长期施用有机肥对稻麦轮作体系土壤有机碳氮组分的影响

【目的】 以湖北武汉地区长期稻麦轮作制度下施肥试验地作为研究对象,研究了长期不同施肥处理对耕层土壤有机碳、全氮及活性碳氮组分的影响,为优化稻麦轮作体系下施肥措施,实现土壤固碳减排,培肥土壤提供理论依据。 【方法】 长期施肥试验开始于1981年,试验处理包括不施肥 (CK)、施化学氮肥 (N)、施化学氮磷肥 (NP)、施化学氮磷钾肥 (NPK)、单施有机肥 (M) 及有机无机肥配施处理 (NPKM)。收集2017年小麦收获后耕层 (0—20 cm) 土壤,测定各小区土壤中的有机碳 (SOC)、全氮 (TN)、微生物量碳氮 (MBC、MBN)、水溶性碳 (DOC)、热水溶性有机碳 (HWSC)、颗粒有机碳氮 (POC和PON)、轻组有机碳氮 (LFOC和LFON) 及氯化钾浸提氮 (KEN,即水溶性无机氮) 的含量并分析各指标间的关系。 【结果】 1) 除KEN外,长期施用有机肥显著增加耕层土壤的各碳氮组分含量,特别是有机无机肥配施处理。2) 各活性有机碳组分占SOC的百分比由高到低排序为POC > LFOC > HWSC > MBC > DOC,各氮组分占TN的百分比由高到低排序为PON > LFON > MBN > KEN,其中POC占SOC的24.04%～37.64%,PON占TN的12.09%～20.24%,且有机肥处理下POC/SOC、PON/TN显著高于其余处理。3) 通过对土壤有机碳及各活性有机碳的对施肥的敏感性分析可得,各活性碳敏感性指数均显著高于SOC,且DOC的敏感性最高。4) 通过各组分间相关性分析可知,除KEN外,各碳、氮组分间显著正相关,其中DOC与SOC、PON与TN关系更为紧密,表明DOC及PON可较好地反应出SOC、TN的变化情况。 【结论】 在湖北稻麦轮作地区,长期有机无机肥配施处理显著增加了土壤碳库及氮库,促进了土壤碳、氮的积累,尤其是颗粒有机碳和有机氮 (POC和PON)。水溶性碳 (DOC) 对施肥反应最为敏感,可作为指示该地区有机物早期变化的指示物。      

长期施肥与地膜覆盖对土壤微生物量碳氮的影响

通过田间定位试验研究长期施肥与地膜覆盖对土壤微生物量C、N的影响。结果表明，长期施肥与地膜覆盖提高了土壤微生物量C、N含量，长期施有机肥和有机无机肥配施，土壤微生物量C、N显著高于单施化肥和不施肥。相关分析表明，土壤微生物量C、N与土壤有机C、全N均呈极显著的正相关。土壤微生物量C、N可作为指示土壤肥力的重要指标。本试验土壤微生物量C占有机C的比例平均为9．95％，微生物量N占全N的比例平均为10．78％。     

Significance of microbial biomass for carbon and nitrogen mineralization in soil

C and N mineralization was quantified in an incubation experiment with two samples containing different amounts of microbial biomass. The samples from two layers (0–20, 20–30 cm) of an arable luvisol from loess were fertilized with nitrate, mixed with ¹⁴C-labelled straw and incubated for 52 days at different O₂ levels. Decreasing O₂ concentrations (21, 2, 1 and 0% O₂) in soil conducted a decrease in C and N mineralization. More C and N were mineralized in samples with a higher initial microbial biomass. The differences in microbial biomass were still present at the end of the experiment, but more proliferation was detected in samples with the lower initial microbial biomass, leading to equal ratios between microbial biomass-C and soil organic C in both soils.     

