不同有机物料对黑土腐殖质元素组成的影响

采用盆栽试验,研究施用动物粪便、动物残体、草本残体、木本残体5年后对黑土胡敏酸（HA）、富里酸（FA）和胡敏素（HM）元素组成的影响。结果表明：与CK相比,有机物料施用5年后,黑土HA的C、H含量均显著降低,而缩合度及含氮基团数量提高,并以木本残体作用最显著。除动物粪便处理HA的N含量与CK的大致相同外,其余有机处理N含量均显著提高,各处理HA的O含量由大到小依次为木本残体〉草本残体〉动物粪便〉CK〉动物残体,且各处理差异显著。有机物料的施用可以降低FA的缩合度,并以草本残体作用最显著,同时草本残体施用提高了FA的N含量。而动物残体使FA的H含量显著降低。有机物料FA的C含量表现为草本残体〉木本残体〉CK〉动物残体〉动物粪便,而O含量及氧化度由大到小依次为动物残体〉动物粪便〉CK〉木本残体〉草本残体,且各处理间差异显著。有机物料的施用使HMi的C、H含量下降而使O含量上升,并以草本处理作用最显著,同时草本处理也使HMi的N含量降低。施用有机物料使HMc的氧化度、芳香度提高,结构变复杂。     

不同处理牛粪对植菜土壤腐殖质结构特征的影响

通过元素组成分析法、红外光谱分析法(IR)、核磁共振光谱分析法(13 C-NMR)等现代分析方法,研究施用新鲜牛粪、腐解牛粪和蛴螬牛粪2a后对植菜轮作土壤胡敏酸(HA)和富里酸(FA)的影响。结果表明,与单施化肥(CK)相比,不同牛粪处理对植菜土壤胡敏酸和富里酸的元素组成影响有较大的差异,各牛粪处理均引发植菜土壤胡敏酸C含量和C/H降低,O含量、O/C和(N+O)/C升高,富里酸C含量和C/N升高,N、O含量和O/C降低,降低了植菜土壤胡敏酸的缩合程度,升高了土壤胡敏酸的氧化程度和极性,降低了植菜土壤富里酸的氧化程度。不同牛粪处理使植菜土壤胡敏酸的脂肪族化合物减少,且均含有苯基碳、酚羟基C、芳香醚和(或)与O、N等取代基邻、对位的连H芳香C,使芳构化程度增加,富里酸的脂肪族化合物增加,芳香类、羧基类化合物减少,芳构化程度降低。不同牛粪处理的植菜土壤未改变土壤腐殖质的基本结构特征,只引起植菜土壤的结构单元和官能团数量上的差异。     

玉米秸秆腐解过程中形成胡敏酸的组成和结构研究

采用化学方法和谱学方法对玉米秸秆腐解生成胡敏酸（CCSR HA）的组成和结构进行了研究.结果表明,CCSR HA的碳组成可分成三个部分：脂肪族碳、芳香族碳和羧基碳,它们的含量分别为59.62%、26.94%和13.44%.CCSR HA主要的官能团包括羟基、烷基、羧基、酰胺基、苯环、烷氧基及碳水化合物结构,木质素残体是其骨架,碳水化合物结构或类糖结构及烷基片段是其主要组成单元.其类型属于Rp型胡敏酸.未腐解的玉米秸秆本身就含有类胡敏酸物质（OCSR HA）,OCSR HA和CCSR HA的官能团组成上有一定差异,后者结构中,甲基、亚甲基、次甲基、醚键官能团和酚羟基的含量降低,而酰胺成分、游离的羧基、甲氧基、碳水化合物组分相对含量升高,脂族性升高,芳香性降低,芳香度由初始的42.19降至腐解后的29.97,并且与无机物质的结合能力增强.就元素组成的变化看,CCSR HA中C和H元素的含量趋于降低,而N和O元素的含量趋于升高.CCSR HA同土壤胡敏酸相比,糖类结构含量较高,并且以片段的形式与水解木质素残体相连.羧基含量较低,但以不同的连接方式存在着.     

