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1.
耕作措施对温带半干旱地区土壤温室气体(CO2、CH4、N2O)通量的影响 总被引:4,自引:1,他引:3
通过设置在甘肃省定西市李家堡镇的不同耕作措施试验, 利用CO2分析仪、静态箱-气相色谱法对双序列轮作次序下春小麦地、豌豆地生育期内CO2、CH4和N2O通量进行了测定。试验结果表明: 4种耕作措施下春小麦地和豌豆地在生育期内均表现为CO2源、N2O源和CH4汇的功能。传统耕作不覆盖、免耕不覆盖、免耕秸秆覆盖和传统耕作结合秸秆还田下, 春小麦生育期内平均土壤CO2通量(μmol·m-2·s-1)分别为0.203 6、0.221 2、0.241 8、0.224 9, CH4通量(mg·m-2·h-1)分别为-0.041 6、-0.078 0、-0.081 8、-0.053 7, N2O通量(mg·m-2·h-1)分别为0.089 1、0.069 2、0.046 1、0.065 6; 豌豆生育期内平均土壤CO2通量(μmol·m-2·s-1)分别为0.273 6、0.261 6、0.218 1、0.236 0, CH4通量(mg·m-2·h-1)分别为-0.055 0、-0.073 7、-0.066 2、-0.054 5, N2O通量(mg·m-2·h-1)分别为0.123 4、0.084 7、0.080 6、0.035 0。少免耕及小麦秸秆覆盖有利于减少土壤CO2排放通量, 免耕不覆盖、免耕秸秆覆盖及传统耕作结合秸秆还田均能不同程度地增加CH4吸收通量、减少N2O排放通量。综合来看, 免耕不覆盖、免耕秸秆覆盖和传统耕作结合秸秆还田3种保护性耕作措施有助于减少土壤温室气体的排放量。春小麦地CO2通量随着土壤温度、土壤含水量的逐渐升高而增大; CH4吸收通量随着土壤含水量的逐渐升高而增大, 而随着土壤温度的逐渐升高而减小。豌豆地CO2通量的变化与土壤含水量存在极显著正相关关系; 而春小麦地N2O通量则与平均土壤温度呈显著正相关, 豌豆地则为极显著正相关。 相似文献
2.
施氮水平对太行山前平原冬小麦-夏玉米轮作体系土壤温室气体通量的影响 总被引:10,自引:4,他引:6
应用静态明箱-气相色谱法对4 个施氮肥水平N0 [0 kg(N)·hm-2]、N200 [200 kg(N)·hm-2]、N400 [400kg(N)·hm-2]、N600 [600 kg(N)·hm-2]的夏玉米-冬小麦季轮作体系2008~2010 年的土壤温室气体(CH4、CO2 和N2O)排放通量进行研究, 同时观测5 cm 土层土壤温度并记录降水量。结果表明: 太行山前平原冬小麦-夏玉米轮作农田生态系统为CH4 吸收汇, CO2 和N2O 排放源。随着氮肥施入量的增加土壤对CH4 的吸收速率降低, 而CO2 和N2O 的排放速率增加。冬小麦季施氮处理土壤对CH4 的吸收速率显著低于无氮肥的N0 处理, 而N600处理土壤CO2 和N2O 排放速率显著高于N0 处理(P<0.05)。施肥和灌溉会直接导致土壤CO2 和N2O 的排放通量增加, 同时土壤对CH4 的吸收峰值减小。土壤温度升高和降水量增加以及干湿交替加剧均会造成N2O 和CO2排放速率增加。同时在持续干燥和低温条件的冬季不施氮处理观测到土壤对N2O 的吸收现象。N0、N200、N400 和N600 处理土壤CH4 年排放总量(kg·hm-2·a-1)分别为-1.42、-0.75、-0.82、-0.92(2008~2009 年)和-2.60、-1.47、-1.35、-1.76(2009~2010 年), N0、N200、N400 和N600 处理土壤CO2 年排放总量(kg·hm-2·a-1)分别为15 597.6、19 345.6、21 455.9、29 012.5(2008~2009 年)和10 317.7、11 474.0、13 983.5、20 639.3(2009~2010年), N0、N200、N400 和N600 处理土壤N2O 年排放总量(kg·hm-2·a-1)分别为1.05、2.16、5.27、6.98(2008~2009年)和1.49、2.31、4.42、5.81(2009~2010 年)。 相似文献
3.