长期施肥对土壤微生物生物量碳、氮及矿质态氮含量动态变化的影响

利用位于陕西杨凌的17年长期定位试验研究了长期不施肥(CK)、单施化肥(F)、化肥配施有机肥(F+M)和化肥加秸秆还田(F+S)处理对小麦-玉米轮作体系中作物不同生长时期土壤微生物生物量碳、氮(SMBC、SMBN)和矿质态氮含量的影响。结果表明,0—10 cm土层土壤SMBC、SMBN和矿质态氮含量的变化范围分别为264.8~752.2、37.51~14.8和3.83~8.5 mg/kg。不同处理相比,F+M处理中各采样时期(小麦苗期、拔节期、灌浆期及玉米播种期、大喇叭口期、灌浆期和收获后)土壤SMBC和SMBN含量均为最高,分别为不施肥对照的1.382~.65和1.892~.50倍;F+S处理矿质态氮含量最高,SMBC和SMBN也高于F和CK处理,大部分采样时期的差异达显著水平(P0.05);与CK相比,长期单施化肥也使各时期SMBC和SMBN含量提高。在小麦拔节期到灌浆期的旺盛生长阶段各施肥处理土壤SMBN含量均下降,而矿质态氮含量变化不大,处于较低水平;在玉米大喇叭口期到灌浆期的旺盛生长阶段,F+M、F+S和F处理土壤矿质态氮含量显著下降,而SMBN含量均有所升高。表明在土壤矿质态氮含量较高时,作物首先利用矿质态氮,而在土壤矿质态氮含量处于较低水平时,微生物固持的氮素可能会释放出来供作物吸收利用。     

长期施肥对栗褐土有机碳矿化的影响

【目的】 土壤有机碳矿化是土壤中重要的生物化学过程,与土壤养分的释放、土壤质量的保持以及温室气体的形成密切相关。本文以 25 年长期定位施肥试验为依托,对栗褐土土壤有机碳矿化速率、有机碳累积矿化量的动态变化进行研究,为科学管理土壤肥力、增加栗褐土碳汇、减少温室气体排放提供依据。 【方法】 田间试验开始于 1988,共设置 8 个施肥处理:不施肥 (CK);单施氮肥 (N);氮磷肥合施 (NP);单施低量有机肥(M₁);低量有机肥与氮肥合施 (M₁N);低量有机肥与氮磷肥合施(M₁NP);高量有机肥与氮肥合施 (M₂N);高量有机肥与氮磷肥合施 (M₂NP)。于 2013 年玉米播种前,采集耕层 (0—20 cm) 土壤样品,采用室内培养方法,对土壤碳矿化释放 CO₂ 的数量和速率进行测定,并利用一级动力学方程计算出土壤有机碳库潜在矿化势和周转速率。 【结果】 各肥料处理不同程度地提高了栗褐土总有机碳含量,以高量有机肥与化肥配施作用最为显著。与 CK 相比,M₂N、M₂NP 处理土壤总有机碳含量增加了 121.1%、166.8%。不同处理土壤样品培养有机碳矿化速率均在第一天达到峰值,随后急剧下降。5 d 后,下降趋缓,不同处理 CO₂ 产生速率趋于一致。培养期间,各处理矿化速率变化符合对数函数关系。长期施用不同肥料均可以提高栗褐土有机碳的矿化速率,其大小顺序为:有机肥与化肥配施 > 单施有机肥 > 单施化肥 > 对照。培养 57 d 后,各处理土壤有机碳累积矿化量为 555.0～980.3 mg/kg,以 M₂NP、M₁N 的累积量较高,为对照的 1.77 倍、1.73 倍。长期施肥栗褐土有机碳矿化率呈下降趋势,以处理 M₂NP 下降最明显,与对照相比,降低了 6.3 个百分点。施肥处理土壤的潜在矿化势均高于对照,M₁N、M₂NP 最高,为 923.7 mg/kg 和 926.4 mg/kg,较对照增加了 74.0% 和 74.5%。不同施肥处理均可明显提升土壤有机碳的周转速率,减少周转时间,其中处理 M₁NP、M₂NP 效果最为明显。 【结论】 长期施用化肥、有机肥及有机无机肥配施可有效促进栗褐土有机碳的积累,提高有机碳的矿化速率和周转速率,降低有机碳的矿化率 (累积矿化量占有机碳总量的比率),加强了土壤的固碳能力,以 M₂NP 处理的效果更佳。      

