长期施用有机无机肥对潮土微生物群落的影响

微生物群落结构是土壤生态系统变化的预警及敏感指标,可用于表征土壤质量及其生态功能变化。本文用磷脂脂肪酸法研究了有机肥和NPK肥料长期施用对华北平原潮土微生物群落结构的影响及其变化特征。结果表明：长期施用有机和无机肥不仅提高了土壤有机碳、全氮、速效磷和速效钾等含量,改善了土壤酸碱度,而且显著增加了土壤微生物生物量,其中以有机肥的效果最为明显,增幅达到15.4%。长期施用肥料有机肥也改变了土壤微生物的群落结构,提高了细菌数量,降低了放线菌含量,而对真菌数量没有明显影响,导致真菌与细菌的比值下降。主成分分析表明,长期施用有机肥的土壤,细菌以含a19:0、br14:0、16:1w5c和17:1w9而真菌以含18:1w10c的微生物为优势种群,NPK处理土壤中细菌以含18:1w7、i19:0、br18:0、16:1w7t和a15:0的微生物为优势种群,CK处理中没有明显的优势种群。     

The influence of previous plant cultivation on soil nitrification

Summary Studies have been made on the effect of previous cultivation of different plants on soil nitrification. Greater effects were obtained when the soil was incubated at 29°C and under natural conditions in the open that at 18°C. The rate of nitrification was usually lower in previously uncultivated than cultivated soils except in the cases of pea, timothy grass and onion when increased rates were found.     

The effects of mineral fertilizer and organic manure on soil microbial community and diversity

The effects of mineral fertilizer (NPK) and organic manure on phospholipid fatty acid profiles and microbial functional diversity were investigated in a long-term (21-year) fertilizer experiment. The experiment included nine treatments: organic manure (OM), organic manure plus fertilizer NPK (OM + NPK), fertilizer NPK (NPK), fertilizer NP (NP), fertilizer NK (NK), fertilizer N (N), fertilizer P (P), fertilizer K (K), and the control (CK, without fertilization). The original soil was extremely eroded, characterized by low pH and deficiencies of nutrients, particularly N and P. The application of OM and OM + NPK greatly increased crop yields, soil pH, organic C, total N, P and K, available N, P and K content. Crop yields, soil pH, organic C, total N and available N were also clearly increased by the application of mineral NPK fertilizer. The amounts of total PLFAs, bacterial, Gram-negative and actinobacterial PLFAs were highest in the OM + NPK treatment, followed by the OM treatment, whilst least in the N treatment. The amounts of Gram-positive and anaerobic PLFAs were highest in the OM treatment whilst least in the P treatment and the control, respectively. The amounts of aerobic and fungal PLFAs were highest in the NPK treatment whilst least in the N and P treatment, respectively. The average well color development (AWCD) was significantly increased by the application of OM and OM + NPK, and the functional diversity indices including Shannon index (H ^′ ), Simpson index (D) and McIntosh index (U) were also significantly increased by the application of OM and OM + NPK. Principal component analysis (PCA) of PLFA profiles and C source utilization patterns were used to describe changes in microbial biomass and metabolic fingerprints from nine fertilizer treatments. The PLFA profiles from OM, OM + NPK, NP and NPK were significantly different from that of CK, N, P, K and NK, and C source utilization patterns from OM and OM + NPK were clearly different from organic manure deficient treatments (CK, N, P, K, NP, NK 6 and NPK). Stepwise multiple regression analysis showed that total N, available P and soil pH significantly affected PLFA profiles and microbial functional diversity. Our results could provide a better understanding of the importance of organic manure plus balanced fertilization with N, P and K in promoting the soil microbial biomass, activity and diversity and thus enhancing crop growth and production.     