傅立叶变换红外光谱法表征玉米秆茬培肥土壤胡敏酸的变化

土壤腐殖质是土壤肥力的重要物质基础,在土壤有机碳库中占有相当大的比重,腐殖质可分成三个组分:胡敏酸(HA,不溶于酸),富里酸(FA,溶于酸)[1]和胡敏素(HM)。其中胡敏酸是土壤腐殖质中的活跃成分,其存在形态、分子组成、理化性质的变化对土壤的肥力特征都会产生巨大影响[2-3]。玉米植株残体作为有机肥的一个重要组成部分,施入土壤后必然对土壤HA的数量、组成、结构及存在形式产生影响,并使其理化性质发生改变,从而起到改善土壤环境和培肥土壤的作用。研究证明,玉米植株残体施入土壤后,土壤胡敏酸的理化性质得到显著的改善[4-5]。张晋京等…     

不同培肥方式黑土腐殖质形态特征研究

针对吉林省黑土区存在的土壤有机质下降、耕地质量退化等问题,利用公主岭国家黑土肥力与肥料效益监测基地连续20年的长期定位试验,采用核磁共振波谱分析法(NMR)、红外光谱分析法(IR)等现代分析方法,研究了不同培肥途径耕层土壤腐殖质的组成、形态结构及动态变化趋势。结果表明:不同培肥途径对耕层土壤腐殖质特征影响明显。施用玉米秸秆处理(S+NPK)和施用有机肥+轮作处理(M+NPK+R)均显著增加了土壤胡敏酸中脂肪族结构成分,单施有机肥处理(M+NPK)显著增加了土壤胡敏酸中羟基含量,S+NPK处理游离羧基含量显著增多。S+NPK、M+NPK及M+NPK+R处理,土壤富啡酸的甲基、亚甲基和次甲基结构成分显著增多,游离羧基含量也显著增多。单施化肥处理,浸提的富啡酸中无机碳酸盐和硅酸盐成分明显增多,化肥长期施用导致土壤中游离富啡酸数量显著减少,土壤的耗竭式利用,导致土壤中铁、铜结合态或络合态的富啡酸增加。不同培肥方式对黑土胡敏酸和富啡酸的元素组成影响有较大的差异,但均可引发胡敏酸C含量降低,N含量增加,富啡酸C、N、H含量增加,O含量降低,可通过不同的培肥方式对土壤腐殖质的元素组成进行调节。     

两种生物质炭对酸性紫色土腐殖质组成的影响

生物质炭的性状与原料中木质纤维含量密切相关，为探明不同原料生物质炭对土壤腐殖质组成的影响，选取玉米秸秆和紫茎泽兰分别作为纤维类和木质类原材料制备生物质炭，向酸性紫色土分别添加5%玉米秸秆生物质炭（MB）和5%紫茎泽兰生物质炭（EB），测定90 d室内培养期间土壤胡敏酸（HA）、富里酸（FA）、胡敏素（HM）含量以及HA光学性质和元素组成变化。结果表明：MB和EB的比表面积分别为2.32 m²·g^-1和0.72 m²·g^-1，总孔体积分别为42.71 mm³·g^-1和12.59 mm³·g^-1，碳与氢元素摩尔比（C/H）分别为1.91和1.46，氧、硫之和与碳元素摩尔比[（O+S）/C]分别为0.09和0.16，玉米秸秆生物质炭的吸附能力更强、有机质成分的缩合度更大且氧化度更小。与对照（不添加生物质炭，CK）相比，培养结束后，施入生物质炭的土壤HA、FA和HM含量分别显著增加（P<0.05）65.59%~102.82%、85.87%~118.54%和137.25%~161.23%，MB处理对这3种腐殖质含量的增加效应较EB处理更明显。培养结束时添加生物质炭的土壤HA/土壤有机碳（SOC）降低13.53%~27.06%，FA/SOC降低6.81%~18.03%，其中EB处理的降低效应达显著水平；HM/SOC则增加4.58%~11.40%，其中MB处理的增加效应达显著水平。添加生物质炭的土壤HA色调系数（ΔlgK）增加2.40%~5.60%，HA的缩合度（C/H）降低3.51%~11.81%，（O+S）/C增加1.51%~8.74%。总体来看，施入生物质炭均能相对增加腐殖质各组分含量，降低C/H，提高HA的氧化度[（O+S）/C]，且纤维类原料（玉米秸秆）生物质炭的效果更明显。纤维类原料（玉米秸秆）生物质炭显著提高了稳定性较高的土壤胡敏素碳比例（HM/SOC），但降低了土壤HA的稳定性[HA的C/H降低，（O+S）/C增加]；木质类原料（紫茎泽兰）生物质炭显著降低土壤胡敏酸碳比例（HA/SOC）和富里酸碳比例（FA/SOC），对HM/SOC增加效益不显著，反之提高了土壤易分解有机碳比例。     

