有机肥与无机肥配施对潮土N2O排放的影响

华北平原是我国重要的粮食主产区,由于土壤有机质含量低,增加氮肥用量并不能导致玉米产量持续增加.有机肥和无机肥配施被广泛认为是同时实现粮食增产和提高土壤有机质的双赢措施,但是有机肥和无机肥配施对华北平原农田N_2O排放的影响尚不明确.本研究在华北平原潮土区,通过测定不同种类有机肥与无机肥配施后农田N_2O排放通量和作物产量,旨在揭示不同种类有机肥及其用量对潮土N_2O排放和作物产量的影响效应.田间试验共设置8个处理,分别为不施肥(CK)、化肥氮(NPK)、 40%牛粪氮+60%化肥氮(CM)、 40%鸡粪氮+60%化肥氮(FC)、 40%猪粪氮+60%化肥氮(FP)、 20%牛粪氮+80%化肥氮(1/2CM)、 20%鸡粪氮+80%化肥氮(1/2FC)和20%猪粪氮+80%化肥氮(1/2FP).整个玉米季N_2O排放通量均与土壤WFPS显著正相关(P0.05).除NPK处理外,玉米季N_2O排放量与土壤可溶性有机碳(DOC)平均含量存在显著的线性关系.玉米季CK处理N_2O排放量为0.50 kg·hm~(-2),NPK处理增加到2.28 kg·hm~(-2).相同用量不同种类有机肥处理,N_2O排放未出现显著差异. 40%有机肥氮用量处理下N_2O排放量与NPK处理无显著差异,而用量减少至20%后, 1/2CM、 1/2FC和1/2FP处理N_2O排放量分别较CM、 FC和FP减少了33.6%、 43.7%和12.1%,其主要原因为易分解有机碳输入减少,土壤DOC含量降低,但玉米产量未出现显著差异.因此,从减少温室效应的角度,玉米季80%化肥氮配施20%有机肥氮为本地区农田施肥的较佳选择.     

华北平原农田管理措施对冬小麦-夏玉米轮作系统N2O和CH4排放的影响

华北平原是我国重要的粮食生产基地,其农业生产对N_2O和CH_4也具有重要影响.本研究设置包括3类不同农田管理措施的田间试验,即免耕(No-tillage,N)/旋耕(Rotary,T)、秸秆清茬(Cleaning,S0)/还田(Straw,S1)以及不同氮肥水平(常规氮肥(F2),优化氮肥(F1)和空白处理(F0)),分析对产量、N_2O和CH_4排放的影响以及与土壤性状的关系.结果表明,优化氮肥能保持和当地常规氮肥水平相同的粮食产量,同时可以有效降低温室气体CO2-eq(45.4%).秸秆还田可以显著降低N_2O的排放,其中在夏玉米季效果尤为明显.施用氮肥能够抑制土壤对CH_4的吸收.夏玉米季是N_2O排放的主要时期(N_2O累积排放占全年的59%~78%).土壤NO-3含量、WFPS和土壤温度都对N_2O有显著影响.主效应和交互作用分析证明,氮肥水平对两季作物产量、秸秆还田对冬小麦的产量有显著影响;耕作方式与氮肥水平、秸秆还田分别对两季作物产量和CH_4有极显著的交互作用,秸秆处理和氮肥水平对CH_4排放和冬小麦产量有显著的交互作用;三因素的交互作用体现在对冬小麦产量和两季作物的总产量有显著影响.在华北平原当前氮肥水平上降低30%仍能维持和当地常规农业管理措施相同的作物产量,降低N_2O和CH_4排放45%以上,秸秆还田体现出降低N_2O排放以及长期提高土壤有机碳水平的效益.     

华北平原玉米-小麦轮作农田N2O交换通量的研究

以华北地区冬小麦-夏玉米轮作农田为研究对象,运用静态箱法对正常施肥及正常施肥结合秸秆还田农田N2O交换通量进行了连续1 a对比研究.正常施肥及正常施肥结合秸秆还田样地N2O全年的累积排放量分别为7.61 kg.hm-2和12.6kg.hm-2,其中秸秆还田引起N2O排放明显增加主要发生在玉米生长季节.两种处理样地在玉米季N2O的排放量占全年累积排放的57%～86%,表明华北玉米-小麦轮作体系中N2O排放主要集中在玉米季.各次施肥后10 d内N2O的累积排放量约占全年总排放量的71%～88%,显然现有化肥极大促进了华北农田N2O排放.     