不同施肥水平及玉米种植对土壤微生物生物量碳氮的影响

以裸地(不种植作物)和玉米种植的田间小区试验为平台,研究不同施肥水平及玉米种植对土壤微生物生物量碳氮的影响。结果表明,当不施肥时,土壤微生物生物量碳氮含量裸地平均值分别为175.98 mg/kg和26.04 mg/kg,种植玉米小区的平均值分别为161.65 mg/kg和22.70 mg/kg,土壤微生物生物量碳氮低于裸地;而施肥时,裸地的土壤微生物生物量碳氮平均值的变化范围分别为182.27~206.27 mg/kg和27.41~31.22 mg/kg,种植玉米小区的变化范围分别为194.70~235.58 mg/kg和35.76~44.66 mg/kg,土壤微生物生物量碳氮高于裸地,可见土壤碳氮的平衡对于土壤微生物生物量碳氮极为重要。裸地和玉米种植小区土壤微生物生物量碳氮均随着施肥量的增加呈现出先增加后降低的趋势,其施氮水平拐点分别为70 kg/hm2和150kg/hm2,表明施肥水平对土壤微生物生物量碳氮具有显著影响。另外,玉米各生育期间土壤微生物生物量碳氮也存在着显著差异,其中,土壤微生物生物量碳氮含量在拔节期处于最低,变动范围分别为154.46~229.09 mg/kg和18.84~31.44 mg/kg;抽雄期处于最高,变动范围分别为171.71~242.48 mg/kg和30.01~50.54 mg/kg。     

Long-term tillage and rotation effects on soil microbial biomass,carbon and nitrogen

Summary Three mollisols, typical of the Palouse winter wheat region of eastern Washington and northern Idaho, were analyzed for microbial biomass, total C and total N after 10 years of combined tillage and rotation treatments. Treatments included till, no-till and three different cereal-legume rotations. All crop phases in each rotation were sampled in the same year. Microbial biomass was monitored from April to October, using a respiratory-response method. Microbial biomass, total C and total N were highest under no-till surface soils (0–5 cm), with minimal differences for tillage or depth below 5 cm. Microbial biomass differences among rotations were not large, owing to the relative homogeneity of the treatments. A rotation with two legume crops had the highest total C and N. Microbial biomass was significantly higher in no-till surface soils where the current crop had been preceded by a high-residue crop. The opposite was true for the tilled plots. There was little change in microbial biomass over the seasons until October, when fresh crop residues and rains had a strong stimulatory effect. The seasonal pattern of biomass in no-till surface soils reflected the dry summer/winter rainfall climate of the region. The results of this study show that numerous factors affect soil microbial biomass and that cropping history and seasonal changes must be taken into account when microbial biomass data are compared.Scientific paper no. 7634     

长期定位施肥对潮土有机氮组分和有机碳的影响

利用河南封丘潮土的13年长期施肥试验,采用Bremner法研究了潮土耕层有机氮组成的变化,分析了长期施肥对土壤有机氮组份和有机碳含量的影响。与不施肥和单施化肥相比,施有机肥或有机肥与化肥配施显著提高了土壤全氮、酸解有机氮、酸解铵态氮、氨基酸态氮、非酸解有机氮和有机碳的含量。有机氮主要由酸解铵态氮和氨基酸态氮组成,其次为酸解未知态氮和非酸解有机氮,氨基糖态氮含量最小。施有机肥尤其利于氨基酸态氮和非酸解有机氮的形成。施肥处理的酸解有机氮占全氮的比例减小,主要是由氨基酸态氮、酸解铵态氮占全氮的比例减小所致。与1989年试验开始时的土壤初始值相比,施有机肥能提高土壤全氮含量和有机质含量。在供应等氮磷钾的情况下,有机无机配施增加了土壤供氮能力、有机质含量和作物产量,是维持土壤肥力和保护环境最优的施肥方式。     