玉米植株残体培肥土壤的研究

采用土培试验对玉米植株残体施人后土壤理化性质及有机质组成的变化进行了分析。结果表明，土壤加入玉米植株残体后，土壤微生物生物量碳和氮含量提高，土壤的阳离子交换量增强，松结合态、联结合态和紧结合态腐殖质的含量增加，稳结合态腐殖质的相对含量下降，土壤中五碳糖和六碳糖的含量升高，土壤胶体活性变强。玉米秸秆和根茬对土壤的培肥作用存在差异。     

有机物料对白土土壤胡敏酸结构特征的影响

【目的】研究有机物料施入对白土土壤的腐殖质含量组成和胡敏酸(HA)结构特征的影响,为明确不同腐殖质组分对土壤肥力的影响提供理论依据。【方法】供试土壤为江苏省溧阳市南渡镇"白土改良大田示范试验核心区"的南方中低产水稻土(白土)。试验设秸秆还田(ST)、施有机肥(OM)和对照(CK,不施有机物)3个处理,培肥3年。同时采集试验田周围相邻的江苏省耕地质量监测点(2007~2013年)的每年施化肥(LAF)和长期不施肥(NF)的两种处理土壤进行比对研究。分别测定土壤的基本理化性质及其腐殖质含量的组成,并提取土壤胡敏酸(HA)固体样品利用红外光谱和元素分析来进行结构表征。【结果】秸秆还田和施有机肥处理的有机碳、全氮含量明显高于对照;与对照相比,施有机物料土壤HA的E4/E6比值增加,且秸秆还田施有机肥对照。红外光谱显示,试验区域和耕地监测点的不同处理土壤HA均在1650 cm-1处(酰胺I带)和1550 cm-1处(1500~1580 cm-1酰胺II带伸缩振动)有特征吸收。施有机肥和秸秆还田处理土壤HA的2920/1720、2920/1650比值显著大于对照。在元素组成上,OM、ST处理的土壤腐殖质(HA)中C、H、N的含量比均高于CK,相对长期施化肥(LAF)和不施肥(NF)的土壤有明显提高,而氧元素的含量呈降低的趋势;OM和ST处理土壤HA的[H]/[C]和[O]/[C]原子数比均低于CK;与LAF和NF处理相比,试验区域各处理土壤腐殖质的[H]/[C]和[O]/[C]原子数比均有明显降低。【结论】有机物料施入土壤后可增加土壤有机碳含量,改善土壤理化性质,提高作物产量和品质,且施入土壤的有机物料可转化为新的腐殖质,降低土壤的腐殖化程度。土壤腐殖质(HA)的红外光谱分析说明,白土土壤HA具有明显的酰胺类化合物特征。有机物料施入后使得土壤脂族性增强,羧基量减少,芳香度降低;秸秆还田和施有机肥处理与对照相比,土壤HA的[H]/[C]和[O]/[C]比均有下降的趋势,且HA的氮素含量明显增加,这显示有机物料施入后白土土壤腐殖质发生"脱水"过程,同时也反映了白土土壤腐殖质形成的特征。     

小麦玉米秸秆连续还田对土壤有机质红外光谱特征及氮素形态的影响

通过6年的田间定位试验,探讨了CK(不施肥,秸秆不还田)、SF(施肥,秸秆不还田)、T1(施肥,玉米秸秆还田)、T2(施肥,小麦秸秆还田)、T3(施肥,玉米小麦秸秆还田)5种处理对土壤氮素形态和有机质红外光谱特征的影响。结果显示:与SF相比较,T1、T2、T3处理使土壤有机氮含量分别增加3.7%、15.9%和18.5%,土壤无机氮含量分别减少15.5%、15.9%和24.0%,其中铵态氮分别降低11.3%、6.0%和12.0%,土壤硝态氮含量分别降低19.3%、22.9%和32.1%;与SF相比较,T1、T3处理土壤有机质(SOM)的C/N分别降低2.8%和1.4%,T2处理SOM的C/N提高1.4%;C/O分别提高9.2%、12.8%和12.1%;而H/C分别降低4.6%、5.5%和4.6%。红外图谱分析显示,T1、T2、T3处理引起3 500~3 200 cm?1处的吸收峰增加,2 924 cm?1处出现了新的弱峰,表明SOM的脂肪族特征增加,且以1 630 cm?1处为中心的宽带吸收峰强度明显增加,SOM芳构化程度增强。研究表明,施肥显著提高了土壤有机氮、无机氮含量,以及土壤有机质的C/N和C/O。而秸秆还田降低了土壤无机氮,提高了土壤有机氮,使SOM的C/N、H/C下降,C/O上升,同时提高了SOM中酚基、羟基、羧基、芳香碳和酰胺含量,其中以小麦、玉米秸秆双季还田的效果最为显著。     