夏季休牧对高寒矮嵩草草甸温室气体排放的影响 总被引:2,自引:0,他引:2
以高寒矮嵩草草甸为研究对象,利用密闭箱-气相色谱法,对夏季休牧8a的围栏草地(休牧草地)和全年放牧的草地(放牧草地)的温室气体排放通量、土壤特性和生物量进行了对比研究。结果表明:与放牧草地相比,休牧草地植被盖度较之高41%,单位面积生物量较之高53%。同时,土壤特性也有较大不同;休牧草地的植被-土壤系统CO2排放通量比放牧草地低20.7%,测定期间两者CO2排放通量以每天每公顷排放C的质量计分别为30.7和38.7 kg·(hm2·d)-1;试验期间高寒矮嵩草草甸植被-土壤系统是大气CH4的弱汇,休牧后草地土壤对CH4的吸收能力增强,休牧和放牧草地CH4的平均吸收强度分别为28.1和21.9 g·(hm2·d)-1;休牧草地土壤N2O排放通量比放牧草地低,两者排放通量分别为4.5和7.6 g·(hm2·d)-1。可见,夏季休牧措施降低了草地对大气中温室气体浓度增加的贡献。 相似文献
4.
气候变化通过大气CO2浓度、温度和降雨的改变,直接或间接影响农田温室气体排放,研究未来气候情景下农田温室气体排放对实现农业碳减排具有重要意义。为探究气候变化背景下农田温室气体排放特征,该研究在长期田间定位试验基础上,利用当前大气CO2浓度与CO2浓度升高条件下旱作玉米农田温室气体排放通量的田间观测数据,采用“试错法”对DayCent模型进行校验,并利用校验后的模型,根据第六次国际耦合模式比较计划(Coupled Model Intercomparison Project phase 6,CMIP6)气候情景数据,预测未来SSP126与SSP245气候情景下旱地玉米农田温室气体排放通量。结果表明,DayCent模型对不同大气CO2浓度下N2O、CH4和CO2排放通量的模拟值与观测值高度一致,模拟效率(modeling efficiency,EF)分别为0.58~0.87、0.45~0.65和0.25~0.62,均方根误差(root mean square error,RMSE)分别为0.83~1.33、0.67~0.82和0.58~0.80 g/(hm2·d),决定系数(coefficient of determination,R2)分别为0.80~0.91、0.53~0.80和0.53~0.85。SSP126和SSP245气候情景下,在玉米单作种植模式下旱地农田N2O和CO2年排放量均呈现上升趋势,以2001—2020年农田温室气体排放通量为基准,到2060年N2O年排放量分别增加22.8%和24.9%,CO2年排放量分别增加6.7%和8.0%;旱地农田CH4年吸收量呈下降趋势,两个气候情景下分别减少13.6%和13.4%。未来气候情景下旱地农田仍是温室气体排放源,优化氮肥管理和农田耕作措施对实现温室气体减排具有重要意义,模拟结果可以为制定农业适应气候变化对策提供基础数据支持。 相似文献
5.
生物炭和秸秆还田对干旱区玉米农田土壤温室气体通量的影响 总被引:4,自引:2,他引:2
为了研究生物炭及秸秆还田对干旱区玉米农田温室气体通量的影响,以内蒙古科尔沁地区玉米农田为试验对象,采用静态箱-气相色谱法对分别施入生物炭0 t·hm-2(CK)、15 t·hm-2(C15)、30 t·hm-2(C30)、45 t·hm-2(C45)及秸秆还田(SNPK)的土壤进行温室气体(CO2、CH4和N2O)通量的原位观测,并估算生长季CH4和N2O的综合增温潜势(GWP)与排放强度(GHGI)。结果表明:添加生物炭能够显著减少土壤CO2和N2O的排放量,并促进土壤对CH4的吸收作用。其中处理C15对CO2的减排效果最好,与对照相比CO2排放量降低21.16%。随着施入生物炭量的增加,生物炭对N2O排放的抑制作用不断增强,处理C45对减排效果最好,与对照相比N2O排放量降低86.25%。处理C15对土壤吸收CH4的促进效果最好,CH4吸收量增加56.62%;处理C45对CH4的排放有促进作用,使生长季土壤吸收CH4减少81.36%。SNPK对温室气体的减排作用接近处理C15。添加生物炭和秸秆还田对提高玉米产量和降低农田GWP与GHGI均有显著效果,施用生物炭及秸秆还田均有效提高了科尔沁地区的玉米产量,且玉米产量随着施入生物炭含量的增大而提升。从GWP上来看,施用15 t·hm-2生物炭对温室气体减排的整体效果最好。从GHGI上来看,施用生物炭及秸秆还田均具有一定的经济效益和减排意义,其中施用15 t·hm-2生物炭的综合效益最高。因此综合经济效益与环境因素,建议科尔沁地区农田在种植玉米时添加15 t·hm-2生物炭,如不具备购买生物炭条件,可以考虑秸秆还田来实现玉米增产与温室气体减排。 相似文献
6.