长期施肥条件下红壤有机碳矿化对温度变化模式的响应

土壤有机碳(SOC)矿化是陆地生态系统碳循环的重要组成部分。土壤温度变化显著影响SOC的矿化特征,然而长期施肥条件下周期性温度变化和恒定温度这两种温度模式对SOC矿化影响的差异目前不清楚。本研究以湖南祁阳长期定位试验为平台,选取不施肥(CK)和有机无机肥配施(NPKM)2个处理,通过60 d室内控制培养试验,对比研究相同积温条件下,恒温(25℃)和变温(20～30℃,以25℃为均温)两种温度模式对CK和NPKM处理土壤有机碳矿化特征的影响。研究结果表明,各处理SOC矿化速率均在培养前期较高,且变温模式下SOC矿化速率显著高于恒温模式。培养结束后,各处理SOC累积矿化量变化范围为C 7.83～15.49 g·kg~(-1) SOC;相较于恒温模式,变温模式下CK和NPKM处理SOC累积矿化量分别增加了98%和57%(P0.05),说明变温模式相对于恒温显著促进了SOC矿化。在恒温模式下,CK处理SOC累积矿化量(C 7.83 g·kg~(-1) SOC)与NPKM处理(C 8.77 g·kg~(-1) SOC)相比无显著差异;而在变温模式下,CK处理SOC累积矿化量(C 15.49 g·kg~(-1) SOC)显著高于NPKM处理(C 13.76 g·kg~(-1) SOC),说明温度变化模式调控长期施肥对土壤有机碳矿化的影响。一级动力学方程模拟SOC矿化特征的结果表明,与恒温模式相比,变温模式下CK和NPKM处理SOC潜在矿化量分别显著提高了3.90和1.21倍,而SOC周转速率常数显著降低了71.6%和40.7%。以上研究结果表明变温模式相对于恒温模式显著促进了土壤有机碳矿化,且温度变化模式可以调控土壤有机碳矿化对长期施肥的响应。     

长期不同施肥处理对水稻土有机碳分布变异及其矿化动态的影响

基于持续26 a的太湖地区水稻土长期定位试验,研究了长期施肥对水稻土剖面有机碳分布、有机碳密度和变异幅度、及有机碳矿化动态的影响。结果表明:(1)长期施肥使水稻土表层有机碳含量显著升高,施有机肥和秸秆还田较单施化肥更能促进表层有机碳累积。施化肥处理10~30 cm土层有机碳含量相对稳定,施有机肥处理20~40 cm土层有机碳含量相对稳定;(2)0~25 cm和0~50 cm土层,施有机肥处理的有机碳密度均高于施化肥处理,有机肥+氮+磷处理(MNP)和化肥氮+磷+钾处理(CNPK)的有机碳密度均为最高,秸秆+化肥氮处理(CRN)高于有机肥+秸秆+氮处理(MRN)。各施肥处理0~25 cm和25~50 cm土层有机碳变异幅度均高于对照C0。施有机肥处理的有机碳密度变异幅度均高于施化肥处理。化肥氮+磷处理(CNP)和有机肥+氮+磷+钾处理(MNPK)有机碳密度的变异性最大;(3)各处理土壤有机碳矿化速率在培养第2~4天均达到最大,第3周后达到稳定,有机肥处理的最大矿化速率均高于化肥处理,各处理平均矿化速率为CO255.36~75.46 m l kg-1d-1,稳定矿化速率为CO210~20 m l kg-1d-1。在8周培养期内,施有机肥处理的累积矿化量始终大于施化肥处理,有机肥+秸秆+氮处理(MRN)的累积矿化量最大,各施肥处理土壤的矿化强度和稳定矿化率仍保持稳定。     

长期有机培肥模式下黑土碳与氮变化及氮素矿化特征

土壤氮的矿化是土壤氮素肥力的重要指标,是影响作物产量至关重要的因素。本研究依托黑土长期定位试验,通过取样分析研究了32 a不同培肥模式下黑土碳、 氮及主要活性组分的变化,采用淹水培养法研究了不同施肥模式下黑土氮素的矿化特征。结果表明,施肥显著提高黑土可溶性碳（DOC）、 氮（DON）的含量及其比例。在氮、 磷、 钾化肥的基础上配施有机肥,显著降低了土壤微生物量氮（SMBN）占土壤总氮的比例,提高了土壤微生物量的C/N比值（SMBC/SMBN）,促进了土壤氮的生物固持。施肥32 a后,单施常量和高量有机肥处理的土壤氮的矿化量（Nt）显著提高,分别相当于不施肥的8.2倍和10.2倍,而单施氮或氮磷钾化肥对黑土氮素矿化量无明显影响。施用有机肥显著提高了土壤氮素的矿化率（Nt/TN）,但有机肥配施化肥（氮或氮磷钾）的处理与单施有机肥相比,黑土氮的矿化率显著降低,降低幅度分别为23.5%~32.1% 和14.1%~17.8%。土壤氮素矿化量与土壤有机质、 全氮储量、 活性碳、 氮组分均呈极显著线性相关,但氮素的矿化率随着有机质和全氮含量的提高而提高至0.4% 后基本稳定。表明尽管土壤氮的矿化与有机质的含量直接相关,但土壤有机质的品质同样决定着土壤氮素的矿化能力。施有机氮是提高土壤供氮能力的重要途径。     