农业有机废弃物对黑土腐殖质元素组成的影响

以循环农业为指导,选取5种具有代表性的农业有机废弃物(秸秆、牛粪、鸡粪、菌渣、树叶)与化肥配施进行腐解培养还田试验,以不施肥(CK)和单施化肥(NPK)作为对照,系统的研究了3a后它们对黑土腐殖质胡敏酸(HA)、富里酸(FA)和胡敏素(HM)元素组成的影响。结果表明,与CK相比,NPK处理并没有对黑土腐殖质元素组成产生明显影响。不同种类有机废弃物与化肥配施可显著提高HA的N、H和O元素含量,降低C元素含量,其中牛粪与化肥配施处理结果不同;5种配施处理均降低了HA的缩合度,且有利于HA中含氮基团的形成。配施处理提高了FA的C和N元素含量,降低O元素含量,但FA的缩合度几乎不变,其中,牛粪和菌渣与化肥配施处理对FA的元素组成影响具有相似性。无论单施化肥还是配施处理,HA的[O]/[C]原子个数比均小于FA,说明FA中含有较多的烷氧基和羧基。配施处理使HMi的H元素含量降低,而O元素含量升高,且各处理之间差异显著;同时提高了HMc的芳香度,使其结构变复杂,以鸡粪与化肥配施作用最为显著。由此可见,有机废弃物与化肥配合施用均对黑土腐殖质元素组成产生了一定的影响,显著优于单施化肥,具有良好的培肥效果,其中以牛粪和秸秆与化肥配施较好,菌渣、树叶及鸡粪与化肥配施次之。     

MINERALIZATION AND CORN RECOVERY OF 15NITROGEN FROM BLACK OATS RESIDUES TREATED WITH HERBICIDES

Nitrogen (N) mineralization from black oat residues (Avena strigosa), with or without previous application of herbicides, and its utilization by corn crop were investigated. The experiments were performed in a completely randomized setup, with three treatments and ten replicates. The treatments were: A) control - corn grown in soil with residues of black oats harvested without herbicide application; B) glyphosate - corn grown in soil with residues of glyphosate-desiccated black oat; and C) glufosinate - corn grown in soil with residues of black oat previously desiccated with glufosinate-ammonium. The remaining black oat residues on the soil surface were smaller in the control treatment than in glyphosate and glufosinate treatments. Black oat residues from the control treatment released 30% and 20% more carbon (C) and nitrogen (N), respectively, than from herbicide treatments. Microbial biomass carbon, total and mineral soil N arising from black oat residues were reduced by herbicide management. Black oat residues treated with glyphosate reduced corn total-N by 16%; however, dry mass yield was not affected by the treatments. Herbicide application on black oat reduced the total amount of residue-released nitrogen in the corn kernels, leaves and the whole plant. Net nitrogen mineralization from black oat residues is affected by the application of glyphosate or glufosinate-ammonium.     

Rates of decomposition of plant residues and available nitrogen in soil, related to residue composition through simulation of carbon and nitrogen turnover