不同施肥方式下紫色土N2O与NOx的排放特征

利用紫色土长期施肥试验平台,采用静态箱-气相色谱法开展紫色土"冬小麦-夏玉米"轮作系统N_2O和NO_x排放的连续两周年(2014年11月~2016年9月)定位观测.研究了氮肥总量相同条件下的常规氮磷钾化肥(NPK)、猪厩肥(OM)、秸秆还田配施氮磷钾化肥(RSDNPK)、猪厩肥配施氮磷钾化肥(OMNPK)和氮磷钾化肥配合硝化抑制剂(DCDNPK)等施肥方式对N_2O和NO_x排放的影响,短期不施肥处理(CK)作为排放系数计算的对照.结果表明,所有施肥方式下紫色土N_2O排放峰均出现在施肥初期和大降雨过程期;NO_x排放过程与N_2O类似,排放峰出现在施肥初期,但强降雨期未出现明显排放峰.NPK、OM、RSDNPK、OMNPK和DCDNPK处理的N_2O年均累积排放量分别为:1.35、4.38、1.43、2.46、0.92 kg·hm~(-2),排放系数分别为:0.33%、1.41%、0.36%、0.73%、0.18%;相应处理的NO_x年均累积排放量分别为:0.11、0.38、0.10、0.27、0.04kg·hm~(-2),排放系数分别为:0.03%、0.13%、0.03%、0.09%、0.01%.较常规化肥,增加有机物料如施用猪厩肥和猪厩肥配施氮磷钾肥分别显著增加226%和83%的N_2O排放(P0.01),同时NO_x排放分别显著增加262%和157%(P0.01);常规化肥配合硝化抑制剂(DCDNPK)使用减少32%的N_2O排放和62%的NO_x排放(P0.01),秸秆还田配施氮磷钾肥对N_2O排放略有增加(P0.05),NO_x排放略有减少(P0.05).统计分析进一步表明,土壤无机氮含量是N_2O和NO_x二者排放的主控因子,而土壤孔隙充水率与温度分别作为N_2O与NO_x各自排放的主控因子之一.     

Effect of diet manipulation in dairy cow N balance and nitrogen oxides emissions from grasslands in northern Spain

Dietary modifications in dairy cattle have been reported as a useful strategy to alter the composition of manure. Many reports have been published on how changes in dietary crude protein content and forage-to-concentrate ratio reduces animal nitrogen (N) excretion, but little information exists about the effect of diet modification on nitrous oxide (N₂O) and nitric oxide (NO) emission when the subsequent slurry is applied on grassland. Two diets differing in forage:concentrate ratio (high forage or HF diet, 75:25; low forage or LF diet, 55:45) were tested to detect the improvement of N use efficiency in milk and the reduction of urinary and fecal N excretion. Triticale silage and barley grain were used as the main forage and concentrate sources in the diets. The subsequent slurries were characterized for N and ammonium-N content (NH₄⁺-N) and applied on grassland in order to study total and pattern of emission of N₂O and NO.The HF diet reduced the voluntary dry matter intake of the cows, N intake and urinary and fecal N excretion. However, the reduction of N intake did not improve the N use efficiency in milk (NUE) (21.0%) and did not reduce N excretion per unit of milk produced (15 g N l⁻¹) due to the lower milk yield. Slurries were similar in N content but differed in NH₄⁺ content, being lower in HF. Therefore, different slurry amounts were needed to be applied on grassland to reach the correct fertilisation rate (120 kg NH₄⁺-N ha⁻¹). Total emissions of N₂O (5.8 and 5.0 kg N₂O-N ha⁻¹) and NO (507.2 and 568.6 g NO-N ha⁻¹), and the pattern of emissions were not affected by dietary treatments. When fertilisation management depends on the collected volume to empty the slurry pit, higher N₂O and NO emissions per kg of slurry could be expected from LF slurry. Nevertheless, if slurry is applied following recommendation rates, N₂O and NO emission per unit of milk produced might be slightly lower from LF slurry. Grass yield (1.5 t dry matter ha⁻¹) and N uptake (50 kg N ha⁻¹) did not vary due to the applications of different slurries, and was attributed to low rainfalls. The correct management of the slurries on grasslands may justify an adequate nutritional strategy of dairy herds from an environmental and productive point of view.     