不同施肥模式对设施菜田土壤微生物量碳、氮的影响

【目的】 本文利用天津日光温室蔬菜不同施肥模式定位试验,研究了不同施肥模式对设施菜田土壤微生物量碳、氮含量的影响,为设施蔬菜高效施肥和菜田土壤可持续利用提供依据。 【方法】 调查在第 9 茬蔬菜 (秋冬茬芹菜) 和第 10 茬蔬菜 (春茬番茄) 进行。定位试验设 8 个处理,分别为:1) 不施氮;2) 全部施用化肥氮 (4/4CN);3) 3/4 化肥氮 + 1/4 猪粪氮 (3/4CN + 1/4PN);4) 2/4 化肥氮 + 2/4 猪粪氮 (2/4CN + 2/4PN);5) 1/4 化肥氮 + 3/4 猪粪氮( 1/4CN + 3/4PN);6) 2/4 化肥氮 + 1/4 猪粪氮 + 1/4 秸秆氮 (2/4CN + 1/4PN + 1/4SN);7) 2/4 化肥氮 + 2/4 秸秆氮 (2/4CN + 2/4SN);8) 农民习惯施肥 (CF),除不施氮肥和农民习惯施肥外,其余处理为等氮磷钾处理。在不同生育时期,采 0—20 cm 土壤样品,测定土壤微生物量碳、氮含量,并分析其与蔬菜产量之间的关系。 【结果】 两茬蔬菜不同施肥模式土壤微生物量碳、氮含量总体上均随生育期的推进呈先增后降的趋势。芹菜季较高土壤微生物量碳含量出现在定植后 90 d,土壤微生物量氮较高含量出现在定植后 60 d;番茄季分别出现在定植后 20～80 d 和 60 d。芹菜季 5 个有机无机肥料配施模式土壤微生物量碳、氮含量分别在 185.0～514.6 和 34.3～79.1 mg/kg 之间,较化肥(4/4CN)模式平均分别增加 15.1%～81.7% 和 24.5%～100.0%,其中以配施秸秆模式土壤微生物量碳、氮含量相对较高,平均分别增加 62.0%～81.7% 和 81.1%～100.0%;番茄季 5 个有机无机肥料配施模式土壤微生物量碳、氮含量分别在 120.7～338.0 和 25.5～68.8 mg/kg 之间,较 4/4CN 模式平均分别增加 16.9%～86.9% 和 12.2%～109.3%,又以配施秸秆模式土壤微生物量碳、氮含量最高,平均分别增加 61.4%～86.9% 和 78.2%～109.3%。两季蔬菜不同生育期土壤微生物量碳、氮含量与当季蔬菜产量和定位试验开始以来蔬菜总产量之间均呈极显著正相关关系。 【结论】 同等养分投入量下,有机无机肥料配合施用提高土壤微生物量碳、氮的效果显著好于单施化肥,又以化肥配施秸秆效果更佳;土壤微生物量碳、氮含量与设施蔬菜产量之间呈极显著正相关关系。证明有机无机肥配施,特别是配施一定量的秸秆可有效提高土壤微生物量碳、氮含量,维持较高的菜田土壤肥力,有利于设施蔬菜的可持续和高效生产。      