The dynamics of inorganic N in soil following the application of plant residues depends on their composition. We assumed that all plant materials are composed of similar components, each decomposing at a specific rate, but differ in the proportions of the various components. The NCSOIL model that simulates C and N turnover in soil was used to link the rates of residue decomposition to their composition, defined as soluble, cellulose-like and lignin-like C and N, and thereby integrate short and long-term effects of residues on available N dynamics in soil. Five plant residues in a wide range of C:N ratios were incubated in soil for 24 weeks at 30 °C, during which C and N mineralization were measured. The materials with large C:N ratios (corn, rice hulls and wheat straw) were also incubated with NH₄⁺-N to avoid N deficiency. The residues were analyzed for total and soluble C and N. The partitioning of insoluble C and N between cellulose- and lignin-like pools was optimized by best fit of simulated C and N mineralization to measured results. The decomposition rate constants of the soluble and lignin-like pools were assumed to be 1.0 and 10⁻⁵ d⁻¹, respectively, and that of the cellulose-like pool, obtained by model optimization against mineralization of cellulose with NH₄⁺-N in soil, was 0.051 d⁻¹. The optimized, kinetically defined lignin-like pool of all residues was considerably larger than lignin contents normally found in plant residues by the Van Soest procedure. Gross N mineralization of tobacco and rape residues was similar, but N recovery from tobacco was larger, because a larger fraction of its C was in the lignin-like pool. N in rice hulls, corn and wheat residues was mostly recalcitrant, yet rice hulls did not cause N deficiency, because most of its C was recalcitrant too. The soluble components of the residues had strong short-term effects on available N in soil, but the cellulose-like pool was equally important for short and medium-term effects. Soluble and cellulose-like C were 29 and 42% of total C, respectively, in corn and 7 and 50% in wheat. Maximal net inorganic N losses, measured in both residue treatments after 2 weeks, were 42 mg g⁻¹ C applied as corn and 31 mg g⁻¹ C applied as wheat, or 84 and 110 mg g⁻¹ decomposed C of corn and wheat, respectively. Rice hulls immobilized N slowly, but by the end of 24 weeks all three residues immobilized 26-27 mg N kg⁻¹ C applied. The different dynamics of N immobilization demonstrated the need to determine the decomposability of C and N rather than their total contents in plant residues.     

无机氮素加入量对玉米秸秆分解过程中棕壤氨基糖含量的影响

在室内恒温(25℃)培养条件下,通过气相色谱法研究高C/N比玉米秸秆降解过程中微生物来源的氨基糖含量及其占有机质比例的变化及其对无机氮素添加水平(0, 60.3, 167.2, 701.9 mg•N•kg-1土,依次标记为N0, Nlow, Nmed, Nhigh)的响应情况。结果表明：在玉米秸秆分解过程中,土壤中的氨基糖含量及其对有机质贡献的比例随着无机氮素供应水平的增加而增加,即以微生物代谢物形式截获的有机碳/氮相应增多。Nmed和Nhigh处理中氨基糖积累量显著高于Nlow和N0处理。不同微生物来源的氨基糖受外源氮素的影响情况不同,胞壁酸比氨基葡萄糖更易于受到土壤中碳氮供给的影响,具有相对较快的转化速率;而在数量上氨基葡萄糖对土壤有机质的贡献比例显著高于前者;氨基半乳糖在土壤中的积累过程较为缓慢,受外源无机氮素添加水平的影响并不明显。可见,在高C/N比作物残体分解过程中,无机氮素的供应水平是影响土壤中氨基糖积累转化的重要因素之一。但是,过多的无机氮素施入并不能被微生物完全同化利用,因此秸秆还田的土壤中必须要考虑有效氮素的水平问题。     

Evaluation of the fertilizer value and nutrient release from corn and soybean residues under laboratory and greenhouse conditions

Abstract

Laboratory and greenhouse studies were conducted on a moderately fertile Taloka (fine, mixed, thermic mollic Albaqualf) silt loam and a low fertility Leadvale (fine‐silty, siliceous, thermic typic Fragiudult) silt loam to evaluate nutrient release and fertilizer value of soybean [Glycine max (L.) Herr.] and corn (Zea mays L.) residues as compared to the inorganic fertilizer 13–13–13–13 (N‐P₂O₅‐K₂O‐S). Residues and the inorganic fertilizer were applied at 50 mg N/kg in a incubation study and at 25 and 50 mg N/kg in a greenhouse study. The incubation study indicted that carbon dioxide (CO₂) evolution and nitrogen (N) mineralization followed a identical sequence: soybean > corn residues, similar to residue N concentration and carbon/nitrogen (C/N) ratio sequence. Application of corn residues produced N immobilization in both soils (‐20 mg N/kg soil), whereas soybean increased inorganic soil N in the Leadvale soil (3 mg N/kg soil) and particularly in the Taloka soil (17 mg N/kg soil). The greenhouse study showed the superiority of the inorganic fertilizer over corn and soybean residues for sorghum‐sudan yield, and N, phosphorus (P), potassium (K), and sulfur (S) total uptake. No significant differences were found among the residues and between residues and the control with the exception of the higher soybean rate for total N uptake in the Taloka soil, and the higher corn and soybean residue rate in the Leadvale soil for total K uptake. It also appeared that soybean residues provided a substantial amount of N and S to sorghum‐sudan. Higher rates of both soybean and corn residues constituted a prime source of K, particularly in the Landvale soil which had a low exchangeable soil K level.     