减量施氮与大豆间作对蔗田土壤温室气体排放的影响 总被引:3,自引:2,他引:1
采用静态箱 气相色谱法对常规施氮(N2, 525 kg·hm-2)y和减量施氮(N1, 300 kg·hm-2)处理下甘蔗与大豆按行数比1∶1(SB1)和1∶2(SB2)间作、甘蔗单作(MS)、大豆单作(MB)种植模式下蔗田土壤CO2、N2O、CH4排放通量及土地当量比(LER)进行观测和对比分析, 以探讨不同间作模式及施氮水平下甘蔗//大豆间作农田土壤温室气体排放的动态变化规律及对作物产量的影响, 为制定农田温室气体减排措施提供合理的依据。研究结果表明, 减量施氮处理甘蔗//大豆(1∶2)间作模式(SB2-N1)农田土壤CO2排放总量较甘蔗单作(MS)显著降低35.58%, N2O累积排放总量较甘蔗单作降低56.36%, CH4累积排放总量较甘蔗单作升高7.02%; 不同种植模式和施氮处理蔗田土壤均表现为CO2和N2O的排放源, CH4吸收汇, 追施氮肥后土壤对CH4的吸收速率降低, 但CO2和N2O的排放速率增加。MS-N1、SB1-N1、SB2-N1、MS-N2、SB1-N2、SB2-N2和MB处理土壤CO2年累积排放总量(kg·hm-2·a-1)分别为5 096.89、6 422.69、3 283.20、4 103.29、4 475.84、4 775.31和4 780.35, 土壤N2O年累积排放总量(kg·hm-2·a-1)分别为4.61、5.11、2.15、3.13、3.72、5.60和3.11, 土壤CH4年累积排放总量(kg·hm-2·a-1)分别为 13.68、 21.78、 12.72、 5.53、 11.36、 4.77和 9.97。甘蔗//大豆间作系统2009-2012年土地当量比(LER)均大于1, 且减量施氮水平下, 甘蔗//大豆(1∶2)间作模式优势最明显。 相似文献
7.
堆放奶牛粪便温室气体排放及影响因子研究 总被引:4,自引:7,他引:4
用静态箱—气相色谱法对两种不同堆放方式的奶牛粪便(自然堆放和覆盖玉米秸秆)在4个不同时段的温室气体排放速率进行了观测,结果表明:各个时段两种处理的温室气体排放速率变化趋势基本一致,但各个时段的排放速率有明显差异。两种处理温室气体的排放速率与牛粪温度相关极显著。覆盖玉米秸秆会减少CO2、N2O的排放,而且第3时段(2006年5月14日~6月14日)CO2的排放速率和第4时段(2006年8月2日~8月30日)N2O的排放速率与自然堆放的均差异显著;不同时段覆盖对CH4的排放影响不同,第4时段覆盖处理的CH4排放速率上升,并且与自然堆放的差异显著;其他时段两种处理温室气体的排放速率无显著差异。 相似文献
8.