施用畜禽粪便堆肥品的蔬菜地CH4、N2O和NH3排放特征

农田是重要的温室气体排放来源之一,其中蔬菜地的温室气体排放日益受到人们关注.以北京市郊某温室种植的油麦菜地为研究对象,通过大棚试验,考察和比较了油麦菜地施用不同类型畜禽粪便堆肥产品的CH4、N2O和NH3排放特征及其影响因素.结果表明,油麦菜地NRM、RM、CF处理的CH4排放系数分别为0.2%、0.027%、0.004%;N2O排放系数分别为0.18%、0.63%、0.74%;NH3排放系数分别为2.00%、3.98%、2.53%.CH4排放通量与土壤温度和地表湿度相关,N2O排放通量与土壤温度、地表温度和湿度相关,CH4、N2O和NH3排放通量均受土壤含水率影响,而温室中的气温不是影响CH4、N2O和NH3排放的主要因素.     

Nitrous oxide emissions from a maize field during two consecutive growing seasons in the North China Plain

Nitrous oxide (N₂O) emissions from a maize field in the North China Plain (Wangdu County, Hebei Province, China) were investigated using static chambers during two consecutive maize growing seasons in the 2008 and 2009. The N₂O pulse emissions occurred with duration of about 10 days after basal and additional fertilizer applications in the both years. The average N₂O fluxes from the CK (control plot, without crop, fertilization and irrigation), NP (chemical N fertilizer), SN (wheat straw returning plus chemical N fertilizer), OM- 1/2N (chicken manure plus half chemical N fertilizer) and OMN (chicken manure plus chemical N fertilizer) plots in 2008 were 8.51, 72.1, 76.6, 101, 107 ng N/(m²·sec), respectively, and in 2009 were 33.7, 30.0 and 35.0 ng N/(m²·sec) from CK, NP and SN plots, respectively. The emission factors of the applied fertilizer as N₂O-N (EFs) were 3.8% (2008) and 1.1% (2009) for the NP plot, 3.2% (2008) and 1.2% (2009) for the SN plot, and 2.8% and 2.2% in 2008 for the OM-1/2N and OMN plots, respectively. Hydromorphic properties of the investigated soil (with gley) are in favor of denitrification. The large differences of the soil temperature and water-filled pore space (WFPS) between the two maize seasons were suspected to be responsible for the significant yearly variations. Compared with the treatments of NP and SN, chicken manure coupled with compound fertilizer application significantly reduced fertilizer loss rate as N₂O-N.     

Development of a new model for the simulation of N<Subscript>2</Subscript>O emissions: a case-study on wheat cropping systems under humid Mediterranean climate

Improving the quantification of nitrous oxide (N₂O) emissions from agricultural land has become an issue of major concern due to its strong contribution to the greenhouse effect and to the fact that N₂O is now the most significant ozone-depleting emission to the atmosphere. The aim of this paper is to describe the development of a new field-scale, simple and empirical model that simulates monthly nitrogen (N) flows in cropping systems based on site characteristics and management practices. We explored its sensitivity for a Basque region of Spain growing winter wheat (Triticum aestivum L.) under humid Mediterranean conditions to varied weather conditions and different scenarios of: (i) fertiliser rates, (ii) soil texture, (iii) organic/mineral fertilisation, (iv) slurry injection/no injection and (v) tillage/no tillage. The model showed sensitivity to most of the changes in the tested parameters. On average, simulated N₂O emissions decreased: (i) with the decrease in N fertiliser rates, (ii) in lighter textured soils, (iii) with organic fertilisation, (iv) after non-injecting slurry and (v) under no-tillage. The model showed that it could be useful to simulate some of the potential trade-offs that may occur after implementation of specific N pollution mitigation measures (e.g. trade-offs in crop productivity and ammonia (NH₃) volatilisation after implementation of measures that target a reduction in N₂O emissions). In a validation exercise, simulated and measured yield and soil moisture showed reasonable agreement. Although the model showed discrepancies for monthly-averaged N₂O fluxes, the peak after fertilisation application was reasonably well simulated. These results and the simplicity and user-friendliness of the model suggest that its structure is appropriate and, if properly calibrated for different soil types and weather conditions, it could be a useful model to be used in carbon footprint studies or to develop site-specific emission factors for current or future climatic scenarios.     