Use of crop residues with alkaline slag to ameliorate soil acidity in an Ultisol

Information regarding the interaction between liming agents and crop residues on soil acidity amelioration is limited. A laboratory incubation study was undertaken to investigate the combined application of alkaline slag (AS, the major component is CaO) and crop residues with different C/N ratios and ash alkalinity content. Incorporation of amendments was effective in reducing soil exchangeable acidity and Al saturation and increasing exchangeable base cations (P < 0.05), but the effect of AS on soil pH adjustment was reduced when added with a high amount of residue with a low C/N ratio. Initial increases in soil pH were attributed to the release of alkalinity from the combined amendments and the mineralization of organic nitrogen (N). During subsequent incubation, the soil pH decreased because of nitrification. Crop residues with a high C/N ratio increased N immobilization and reduced net nitrification, resulting in a slight pH decrease. Crop residues with a low C/N ratio resulted in a sharp decrease in soil pH when applied with low levels of AS because of stimulated soil nitrification, whereas high AS had no consistent effect on net nitrification. Hence, compared to the control (pH = 4.21), a large increase in soil pH occurred, especially when peanut straw was applied at 10 g/kg (pH = 5.16). It is suggested that crop residues with high C/N ratio and also combined with a liming agent such as AS are preferred to ameliorate soil acidity. The liming effect of AS is likely to be negated if added in combination with residues with high N contents.     

控释尿素配施黄腐酸对小麦产量及土壤养分供应的影响

【目的】 控释尿素可调控氮素缓慢释放使其与作物养分吸收速率基本同步,黄腐酸可调控土壤与肥料养分转化,两者均能显著提高肥料利用率,然而控释尿素配伍黄腐酸对小麦的协同增效研究鲜有报道。本文研究控释尿素配施黄腐酸对小麦产量和土壤肥力的影响,为其科学施用提供依据。 【方法】 以小麦 (Triticum aestivum L.) 为试材进行了盆栽试验,供试土壤为棕壤。试验设不施氮 (CK)、尿素全量 (U)、尿素减量1/3(U2/3)、尿素全量及减量配施黄腐酸 (U + FA、U2/3 + FA)、控释尿素全量及减量 (CRU、CRU2/3)、控释尿素全量和减量配施黄腐酸 (CRU + FA、CRU2/3 + FA) 共9个处理。所有处理P₂O₅ 和K₂O施入量均为150 kg/hm2和75 kg/hm2,尿素全量处理为N 225 kg/hm2,黄腐酸处理黄腐酸用量为45 kg/hm2。控释尿素处理均为一次性基施,普通尿素处理于拔节期追施尿素,基追比为1∶1。于小麦苗期、返青期、拔节期、开花期和成熟期取0—20 cm土壤样品,测定土壤硝态氮、铵态氮含量,同时测定株高和叶片SPAD值,收获期调查了小麦产量和土壤养分含量。 【结果】 1) 控释尿素CRU、CRU2/3较等氮尿素U、U2/3处理产量平均显著增加7.3%,净收益显著提高24.9%;CRU2/3与处理U产量差异不显著;CRU + FA较CRU显著增产6.4%,净收益显著增加12.6%;与U2/3处理相比,U2/3 + FA显著增产10.6%;U + FA较U处理显著减产12.8%。2) 等氮条件下,CRU、CRU2/3处理与U、U2/3处理小麦株高、叶片SPAD值差异不显著,CRU + FA、CRU2/3 + FA与CRU、CRU2/3处理间差异均不显著。3) 拔节期,CRU、CRU2/3处理土壤硝态氮含量比等氮U、U2/3处理平均显著高出54.7%,CRU2/3处理与U处理差异不显著;配施黄腐酸处理U + FA、U2/3 + FA、CRU + FA、CRU2/3 + FA的土壤有效磷含量均呈现先降低后增加最后降低的趋势,拔节期CRU处理的土壤有效磷含量与U处理无显著差异,CRU2/3、U2/3 + FA的土壤有效磷含量较CRU处理显著提高了18.6% 和20.6%;拔节期U + FA、U2/3 + FA较等氮U、U2/3处理土壤pH平均显著降低了0.11个单位,其他时期U + FA和CRU + FA处理与等量单施化肥处理差异不显著。 【结论】 控释尿素配施黄腐酸可协同增效,满足小麦各生育期氮素需求,一次性基施显著提高小麦中后期土壤养分供应强度,显著提高了小麦产量、肥料利用率和净收益。      