化肥减量配施有机肥对棉田土壤微生物生物量、酶活性和棉花产量的影响

在甘肃河西走廊棉区进行连续3年的定位施肥试验,研究了化肥减量20%～40%并配施不同有机肥对棉田土壤微生物生物量、酶活性和棉花产量的影响。结果表明:与单施化肥相比,化肥减量配施有机肥能显著提高土壤细菌和放线菌数量,降低土壤真菌数量,化肥减量配施普通有机肥加生物有机肥(COBF₂)处理土壤细菌最多,较单施化肥(CF)在棉花蕾期、铃期和吐絮期分别提高了84.6%、57.1%和43.5%,化肥减量配施生物有机肥(CBF₂)处理放线菌数量最多,较CF在棉花蕾期、铃期和吐絮期分别提高了28.2%、32.7%和32.2%,CBF₂土壤真菌数量最低,较CF在棉花蕾期、铃期和吐絮期分别降低了35.8%、29.3%和13.4%。化肥减量配施有机肥提高了土壤细菌/真菌、放线菌/真菌和脲酶、过氧化氢酶、蔗糖酶、碱性磷酸酶活性,其中COBF₂对酶活性的提升最有效。化肥减量配施有机肥提高了棉花单株铃数,对棉花长势、地上干物质积累有一定的促进作用,COBF₂棉花产量最高,籽棉和皮棉产量分别较CF提高了14.2%和10.9%,增产显著。综合分析土壤微生物生物量、酶活性和棉花产量,COBF₂处理,即化肥减量40%配施1800 kg·hm^-2普通有机肥和600 kg·hm^-2生物有机肥效果最佳。     

Influence of five pyrethroid insecticides on microbial populations and activities in soil

Laboratory tests were conducted to determine the effects of five pyrethroid insecticides—permethrin (FMC 33297) [3-phenoxybenzyl (±)-3-(2,2-dichlorovinyl)-2,2-dimethylcyclopropanecarboxylate]; FMC 45498 [(S)--cyano-3-phenoxybenzyl-(R)-cis-2-(2,2-dibromovinyl)-3,3-dimethylcyclopropanecarboxylate]; Shell WL 41706 [(±)--cyano-3-phenoxybenzyl 2,2,3,3-tetramethylcyclopropane-carboxylate]; Shell WL 43467 [(±)--cyano-3-phenoxy benzyl (±)-cis,trans-2-(2,2-dichlorovinyl)-3,3-dimethylcyclopropanecarboxylate]; and Shell WL 43775 [(±)--cyano-3-phenoxybenzyl (±)-2-(4-chlorophenyl)-3-methylbutyrate]—at 0.5 and 5g/g on microbial populations and activities in a sandy loam. The insecticides had antimicrobial activity in early stages of incubation. The populations recovered after 2 to 4 weeks and stimulatory effects on populations were also observed in later stages. No inhibition of acetylene (C₂H₂) reduction was evident with any of the insecticides. However, WL 43467 at both concentrations and permethrin and WL 41706 at 5 g/g increased nitrification after 4 weeks. Soil microbial respiration, as indicated by oxygen consumption, increased with increasing concentration of insecticides, suggesting the possibility of microbial degradation of the insecticides. Dehydrogenase activity showed that none of the insecticides inhibited formazan (2,3,5-triphenyltetrazolium formazan) formation, whereas urease activity was stimulated in most cases. The studies indicated that some of the pyrethroid insecticides may exert transient effects on populations and activities of the microflora in a sandy loam, but these were short-lived and minor in nature.     

Effects of potassium azide on soil microbial populations and soil enzymatic activities.