控释尿素对黄河故道沙性潮土N2O排放的影响

建立田间原位试验,采用静态箱-气相色谱法,研究了常规尿素及其与硫包膜和聚氨酯包膜控释尿素配施(比例分别为30%∶70%、 50%∶50%和70%∶30%)对黄河故道沙性潮土玉米生长季氧化亚氮(N_2O)排放的影响.研究发现:常规尿素处理N_2O排放量(以N计,下同)为1.78 kg·hm~(-2),排放系数为0.38%;与之相比,配施30%、 50%和70%硫包膜尿素处理的N_2O排放量分别降低了1.12%、 22.5%和11.2%,排放系数下降2.63%～26.3%.相反,配施聚氨酯包膜尿素处理增加N_2O排放量0.02～0.41 kg·hm~(-2),其中70%聚氨酯包膜尿素处理增幅最大,达到23.0%.回归分析表明,各处理N_2O排放通量与10 cm处土温、土壤NH~+_4-N和NO~-_3-N含量呈极显著正相关(P0.01),而与土壤孔隙含水量和溶解性有机碳含量无显著关系.与常规尿素相比, 50%常规尿素+50%硫包膜控释尿素处理玉米产量略有增加,而30%常规尿素+70%硫包膜尿素处理稍微降低了玉米产量,但不显著(P0.05).因此,控释肥减缓土壤N_2O排放以及对作物产量的影响主要受控于包衣材料.     

On the determination of nitrous oxide emission factor during biomass burning

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Differences in nitrous oxide fluxes from red soil under different land uses in mid-subtropical China

Red soil may play an important role in nitrous oxide (N₂O) emissions due to its recent land use change pattern. To predict the land use change effect on N₂O emissions, we examined the relationship between soil N₂O flux and environmental determinants in four different types of land uses in subtropical red soil. During two years of study (January 2005-January 2007), biweekly N₂O fluxes were measured from 09:00 to 11:00 a.m. using static closed chamber method. Objectives were to estimate the seasonal and annual N₂O flux differences from land use change and, reveal the controlling factors of soil N₂O emission by studying the relationship of dissolved organic carbon (DOC), microbial biomass carbon (MBC), water filled pore space (WFPS) and soil temperature with soil N₂O flux. Nitrous oxide fluxes were significantly higher in hot-humid season than in the cool-dry season. Significant differences in soil N₂O fluxes were observed among four land uses; 2.9, 1.9 and 1.7 times increased N₂O emissions were observed after conventional land use conversion from woodland to paddy, orchard and upland, respectively. The mean annual budgets of N₂O emission were 0.71-2.21 kg N₂O-N ha⁻¹ year⁻¹ from four land use types. The differences were partly attributed to increased fertilizer use in agriculture land uses. In all land uses, N₂O fluxes were positively related to soil temperature and DOC accounting for 22-48% and 30-46% of the seasonal N₂O flux variability, respectively. Nitrous oxide fluxes did significantly correlate with WFPS in orchard and upland only. Nitrous oxide fluxes responded positively to MBC in all land use types except orchard which had the lowest WFPS. We conclude that (1) land use conversion from woodland to agriculture land uses leads to increased soil N₂O fluxes, partly due increased fertilizer use, and (2) irrespective of land use, soil N₂O fluxes are under environmental controls, the main variables being soil temperature and DOC, both of which control the supply of nitrification and denitrification substrates.     