探讨有机物料还田对冬小麦田温室气体排放特性的影响,对提高经济效应和环境效应有积极意义。本研究应用静态箱-气相色谱法对秸秆还田(J)、秸秆还田+牛粪(JF)和秸秆还田+菌渣(JZ)3种有机物料还田下分别施氮肥243 kg (N)·hm-2(减氮10%,N1)、216 kg (N)·hm-2(减氮20%,N2)对冬小麦农田N2O、CO2和CH4的排放通量进行监测,探讨了不同施肥措施对麦田温室气体累积排放量、增温潜势的影响。试验期间同步记录每项农事活动机械燃油量、施肥量和灌溉量,测定产量,地上部生物量,估算农田碳截留。结果表明,冬小麦农田土壤N2O和CO2是排放源,是CH4的吸收汇,氮肥施入、灌溉以及强降水促进了土壤N2O和CO2的生成,却弱化了CH4作为大气吸收汇的特征。牛粪+秸秆(JF)处理N2O和CO2排放总量最高,分别为3.5 kg (N2O-N)·hm-2和19 689.67 kg (CO2-C)·hm-2,但CH4的吸收值最大,为5.33 kg (CH4-C)·hm-2,均显著高于菌渣+秸秆(JZ)和秸秆(J)处理(P<0.05);各处理N2O和CO2的总量随施氮量的增加呈升高趋势,CH4的总量随施氮量的增加而呈降低趋势。JFN2、JN2和JZN2处理农田综合增温潜势(GWP)均为负值,表明有机物料还田且减氮20%条件下农田生态系统为大气的碳汇,麦季净截留碳1 038~2 024 kg·hm-2,其他处理GWP值均为正。JZN2处理小麦产量为8 061 kg·hm-2,显著高于JFN2处理(P<0.05)。综上所述,JZN2处理不仅能够保证小麦产量,且对环境效应最有利,为本区域冬小麦较优的施肥管理模式。 相似文献
9.
不同施肥处理稻田甲烷和氧化亚氮排放特征 总被引:48,自引:14,他引:48
采用静态箱-气相色谱法对长期不同施肥处理(NPKS、CK、NPK和NKM)的稻田CH4和N2O排放进行了观测。结果表明,稻田CH4和N2O排放季节变化规律明显不同,二者排放通量季节变化呈显著负相关(p<0.01)。与单施化肥和CK相比,施用有机肥显著促进CH4排放,排放量最高的NPKS处理早晚稻田排放量分别是:526.68 kg/hm2和1072.92 kg/hm2。对于N2O排放,早稻田各处理间差异不显著,NPK处理排放量最大,为1.48 kg/hm2;晚稻田各处理差异极显著(p<0.01),NPKS处理排放量最大,为1.40 kg/hm2。晚稻田CH4排放通量和10 cm土层温度及土壤pH值相关极显著(p<0.01),并与二者存在显著的指数关系。没发现N2O排放通量与温度及pH值间存在显著相关。稻田CH4和N2O排放受多种因素影响,但对全球变暖的贡献率CH4远大于N2O。NPKS处理的增温潜势最大,NPK处理的最小。 相似文献
10.
不同耕作措施下豆麦双序列轮作农田温室气体的排放特征及其增温潜势 总被引:4,自引:0,他引:4
基于甘肃农业大学在定西市李家堡镇开展的保护性耕作长期定位试验,采用CO2分析仪、静态箱-气相色谱法对2011年度不同耕作措施下豆麦双序列轮作农田土壤CO2和N2O的排放通量进行全年连续观测。结果表明:测定期内不同耕作措施下豆麦双序列轮作农田土壤均表现为CO2源和N2O源;免耕不覆盖有利于降低两个序列土壤的CO2排放通量,免耕秸秆覆盖、免耕不覆盖和传统耕作+秸秆还田三种保护性耕作处理不同程度的减少了两个序列土壤的N2O排放通量;两个序列下CO2的相对增温潜势最大,W→P→W序列传统耕作+秸秆还田处理对温室效应贡献最多,相反免耕不覆盖处理能相对减少温室气体排放量,从而降低温室效应;P→W→P序列传统耕作不覆盖处理对温室效应的贡献最大,传统耕作+秸秆还田处理对温室效应贡献最小,对温室气体有减排效应。 相似文献
11.