Preplant applications of potassium azide (KN3) to pine nursery beds were evaluated for effect on the soil microflora and on soil enzyme activity where either plastic-sealing or water-sealing techniques were used. Two weeks after incorporation of azide (0-224 kg/hs), soil samplings revealed reduced populations of bacteria and fungi and a corresponding decline in invertase and amylase activities. These effects were proportionate to the amount of azide used and were more pronounced in plastic-sealed plots. Phosphatase activity was little affected. Five weeks after azide application, bacterial populations were higher in treated plots than in controls. Greater numbers of bacteria were recorded from plastic-sealed plots and highest populations coincided with plots receiving the highest rates of azide, regardless of the sealing technique. Fungal populations at this sampling were generally less in treated plots than in the controls, but were higher under plastic seal. At this time, changes in invertase and amylase activities did not correspond to increased microbial numbers. Sixteen weeks after applications of KN3, bacterial populations in treated plots did not differ significantly from controls, but remained higher in plastic-sealed than water-sealed plots. Fungal populations under plastic seal had changed little and remained significantly lower in treated water-sealed plots than in controls. The earlier recorded reduction in invertase and amylase activities was still evident at the final sampling;     

种植转Bt基因抗虫棉对土壤生物学活性的影响

采用温室盆栽实验,研究了种植转Bt基因棉（苏抗103）和同源常规棉（苏棉12）对根际土壤生物学活性的影响。结果表明：与对照常规棉相比,种植转Bt基因棉对根际土壤脱氢酶、碱性磷酸酶、蔗糖酶和土壤呼吸的影响因生育期而异,土壤脲酶、蛋白酶和微生物量C在各生育期均没有显著差异;土壤蔗糖酶、土壤脱氢酶和土壤呼吸分别只在苗期（苏抗103〉苏棉12,增幅为25．5％）、花铃期（苏抗103〉苏棉12,增幅为21．6％）、花铃期（苏抗103〉苏棉12,增幅为36．1％）存在显著差异;土壤磷酸酶在花铃期和吐絮期活性显著下降（降幅分别为22．1％和32．9％）。     

有机物料与锌肥配施对石灰性土壤锌有效性及形态转化的影响

采用尼龙网袋田间填埋培养法探究了外源施锌条件下石灰性土壤Zn有效性及形态转化对不同有机物料(作物秸秆、生物菌肥、黄腐酸和腐熟鸡粪)的响应.结果表明:与对照相比,Zn肥单施和与有机物料配施均显著提高了土壤全Zn含量(7.2%~13.8%)和DTPA-Zn含量(2.1~2.8倍).在施Zn条件下,有机物料对土壤全Zn和DTPA-Zn的贡献量表现为腐熟鸡粪>生物菌肥>玉米秸秆>黄腐酸,但外源锌的DTPA-Zn转化率以添加秸秆和生物菌肥处理最高.与单施Zn肥相比,有机物料与Zn配施处理显著提高了土壤有机质含量,促进了松结有机态Zn的形成,进而提高了土壤Zn转移因子,降低了Zn分配指数.不同物料与Zn肥配施土壤Zn有效性及形态转化之间存在差异,这可能与有机物料自身性质如腐熟度和含Zn量有关.尽管秸秆与Zn配施对DTPA-Zn含量的提升效果不及生物菌肥或腐熟鸡粪与Zn配施,但综合考虑环境和经济效益,其仍是改善缺锌石灰性土壤Zn有效性的最佳选择.     

生物有机肥对猕猴桃土壤酶活性和微生物群落的影响

采用田间试验,研究了不施肥、施用生物有机肥、传统有机肥和化肥对猕猴桃土壤酶活性、微生物群落结构及其代谢的影响.结果表明: 施用生物有机肥在猕猴桃生育期内可显著提高土壤蔗糖酶和荧光素二乙酸酯水解酶活性,分别比对照高出12.2%～129.4%、18.8%～87.4%.施用生物有机肥在膨大期和成熟期的土壤脲酶和酸性磷酸酶活性显著高于其他处理.Biolog微平板法测定结果表明,生物有机肥在猕猴桃生育期内提高了土壤微生物的平均每孔颜色变化率,增加了物种多样性、丰富度和均匀度,改变了微生物对6大类碳源的相对利用率,降低了微生物对氨基酸类碳源的相对利用能力,提高了微生物对多酚类和多胺类碳源的相对利用能力;主成分分析表明,对土壤中微生物起分异作用的碳源种类主要是糖类、氨基酸类和羧酸类.     