秸秆还田配施生物炭对关中平原夏玉米产量和土壤N2O排放的影响

为探明秸秆还田配施生物炭对夏玉米产量和土壤氧化亚氮（N₂O）排放的影响,基于2019~2020年关中平原田间定位试验,利用静态暗箱-气相色谱法监测了土壤N₂O排放通量,综合分析夏玉米产量、土壤N₂O排放和土壤活性氮组分,明确了秸秆还田配施生物炭在培肥土壤、增产减排方面的效应.以秸秆不还田（S₀）为对照,设置秸秆还田（S）和秸秆还田配施生物炭（SB）共3个处理.结果表明,各处理N₂O排放峰值出现在秸秆还田后10 d,秸秆还田30 d后土壤N₂O排放通量处于较低水平,土壤N₂O排放通量与铵态氮（NH₄⁺-N）、无机氮、微生物量氮（MBN）和可溶性有机氮（DON）含量呈显著的正相关关系（P<0.05）.S较S₀显著增加夏玉米产量、N₂O累积排放量、单位产量N₂O累积排放量和土壤总氮（TN）含量,分别为7.4%~13%、65.8%~132.2%、54.6%~103%和27.8%~33%.虽然SB较S提高夏玉米产量（2.5%~3.3%）的趋势不显著（P>0.05）,但是SB较S显著降低N₂O累积排放量和单位产量N₂O累积排放量,分别为24.0%~27.3%和26.4%~29.2%.在土壤N₂O排放通量达到峰值时,SB较S显著降低土壤N₂O排放通量45.1%~69.6%,生物炭能够缓解秸秆还田所诱发的土壤N₂O排放,具有削峰的作用.SB较S显著增加土壤总氮9.1%~12.2%.综合作物产量、N₂O排放和土壤总氮,对夏玉米生产而言,秸秆还田配施生物炭不仅培肥地力,提高夏玉米产量,而且减少单位产量N₂O累积排放量,是可供推广的兼顾作物产量和环境友好的适宜管理措施.     

长期定位有机物料还田对关中平原冬小麦-玉米轮作土壤N2O排放的影响

为定量研究有机物料还田对农田土壤N2O排放的影响,采用静态暗箱-气相色谱法对关中平原冬小麦-玉米轮作24 a长期定位施肥试验地土壤N2O排放速率和相关环境因子进行了周年观测,试验处理为对照(CK,0 kg·hm~(-2))、氮磷钾(NPK,353kg·hm~(-2))、氮磷钾加秸秆还田[NPKS,(353+40)kg·hm~(-2)]和氮磷钾加牛粪[NPKM,(238+115)kg·hm~(-2)]4个处理.结果表明观测期内,CK处理N2O排放速率较小[2.9 g·(hm~2·d)~(-1)];施肥处理在冬小麦季施肥和玉米季灌溉后均出现排放峰,最高值分别为NPKS[113.4 g·(hm~2·d)~(-1)]和NPKM[495.0 g·(hm~2·d)~(-1)]处理.各处理N2O排放通量与土壤湿度均呈显著正相关关系(r0.28,P0.05).CK、NPK、NPKS和NPKM处理N2O年排放总量分别为(0.1±0.0)、(2.6±0.1)、(3.4±0.7)和(2.9±0.3)kg·hm~(-2),施肥处理排放总量显著高于CK处理(P0.05),但施肥处理之间差异不显著(P=0.06),说明施肥促进了N2O排放,但有机物料还田未能显著增加N2O排放.各施肥处理N2O直接排放系数分别为0.72%、0.83%和0.80%,均低于IPCC缺省值1%.施肥处理中,NPKM处理的单位产量N2O排放量最低.     

Nitrous oxide emission fromagricultural lands in Russia

Nitrous oxide (N₂O) atmospheric emission from differentagricultural soil types in Russia was evaluated based on published data onsingle input of nitrogen (N) fertilizers. For most of experiments the rates offertilization varied from 40 to 75 and from 160 to 264 kg/ha in activematter and they were considered separately. The higher rates ofsynthetic fertilizers (160 to 264 kg/ha) reduced relative gaseous loss ofN as N₂O (N₂O-N). Evidently, if nitrate (NO₃) concentrationswere high, the low content of organic carbon (C) and oxygen (O) restricted soilmicrobiological activity and consequently formation of N₂O. Themajority of gaseous loss of N₂O-N occurred within 140 days afterthe input of fertilizers. The N₂O emission factors derived forchernozem and soddy podzolic soil are 0.0126 and 0.0238 kgN₂O-N/kg N respectively. In 1990, the use of N fertilizers innational agriculture caused the release of 53 Gg N₂O-N thatconstituted 6% of global N₂O emission. Later on, the emissiondropped because of decreased use of N fertilizers, and in 1998 itwas almost 21% of the 1990 level.     