有机物料对不同作物根系土壤腐殖质组成和结构的影响

为探讨施用有机物料后不同作物根系土壤腐殖质各组分含量和胡敏酸元素组成的变化情况,以吉林农业大学试验田培肥2a的黑土为研究对象,试验选取3种作物(玉米、大豆、白菜),每种作物设4种施肥处理,包括化肥(CK)、玉米秸秆配施化肥、树叶配施化肥和鸡粪配施化肥。采用腐殖质修改法提取水溶性物质(WSS)、胡敏酸(HA)、富里酸(FA)、胡敏素(HM),利用重铬酸钾外加热法测定腐殖质各组分有机碳含量,采用分光光度计法测定HA和FA的光学性质,通过光密度E_4/E_6值和元素组成分析HA的结构变化。结果表明:土壤总有机碳(TOC)和腐殖质各组分有机碳含量均表现为白菜玉米大豆。相比CK,配施有机物料后作物根系土壤TOC、WSS、HA含量分别显著增加5%~8%,34%~55%,8%~20%,FA含量变化不明显。相比树叶和鸡粪,秸秆可显著提高TOC含量;WSS在各物料之间差异不明显;HM含量表现为秸秆树叶鸡粪CK。有机物料对PQ值的影响因作物而异,秸秆和鸡粪对玉米、大豆根系土壤PQ值(HA占腐殖酸的比率)的影响相似,而鸡粪对白菜根系土壤PQ值的影响显著高于玉米秸秆。施用有机物料后HA的E_4/E_6未发生明显改变,FA的E_4/E_6显著提高。有机物料使根系土壤HA缩合度升高,分子结构更加复杂,且有利于HA含氮基团的形成,以秸秆处理作用最好。由此可见,有机物料具有良好的培肥效果,其中鸡粪对白菜根系土壤培肥效果最显著,秸秆与鸡粪对玉米、大豆根系土壤培肥效果相似,均显著高于化肥。     

Do combined applications of crop residues and inorganic fertilizer lower emission of N2O from soil?

Emissions of N₂O were measured following addition of ¹⁵N‐labelled residues of tropical plant species [Vigna unguiculata (cowpea), Mucuna pruriens and Leucaena leucocephala] to a Ferric Luvisol from Ghana at a rate of 100 mg N/kg soil under controlled environment conditions. Residues were also applied in different ratio combinations with inorganic N fertilizer, at a total rate of 100 mg N/kg soil. N₂O emissions were increased after addition of residues, and further increased with combined (ratio) applications of residues and inorganic N fertilizer. However, ¹⁵N‐N₂O production was low and short‐lived in all treatments, suggesting that most of the measured N₂O‐N was derived from the applied fertilizer or native soil mineral N pools. There was no consistent trend in magnitude of emissions with increasing proportion of inorganic fertilizer in the application. The positive interactive effect between residue‐ and fertilizer‐N sources was most pronounced in the 25:75 Leucaena:fertilizer and cowpea:fertilizer treatments where 1082 and 1130 mg N₂O‐N/g residue were emitted over 30 days. N₂O (log_e) emission from all residue amended treatments was positively correlated with the residue C:N ratio, and negatively correlated with residue polyphenol content, polyphenol:N ratio and (lignin + polyphenol):N ratio, indicating the role of residue chemical composition in regulating emissions even when combined with inorganic fertilizer. The positive interactive effect in our treatments suggests that it is unlikely that combined applications of residues and inorganic fertilizer can lower N₂O emissions unless the residue is of very low quality promoting strong immobilisation of soil mineral N.     

无机氮素加入量对玉米秸秆分解过程中棕壤氨基糖含量的影响

作物秸秆还田作为一种调控土壤养分循环、减少氮肥损失、维持和提高土壤有机质水平的有力措施,越来越受到人们的重视[1-2]。还田的秸秆是微生物的碳源和能源,常导致土壤微生物量迅速增加,相应的微生物死亡率和微生物残体积累量也提高[3-4]。根据Appuhn等[5]对微生物细胞壁组分的