章古台沙地松树人工林土壤无机氮、微生物生物量碳及微生物生物量氮

The dynamics of soil inorganic nitrogen （NH4^＋ -N and NO3^- -N） and microbial biomass carbon （Cmic） and nitrogen （Nmic） under 30-year-old fenced Pinus sylvestris L. var. mongolica Litvin （SF）, unfenced P. sylvestris L. var. mongolica Litvin （SUF）, and unfenced Pinus densiflora Siebold et Zucc. （DUF） plantations in the Zhanggutai sandy soil of China were studied during Apr. to Oct. 2004 by the in situ closed-top core incubation method. All mentioned C and N indices in each stand type fluctuated over time. The ranges of inorganic N, Cmic, and Nmic contents in the three stand types were 0.7-2.6, 40.0-128.9, and 5.4-15.2 μg g^-1, respectively. The average contents of soil NH4^＋ -N and Cmic under the three 30-year-old pine plantations were not different. However, soil NO3^ -N and total inorganic N contents decreased in the order of SUF ≥ SF ≥ DUF, the Nmic content was in the order of SF = SUF 〉 DUF, and the Cmic：Nmic ratio was in the order of SUF = DUF 〉 SF. Seasonal variations were observed in soil inorganic N, microbial biomass, and plant growth. These seasonal variations had certain correlations with microbe and plant N use in the soil, and their competition for NH4^＋ -N was mostly regulated by soil N availability. The influence of tree species on inorganic N and Nmic were mainly because of differences in litter quality. Lack of gazing decreased the Cmic：Nmic ratio owing to decreased carbon output and increased the ability of soil to supply N. The soil N supply under the P. sylvestris var. mongolica plantation was lower than under the P. densiflora plantation.     

不同施肥管理对红壤性水稻土有机碳、氮形态的影响

A long-term experiment beginning in 1981 in Jinxian County of Jiangxi Province, subtropical China, was conducted in a paddy field under a double rice cropping system with four different fertilization regimes, including 1) no fertilizer as control (CK), 2) balanced chemical N, P, and K fertilizers (NPK), 3) organic manure using milk vetch and pig manure in the early and late rice growing season, respectively (OM), and 4) balanced chemical fertilizers combined with organic manure (NPKM). Samples (0-17 cm) of the paddy field soil, which was derived from Quaternary red clay, were collected after the late rice harvest in November 2003 for determination of total organic carbon (TOC) and total nitrogen (TN) and fractions of organic C and N. Results showed that TOC and TN in the NPKM and OM treatments were significantly higher than those in other two treatments (CK and NPK). Application of organic manure with or without chemical fertilizers significantly increased the contents of all fractions of organic C and N, whereas chemical fertilizer application only increased the contents of occluded particulate organic C (oPOC) and amino acid N. In addition, application of organic manure significantly enhanced the proportions of free particulate organic carbon (fPOC) and oPOC in total C, and those of amino sugar N and amino acid N (P < 0.01) in total N. In contrast, chemical fertilizer application only increased the proportions of oPOC and amino acid N (P < 0.05). There were no significant differences in either contents or proportions of soil organic C and organic N fractions between the NPKM and OM treatments. These indicated that organic manure application with or without chemical fertilizers played the most significant role in enhancing soil organic C and N quantity and quality in the paddy field studied.     

小麦–玉米轮作体系长期施肥对塿土微生物量碳、氮及酶活性的影响

以20年塿土小麦玉米轮作体系长期肥料定位试验为平台,探讨不同施肥模式下土壤化学肥力要素、微生物量碳氮及酶活性的响应。试验包括不施肥（CK）、单施氮肥（N）、氮磷（NP）、磷钾（PK）、氮磷钾（NPK）、NPK+秸秆（SNPK）以及不同量有机肥+NPK（M1NPK、M2NPK）等8种施肥模式。结果表明,与CK相比,长期施用NP提高土壤有机碳含量达34.0%、全氮34.0%、全磷58.5%、速效磷608.9%、微生物量碳23.3%、微生物量氮54.0%、蔗糖酶53.9%、脲酶132.6%、碱性磷酸酶29.9%以及脱氢酶40.9%。长期施用NPK与NP效果相似,钾素效果甚微。作物秸秆还田配合氮磷钾化肥与氮磷钾相比没有明显影响土壤有机碳、氮和磷水平,但是显著提高微生物量碳的含量（29.5%）、碱性磷酸酶（23.0%）和脱氢酶（26.9%）的活性。有机肥配合氮磷钾与其它施肥处理相比,显著提升土壤化学肥力要素、微生物量碳氮和酶活性,特别是引起了磷素的大量富集（速效磷含量大于150 mg/kg）。因此,塿土不施有机物情况下,氮磷配合可以提高土壤化学和生物肥力,作物秸秆还田配合氮磷钾化肥的培肥效果优于氮磷钾化肥配合,而合理的有机无机肥配合是塿土提升化学肥力和保证生物健康的最佳施肥模式。     

