in 1999 than in 2000, the fertilized treatments in both years showed a significantly higher cumulative CH₄ flux than the unfertilized treatments. This might be ascribed to the higher level of nitrification in the fertilized treatments, because a high nitrate concentration was observed in the fertilized treatments in the onion growing season. The results also revealed that onion growing did not exert a significant influence on the CH₄ flux. The precipitation from May to November was 642 mm in 1999 and 1,008 mm in 2000, and the CH₄ emission increased when the precipitation was low. In addition, the CH₄ concentration in the soil profile increased with the increase of the depth in summer as the soil was dry. These findings indicated that CH₄ diffusion from the soil to the atmosphere was inhibited by rainwater.     

有机肥与化肥不同比例配施下水稻土铵态氮释放特征

采用淹水密闭培养-间歇淋洗法,研究了有机肥(猪粪和牛粪)与化肥(尿素)氮以不同比例配施后对水稻土铵态氮释放特征的影响。结果表明:与单施100%尿素处理相比,培养到28 d,配施有机肥处理(除80%尿素氮配施20%牛粪氮、70%尿素氮配施30%牛粪氮和50%尿素氮配施30%牛粪氮处理)显著降低土壤铵态氮的累积释放量,且随有机肥配施比例的增加降幅增大,降低幅度为5.78%~41.20%(P0.05);培养28~90 d,配施有机肥处理(50%尿素氮配施30%牛粪氮处理除外)的土壤铵态氮释放量显著提高;至培养90 d,50%尿素氮配施50%猪粪氮和80%尿素氮配施20%牛粪氮处理的土壤铵态氮累积释放量显著高于单施100%尿素处理,提高幅度分别为4.81%和9.32%(P0.05)。培养结束时,氮素减施20%(单施80%尿素氮、50%尿素氮配施30%猪粪氮和50%尿素氮配施30%牛粪氮)处理的土壤铵态氮累积释放量与单施100%尿素处理无显著差异。本研究表明,50%尿素氮配施30%猪粪氮既可以降低土壤铵态氮前期释放速率,又可以增加水稻土持续稳定的供氮能力,对减少氮肥损失维持作物生产具有重要意义。