常规施肥条件下农田不同途径氮素损失的原位研究:以长江中下游地区夏玉米季为例

为了解农田常规施肥条件下的不同途径氮素损失特征,本文通过田间原位试验同步研究了长江中下游地区夏玉米生长季氮肥施用后的农田N2O排放、NH3挥发、氮渗漏和地表径流的变化.结果表明,在复合肥为基肥,尿素为追肥,基追肥氮素水平均为150 kg·hm-2的条件下,整个玉米生长季N2O排放系数为3.3%,NH3挥发损失率为10.2%,氮渗漏和地表径流损失率分别为11.2%和5.1%.此外,基肥施用以氮素渗漏损失为主,而追肥氮素损失以氨挥发和渗漏为主,表明不同途径化肥氮素损失主要受氮肥品种影响,玉米季追肥可改用低氨挥发氮肥品种以减少氮素损失.     

氮肥施用对紫色土-玉米根系系统N2O排放的影响

通过不同施氮水平与不同氮肥品种2个田间试验,结合静态箱-气相色谱法研究了川中丘陵区2005年5～9月石灰性紫色土-玉米根系系统的N2O排放变化.结果表明:1)施用氮肥显著地增加了N2O排放,在3个施氮水平下(0、150和250 kg·hm-2),N2O排放总量分别为0.88、2.19和2.52 kg·hm-2;施氮量越高,N2O排放量也越高.当施氮量超过一定水平后,施肥量高低对N2O排放总量的影响并不显著.由氮肥施用引起的N2O排放量占施氮量的0.87%(150 kg·hm-2)和0.66%(250 kg·hm-2).2)氮肥品种显著影响N2O排放,尿素(酰胺态氮肥)和硫酸铵(铵态氮肥)处理的N2O排放量分别为2.09和1.80 kg·hm-2,显著高于硝酸钾(硝态氮肥)处理(1.27 kg·hm-2),三者排放量分别占施氮量的0·80%、0.60%和0.27%.3)降雨是玉米生长季N2O排放的主要影响因子,而无机氮则是影响N2O排放的主要限制因子.     

Effect of C/N ratio, aeration rate and moisture content on ammonia and greenhouse gas emission during the composting

Gaseous emission (N₂O, CH₄ and NH₃) from composting can be an important source of anthropogenic greenhouse gas and air pollution. A laboratory scale orthogonal experiment was conducted to estimate the effects of C/N ratio, aeration rate and initial moisture content on gaseous emission during the composting of pig faeces from Chinese Ganqinfen system. The results showed that about 23.9% to 45.6% of total organic carbon (TOC) was lost in the form of CO₂ and 0.8% to 7.5% of TOC emitted as CH₄. Most of the nitrogen was lost in the form of NH₃, which account for 9.6% to 32.4% of initial nitrogen. N₂O was also an important way of nitrogen losses and 1.5% to 7.3% of initial total nitrogen was lost as it. Statistic analysis showed that the aeration rate is the most important factor which could affect the NH₃ (p = 0.0189), CH₄ (p = 0.0113) and N₂O (p = 0.0493) emissions significantly. Higher aeration rates reduce the CH₄ emission but increase the NH₃ and N₂O losses. C/N ratio could affect the NH₃ (p = 0.0442) and CH₄ (p = 0.0246) emissions significantly, but not the N₂O. Lower C/N ratio caused higher NH₃ and CH₄ emissions. The initial moisture content can not influence the gaseous emission significantly. Most treatments were matured after 37 days, except a trial with high moisture content and a low C/N ratio.     

猪粪化肥配施对双季稻田CH4和N2O排放及其全球增温潜势的影响

以湖南典型红壤双季稻田系统为研究对象,采用静态箱-气相色谱法研究了水稻生长季基肥配施猪粪条件下CH4和N2O的排放特征,并估算了排放的CH4和N2O的全球增温潜势(GWP).结果表明,与施用化肥处理相比,猪粪化肥配施对稻田CH4和N2O排放的季节变化模式无明显影响,但影响其排放量大小.两个稻季,猪粪替代50%化学氮肥处理(1/2N+PM)CH4累积排放量较不施氮肥处理(0N)、50%化学氮肥处理(1/2N)、100%化学氮肥处理(N)分别提高54.83%、33.85%和43.30%(P<0.05);1/2N+PM处理N2O累积排放量较N处理显著降低67.50%,较0N处理、1/2N处理分别提高129.43%、119.23%(P<0.05).水稻生长季CH4是GWP的主要贡献者,占CH4和N2O综合GWP的99%以上.1/2N+PM处理的GWP显著高于其他处理(P<0.05),且1/2N+PM处理单位产量GWP最高,较N处理、1/2N处理、0N处理分别提高58.21%、26.82%、20.63%.因此,双季稻田猪粪替代部分化学氮肥较全部施用化学氮肥增加了双季稻田CH4和N2O排放的综合温室效应,其对温室气体排放的影响需在区域温室气体排放清单中加以考虑.     