长期施肥对高原农业生态系统土壤有机碳和氮的影响

The effects of fertilization on the distributions of organic carbon (OC) and nitrogen (N) in soil aggregates and whether these effects vary with cropping system have not been well addressed.Such information is important for understanding the sequestration of OC and N in agricultural soils.In this study,the distributions of OC and N associated with soil aggregates were analyzed in different fertilization treatments in a continuous winter wheat cropping system and a legume-grain rotation system in a 27-year field experiment,to understand the effects of long-term fertilization on the distributions of OC and N in aggregates and to examine the recovery of soil OC and N in a highland agroecosystem.Manure fertilizer significantly decreased soil bulk density but increased the amount of coarse fractions and their associated OC and N stocks in the soils of both systems.Fertilizers N + phosphorus (P) and manure had similar effects on total soil OC and N stocks in both systems,but had larger effects on the OC and N stocks in ＞ 2 mm aggregates in the legume-grain rotation system than in the continuous winter wheat system.The application of P increased the OC and N stocks in ＞ 2 mm aggregates and decreased the loss of N from chemical fertilizers in the legume-grain rotation system.The results from this study suggested that P fertilizer should be applied for legume-included cropping systems and that manure with or without chemical fertilizers should be applied for semiarid cropping systems in order to enhance OC and N accumulation in soils.     

添加生物质炭对红壤水稻土有机碳矿化和微生物生物量的影响

通过室内培育试验,研究了添加生物质炭对江西红壤水稻土有机碳矿化和微生物生物量碳、氮含量的影响。结果表明:红壤有机碳矿化速率在培育第2天达最大值后迅速降低,培养7天后下降缓慢并趋于平稳;添加生物质炭降低了土壤有机碳的矿化速率和累积矿化量,培养结束时,不加生物质炭的对照处理中有机碳的累积矿化量分别比添加0.5%和1.0%生物质炭的处理高10.0%和10.8%。此外,生物质炭的加入显著提高了土壤微生物生物量,添加0.5%生物质炭处理的土壤微生物生物量碳、氮含量分别比对照高111.5%～250.6%和11.6%～97.6%,添加1.0%生物质炭处理的土壤微生物生物量碳、氮含量分别比对照高58.9%～243.6%和55.9%～110.4%。相同处理中,干旱的水分条件下(40%田间持水量)微生物生物量要高于湿润的水分条件(70%田间持水量)。同时,添加0.5%和1.0%的生物质炭使土壤代谢熵分别降低2.4%和26.8%,微生物商减少了43.7%和31.7%。     

长期施肥对土壤有机碳和无机碳的影响

利用18年长期定位试验,研究了在不同施肥条件下,土壤有机碳和无机碳在0~50 cm土层分布特征。结果表明,施肥对土壤有机碳的影响随着土层深度的增加而下降,0~7.5 cm土层的土壤有机碳比7.5~15 cm、15~30 cm、30~50 cm分别增加了4.6%、22.0%、63.1%,而无机碳含量随着土层深度的增加而增加,与有机碳的变化规律正好相反。不同种类的肥料对土壤有机碳的影响也不相同,化肥、有机肥长期配合施用和长期施用有机肥可以在0~30 cm土层增加土壤有机碳含量,降低土壤中的无机碳含量,而长期单施化肥对土壤的有机碳和无机碳含量无明显差异。     