耕作方式转变对冬小麦季农田温室气体排放和产量的影响 总被引:5,自引:0,他引:5
合理耕作方式对农业可持续生产和减缓全球气候变化有重要意义。为评价耕作方式转变对农田温室气体排放的影响,本研究针对连续16年的长期旋耕小麦/玉米农田进行不同的轮耕处理,采用原位静态箱-气相色谱法分析了小麦季农田土壤3种温室气体CH_4、CO_2、N_2O排放规律。试验共设3个处理:在前期旋耕基础上分别进行翻耕处理(XF)和深松处理(XS),另外保持旋耕(X)作为对照。试验结果表明:CO_2排放通量在耕作后1周有明显排放峰,XF处理显著低于X和XS处理;N_2O排放通量在耕作和灌溉施肥后有明显排放峰,XS处理显著高于XF和X处理;两种气体排放通量在越冬期出现最低值。CH_4从耕作后到越冬期有持续明显的吸收过程,其中XS处理的吸收通量显著高于XF和X处理。农田土壤在冬小麦生长季表现为CO_2的源,累积排放量为XS(5 241 kg·hm~(-2))X(5 160 kg·hm~(-2))XF(4 840 kg·hm~(-2)),XS与X处理间差异不显著,均显著高于XF;N_2O的源,累积排放量表现为XS(4.38 kg·hm~(-2))XF(2.39 kg·hm~(-2))X(2.26 kg·hm~(-2)),XS与XF处理间差异不显著,均显著高于X处理;CH_4的汇,累积吸收量为XS(6.14 kg·hm~(-2))XF(5.64 kg·hm~(-2))X(3.70 kg·hm~(-2))。将累积温室气体换算为CO_2当量,对增温效应的贡献表现为XF(5.32 t·hm~(-2))X(5.66 t·hm~(-2))XS(6.23 t·hm~(-2)),三者之间差异达显著水平。经翻耕处理后,0~10 cm土壤有机质含量明显低于X处理,而10~20 cm土壤有机质升高,表层有机质降低可能是翻耕处理CO_2的排放减少的主要原因。不同耕作处理后小麦产量差异明显,X处理冬小麦产量最高,且显著高于XS处理,XF处理与X和XS处理差异均不显著。综合考虑耕作方式对温室气体排放和冬小麦产量的影响,短期内旋耕-翻耕可能是较适宜的轮耕模式,旋耕深松模式不利于控制温室气体排放,但未来需要加强对不同轮耕模式长期效应研究。 相似文献
12.
不同秸秆还田年限对稻麦轮作系统温室气体排放的影响 总被引:4,自引:0,他引:4
为揭示稻麦轮作系统不同秸秆还田年限下温室气体排放特征及减排调控机制,本研究采用大田小区试验,考察了稻麦轮作不同秸秆还田年限[空白对照(CK)、常规处理秸秆不还田(NT)、1年秸秆还田(SR1)和5年秸秆还田(SR5)]对CH4、CO2和N2O 3种温室气体排放规律的影响,同时测定了土壤固碳量,估算了秸秆焚烧产生的温室气体排放量,综合计算了4种处理对全球变暖的贡献。试验结果表明,SR1和SR5均显著提升CH4和CO2的排放通量,分别高出NT、CK处理73.52%、309.49%和13.29%、13.06%;同时显著降低N2O排放通量,较NT降低29.68%和42.55%;但SR1和SR5之间温室气体排放通量差异不显著;与NT相比,SR1和SR5可以显著提高土壤固碳量517.9%和709.03%,SR5土壤固碳量高出SR1达30.93%;NT秸秆焚烧产生的全球气温变暖贡献为9 698.49 kg(CO2-eqv)·hm?2,比CK高126.98%。综合分析温室气体排放、土壤固碳以及秸秆焚烧3个因素,SR1全球升温贡献最低,显著低于NT 4.72%。短期全量秸秆还田有助于降低总体温室气体排放,长期进行秸秆还田后降低幅度会逐步减小。 相似文献
13.
《Land Degradation \u0026amp; Development》2017,28(2):673-681
Agricultural activities emit greenhouse gases (GHGs) and contribute to global warming. Intensive plough tillage (PT), use of agricultural chemicals and the burning of crop residues are major farm activities emitting GHGs. Intensive PT also degrades soil properties by reducing soil organic carbon (SOC) pool. In this scenario, adoption of no‐till (NT) systems offers a pragmatic option to improve soil properties and reduce GHG emission. We evaluated the impacts of tillage systems (NT and PT) and wheat residue mulch on soil properties and GHG emission. This experiment was started in 1989 on a Crosby silt loam soil at Waterman Farm, The Ohio State University, Columbus, Ohio, USA. Mulching reduced soil bulk density and improved total soil porosity. More total carbon (16.16 g kg−1), SOC (8.36 mg L−1) and soil microbial biomass carbon (152 µg g−1) were recorded in soil under NT than PT. Mulch application also decreased soil temperature (0–5 cm) and penetration resistance (0–60 cm). Adoption of long‐term NT reduced the GHG emission. Average fluxes of GHGs under NT were 1.84 g CO2‐C m−2 day−1 for carbon dioxide, 0.07 mg CH4‐C m−2 day−1 for methane and 0.73 mg N2O‐N m−2 day−1 for nitrous oxide compared with 2.05 g CO2‐C m−2 day−1, 0.74 mg CH4‐C m−2 day−1 and 1.41 mg N2O‐N m−2 day−1, respectively, for PT. Emission of nitrous oxide was substantially increased by mulch application. In conclusion, long‐term NT reduced the GHG emission by improving the soil properties. Copyright © 2016 John Wiley & Sons, Ltd. 相似文献
14.