Effects of irrigation,fertilization and crop straw management on nitrous oxide and nitric oxide emissions from a wheat–maize rotation field in northern China

One-year winter wheat–summer maize rotation is the most popular double cropping system in north-central China, and this highly productive system is an important source of nitrous oxide (N₂O) and nitric oxide (NO) emissions due to the high fertilizer N and irrigation water inputs. To sustain the high crop production and mitigate the detrimental impacts of N₂O and NO emissions, improved management practices are extensively applied. The aim of this study is therefore to evaluate the effects of an improved management practice of irrigation, fertilization and crop straw on grain yield and N₂O and NO emissions for a wheat–maize rotation field in northern China. Using automated and manual chamber measuring systems, we monitored N₂O and NO fluxes for the conventional (CT, 2007–2008), improved (IT, 2007–2008), straw-amended (WS, 2008–2009), straw-not-amended (NS, 2008–2009), and no N-fertilizer treatments (WS–NN, 2008–2009), respectively, for one rotation-year. The grain yields were determined for CT and IT for three rotation-years (2005–2008) and for WS, NS and WS–NN for one rotation-year (2008–2009). The improved management of irrigation and fertilization reduced the annual N fertilization rate and irrigation amount by 17% and 30%, respectively; increased the maize yield by 7–14%; and significantly decreased the N₂O and NO emissions by 7% (p < 0.05) and 29% (p < 0.01), respectively. The incorporation of wheat straw increased the cumulative N₂O and NO emissions in the following maize season by 58% (p < 0.01) and 13%, respectively, whereas the effects of maize straw application were not remarkable. The N₂O and NO emission factors of applied N were 2.32 ± 2.32% and 0.42 ± 1.69% for wheat straw and 0.67 ± 0.23% and 0.54 ± 0.15% for chemical N-fertilizers, respectively. Compared to conventional management practices using high application rates of irrigation water and chemical N-fertilizer as well as the field burning of crop straw, the improved management strategy presented here has obvious environmentally positive effects on grain yield and mitigation of N₂O and NO emissions.     

不同水分管理方式下水稻生长季N2O排放量估算:模型建立

我国水稻生产中往往采用多种水分管理方式,如持续淹水、淹水-烤田-淹水和淹水-烤田-淹水-湿润灌溉等. 水分管理方式的不同会引起水稻生长季N₂O排放的显著变化. 本研究收集和整理了2005年以前17篇国内外文献报道的有关我国稻田N₂O季节排放通量的71组田间原位测定资料,每组资料包括稻田氮肥施用的种类和施用量、水分管理方式、N₂O季节排放量等数据,旨在建立不同水分管理方式下水稻生长季N₂O直接排放量的估算模型. 分析结果表明,持续淹水稻田N₂O季节排放量与施氮量无明显相关关系,在淹水-烤田-淹水和淹水-烤田-淹水-湿润灌溉的水分管理方式下,两者呈极显著线性正相关关系. 持续淹水稻田N₂O季节排放总量相当于施氮量的0.02%. 基于普通最小二乘法（OLS）分析技术建立的线性回归模型估算结果表明,淹水-烤田-淹水的水分管理方式下稻田肥料氮的N₂O排放系数为0.42%,但N₂O季节背景排放量不显著. 在淹水-烤田-淹水-湿润灌溉的水分管理方式下,水稻生长季肥料N的N₂O排放系数和N₂O-N背景排放量分别为0.73%和0.79 kg·hm^-2. 残差分析和效能分析显示模型具有较好的适切性. 综合3种水分管理方式,我国稻田水稻生长季N的N₂O排放系数和N₂O-N背景排放量平均分别为0.54%和0.43 kg·hm^-2. 相对于旱作农田而言,水稻生长季肥料N的N₂O排放系数较低,意味着水稻生产较旱地作物可能更有利于减缓我国农业N₂O排放. 本研究建立的模型可以用于我国稻田水稻生长季N₂O直接排放量的估算.