长期施用有机肥增加黄壤稻田土壤微生物量碳氮

【目的】微生物量碳、氮是土壤中易于利用的养分库及有机物分解和矿化的动力,与土壤养分循环密切相关,其变化可反映土壤耕作制度和土壤肥力的变化。本研究旨在揭示长期施肥对贵州黄壤稻田土壤微生物生物量碳 (SMBC) 和土壤微生物生物量氮 (SMBN) 的影响,并探讨其合理培肥模式。【方法】以贵州黄壤肥力与肥效长期定位监测基地为依托,采用氯仿熏蒸—K₂SO₄提取法,重点研究不同施肥条件下土壤微生物生物量碳氮的变化及其与全量有机碳氮的关系。试验处理包括不施肥 (CK)、单施化肥 (NPK)、单施有机肥 (M)、低量有机无机肥配施 (0.5MNPK) 和高量有机无机肥配施 (MNPK)。【结果】长期不同施肥处理下,SMBC的变化范围在423.87～695.04 mg/kg之间,SMBN的变化范围在44.36～91.65 mg/kg之间。施用化肥 (NPK) 和施用有机肥及两者配施 (M、0.5MNPK和MNPK) 能增加SMBC和SMBN含量,其中MNPK处理较CK处理SMBC含量增幅最高,达64.0%,显著高于NPK和0.5MNPK处理,但与M处理差异不明显;M处理较CK处理SMBN含量增幅最高,达106.6%,显著高于NPK和0.5MNPK处理,但与MNPK处理差异不明显;长期单施化肥 (NPK) 仅对SMBN含量有显著提高作用 (44.1%),对SMBC作用不明显。SOC、TN和微生物熵 (qMB) 的变化与SMBC一致,均表现为MNPK处理最高,其次为M和0.5MNPK处理,NPK处理最低;所有施肥处理下的SMBC/SMBN无显著性差异且均低于CK处理。【结论】土壤微生物碳、氮量和微生物熵的显著提高均与土壤有机质和全氮的含量变化呈正相关,单施有机肥和高量有机无机肥配施是提高土壤微生物生物量的有效途径。     

The contribution of soil organic matter fractions to carbon and nitrogen mineralization and microbial community size and structure

The aims of this study were to: (i) assess the impact of hay and fertilizer application on organic matter (OM) fractions (dissolved organic matter (DOM), light fraction organic matter (LFOM, <1.0 g cm⁻³), heavy fraction OM (HFOM, <1.7 g cm⁻³)), carbon (C) and nitrogen (N) cycling processes and microbial community size and structure, and (ii) quantify the role of OM fractions to C and N cycling. Soil was collected in 2001 from a field experiment to which grass hay (1996) and/or fertilizer (1995 and 1999) had previously been applied. DOM-C (P<0.05) and DOM-N (P=0.07) were significantly higher in control and fertilized soil than hay and hay+fertilized soil. LFOM and HFOM C and N contents and C/N ratios were significantly (P<0.05) higher in hay+fertilized and hay amended soil than in control and fertilized soil. Potentially mineralizable-N (PMN), microbial biomass-C (MB-C), microbial biomass-N (MB-N) and microbial respiration (CO₂) were not affected by fertilizer and/or hay application. Gross N mineralization (Gross Min) and gross nitrification (Gross Nit) rates were significantly (P<0.05) higher in fertilized, hay, hay+fertilized soil than control soil. However, there was no significant difference between treatments in gross N immobilization rates. Results reported here highlight the importance of a labile fraction of the DOM pool to N and C cycling as its removal significantly (P<0.05) reduced PMN, MB-N, Gross Min and Gross Nit compared with whole soil in most or all treatments. In soil where DOM+LFOM were removed PMN was significantly (P<0.05) lower, but MB-C, Gross Min and Gross Nit was significantly (P<0.05) higher than in DOM removed soil. This suggests that LFOM plays an important role as a sink for mineral-N. Total soil phospholipid fatty acid (PLFA) concentration was significantly (P<0.05) higher in hay amended than control, fertilized and hay+fertilized soil. Principal components analysis was able to clearly discriminate between control, fertilized, hay+fertilized and hay amended soil. Soil amended with hay or fertilizer had a microbial community structure which differed from that of the control or hay+fertilized soils. Redundancy analysis with Monte Carlo permutation tests revealed that PLFA profiles were strongly correlated to differences in Gross Min, Gross Nit, MB-N, MB-C, MB-C/N ratio, total soil C and total soil C/N ratio. The results of this research suggest that changes in microbial structure are related to aspects of soil C and N pools and cycling.