Carbon sequestration in agricultural soils in the Cerrado region of the Brazilian Amazon 总被引:2,自引:0,他引:2
J.L.N. Carvalho C.E.P. Cerri B.J. Feigl M.C. Píccolo V.P. Godinho C.C. Cerri 《Soil & Tillage Research》2009,103(2):342
The introduction of crop management practices after conversion of Amazon Cerrado into cropland influences soil C stocks and has direct and indirect consequences on greenhouse gases (GHG) emissions. The aim of this study was to quantify soil C sequestration, through the evaluation of the changes in C stocks, as well as the GHG fluxes (N2O and CH4) during the process of conversion of Cerrado into agricultural land in the southwestern Amazon region, comparing no-tillage (NT) and conventional tillage (CT) systems. We collected samples from soils and made gas flux measurements in July 2004 (the dry season) and in January 2005 (the wet season) at six areas: Cerrado, CT cultivated with rice for 1 year (1CT) and 2 years (2CT), and NT cultivated with soybean for 1 year (1NT), 2 years (2NT) and 3 years (3NT), in each case after a 2-year period of rice under CT. Soil samples were analyzed in both seasons for total organic C and bulk density. The soil C stocks, corrected for a mass of soil equivalent to the 0–30-cm layer under Cerrado, indicated that soils under NT had generally higher C storage compared to native Cerrado and CT soils. The annual C accumulation rate in the conversion of rice under CT into soybean under NT was 0.38 Mg ha−1 year−1. Although CO2 emissions were not used in the C sequestration estimates to avoid double counting, we did include the fluxes of this gas in our discussion. In the wet season, CO2 emissions were twice as high as in the dry season and the highest N2O emissions occurred under the NT system. There were no CH4 emissions to the atmosphere (negative fluxes) and there were no significant seasonal variations. When N2O and CH4 emissions in C-equivalent were subtracted (assuming that the measurements made on 4 days were representative of the whole year), the soil C sequestration rate of the conversion of rice under CT into soybean under NT was 0.23 Mg ha−1 year−1. Although there were positive soil C sequestration rates, our results do not present data regarding the full C balance in soil management changes in the Amazon Cerrado. 相似文献
15.
Tjaša Danev?i? Bla? Stres David Stopar Janez Hacin 《Soil biology & biochemistry》2010,42(9):1437-1446
Peatlands play an important role in emissions of the greenhouse gases CO2, CH4 and N2O, which are produced during mineralization of the peat organic matter. To examine the influence of soil type (fen, bog soil) and environmental factors (temperature, groundwater level), emission of CO2, CH4 and N2O and soil temperature and groundwater level were measured weekly or biweekly in loco over a one-year period at four sites located in Ljubljana Marsh, Slovenia using the static chamber technique. The study involved two fen and two bog soils differing in organic carbon and nitrogen content, pH, bulk density, water holding capacity and groundwater level. The lowest CO2 fluxes occurred during the winter, fluxes of N2O were highest during summer and early spring (February, March) and fluxes of CH4 were highest during autumn. The temporal variation in CO2 fluxes could be explained by seasonal temperature variations, whereas CH4 and N2O fluxes could be correlated to groundwater level and soil carbon content. The experimental sites were net sources of measured greenhouse gases except for the drained bog site, which was a net sink of CH4. The mean fluxes of CO2 ranged between 139 mg m−2 h−1 in the undrained bog and 206 mg m−2 h−1 in the drained fen; mean fluxes of CH4 were between −0.04 mg m−2 h−1 in the drained bog and 0.05 mg m−2 h−1 in the drained fen; and mean fluxes of N2O were between 0.43 mg m−2 h−1 in the drained fen and 1.03 mg m−2 h−1 in the drained bog. These results indicate that the examined peatlands emit similar amounts of CO2 and CH4 to peatlands in Central and Northern Europe and significantly higher amounts of N2O. 相似文献
16.
A laboratory investigation was performed to compare the fluxes of dinitrogen (N2), N2O and carbon dioxide (CO2) from no-till (NT) and conventional till (CT) soils under the same water, mineral nitrogen and temperature status. Intact soil cores (0-10 cm) were incubated for 2 weeks at 25 °C at either 75% or 60% water-filled pore space (WFPS) with 15N-labeled fertilizers (100 mg N kg−1 soil). Gas and soil samples were collected at 1-4 day intervals during the incubation period. The N2O and CO2 fluxes were measured by a gas chromatography (GC) system while total N2 and N2O losses and their 15N mole fractions in the soil mineral N pool were determined by a mass spectrometer. The daily accumulative fluxes of N2 and N2O were significantly affected by tillage, N source and soil moisture. We observed higher (P<0.05) fluxes of N2+N2O, N2O and CO2 from the NT soils than from the CT soils. Compared with the addition of nitrate (NO3−), the addition of ammonium (NH4+) enhanced the emissions of these N and C gases in the CT and NT soils, but the effect of NH4+ on the N2 and/or N2O fluxes was evident only at 60% WFPS, indicating that nitrification and subsequent denitrification contributed largely to the gaseous N losses and N2O emission under the lower moisture condition. Total and fertilizer-induced emissions of N2 and/or N2O were higher (P<0.05) at 75% WFPS than with 60% WFPS, while CO2 fluxes were not influenced by the two moisture levels. These laboratory results indicate that there is greater potential for N2O loss from NT soils than CT soils. Avoiding wet soil conditions (>60% WFPS) and applying a NO3− form of N fertilizer would reduce potential N2O emissions from arable soils. 相似文献
17.
水分类型对土壤排放的温室气体组成和综合温室效应的影响 总被引:36,自引:2,他引:34
实验室研究表明,土壤排放出的温室气体(CO2、CH4和N2O)组成及总理显著地受土壤水分类型和施用秸秆的影响。连续淹水条件下,土壤仅排放微理的N2O,但排放出大量的C睡C敢条件下,土壤不排放C上键合的但排放出大量的N2O;虽然淹水的土壤排水促进N2O排放,但显著抑制CH4的排放,淹水好气交替处理的土壤其排放的CO2、CH4和N2O均在好气和连续淹水之间。根据各种温室产生温室效应的相对潜力,计算土壤 相似文献
18.
Yo Toma Shingo Oomori Asuka Maruyama Hideto Ueno Osamu Nagata 《Soil Science and Plant Nutrition》2016,62(1):69-79
Agricultural fields, including rice (Oryza sativa L.) paddy fields, constitute one of the major sources of atmospheric methane (CH4) and nitrous oxide (N2O). Organic matter application, such as straw and organic fertilizer, enhances CH4 emission from paddy fields. In addition, rice straw management after harvest regulates CH4 emissions in the growing season. The interaction of tillage times and organic fertilizer application on CH4 and N2O emissions is largely unknown. Therefore, we studied the effects of fallow-season tillage times and fertilizer types on CH4 and N2O emissions in paddy fields in Ehime, southwestern Japan. From November 2011 to October 2013, four treatments, two (autumn and spring) or one (spring) in the first year, or two (autumn and spring) or three (autumn, winter, and spring) in the second year times of tillage with chemical or organic fertilizer application, were established. Gas fluxes were measured by the closed-chamber method. Increasing the number of tillage times from one to two decreased succeeding CH4 emission and the emission factor for CH4 (EFCH4) in the rice-growing season, suggesting that the substrate for CH4 production was reduced by autumn and spring tillage in the fallow season. Higher EFCH4 [1.8–2.0 kg carbon (C) ha?1 d?1] was observed when more straw was applied (6.9–7.2 Mg ha?1) in the second year. Organic fertilizer application induced higher CH4 emission just after the application as basal and supplemental fertilizers, especially at a lower straw application rate. This indicated that EFCH4 in the organically managed fields should be determined individually. Organic fertilizer application with two tillage times induced N2O efflux during the rice-growing season in the second year, but N2O emissions were not affected by winter tillage. Although paddy fields can act as an N2O sink because of reduced soil conditions when straw application was high, application of organic C and nitrogen as fertilizer can enhance N2O production by the denitrification process during the growing season, especially in the ripening stage when soil anaerobic conditions became moderate. These results suggest that negative emission factors for N2O (EFN2O) can be applied, and EFN2O of organic fertilizer should be considered during the estimation of N2O emission in the paddy field. 相似文献