Effects of repeated cultivation of transgenic Bt cotton on functional bacterial populations in rhizosphere soil

The impact of multiple-year (0–5 years) cultivation of transgenic Bacillus thuringiensis (Bt) cotton on the functional bacterial populations in rhizosphere soil was investigated. The transgenic Bt + CpTI cotton line SGK321 and a non-Bt cotton line Shiyuan321 were planted in four fields in which Bt cotton had been continuously cultivated for 0, 1, 3, and 5 years. Rhizosphere soil samples were collected at the seedling, squaring, flower and boll, and boll-opening stages of cotton. Numbers of bacteria involved in nitrogen-fixing, organic phosphate-dissolving, inorganic phosphate-dissolving, and potassium-dissolving were measured with cultivation-dependent approaches. The data presented here showed no consistent statistically significant differences in the numbers of different groups of functional bacteria between rhizosphere soil of Bt and non-Bt cotton in the same field, and no obvious trends in the numbers of the various group of functional bacteria with the increasing duration of Bt cotton cultivation. These studies suggest that multiple-year cultivation of transgenic Bt cotton may not affect the functional bacterial populations in rhizosphere soil.     

减氮配施有机肥对滴灌棉田土壤生物学性状与团聚体特性的影响

本文通过新疆绿洲棉田连续4年定位施肥试验,研究了不同处理[对照CK、常规化肥CF、减氮配施普通有机肥OF(80%CF+OF和60%CF+OF)、减氮配施生物有机肥BF(80%CF+BF和60%CF+BF)]对土壤生物学性状和团聚体特性的影响,探讨了土壤生物学性状与有机碳及团聚体之间的关系.结果表明:与单施化肥(CF)相比,配施生物有机肥的80%CF+BF和60%CF+BF处理均可显著提高土壤脲酶、碱性磷酸酶、蔗糖酶、β-葡萄糖苷酶、多酚氧化酶和芳基硫酸酯酶活性,其增幅分别为55.6%～84.0%、53.1%～74.0%、15.1%～38.0%、38.2%～68.0%、29.6%～52.0%和35.4%～58.9%,高量配施有机肥效果优于低量配施.各施肥处理明显提高了土壤基础呼吸,具体表现为BF>OF>CF>CK.与CF相比,60%CF+BF处理的土壤有机碳、微生物生物量碳分别增加22.3%和43.5%,但微生物生物量碳氮比显著下降.>0.25 mm的水稳性团聚体在配施普通有机肥的80%CF+OF、60%CF+OF处理比对照(CK)分别增加7.1%和8.0%.80%CF+BF处理较80%CF+OF处理机械稳定性团聚体的几何平均直径(GMD)增加了9.2%.冗余(RDA)分析和聚类分析均表明,减氮增碳可明显调控滴灌棉田土壤生物活性与团聚体结构.连续4年化肥减量配施有机肥或生物有机肥,提高了土壤有机碳含量,并对团聚体稳定性和生物学性状有协同改善效应,是维持与提升绿洲滴灌棉田土壤肥力的有效途径.     

氮添加土壤微生物群落结构影响微生物碳利用效率

尽管近年来中国氮(N)沉降水平逐渐趋于稳定,但中国东南地区N沉降相比于其他地区仍处于较高水平。N沉降对陆地生态系统碳循环过程的影响不容忽视。微生物碳利用效率(CUE)是指微生物将吸收的碳转化为生物量碳的效率,高微生物CUE意味着高土壤有机碳存储潜力。因此,探究N沉降背景下微生物CUE的变化将有助于进一步认识陆地生态系统土壤碳存储的变化。然而,目前关于N沉降下微生物群落结构的变化如何影响微生物CUE鲜有报道。在福建省泉州市戴云山国家级自然保护区的罗浮栲林通过N添加模拟N沉降。实验共包括三个N添加处理：对照(CT,+0 kg hm^-2 a^-1)、低氮(LN,+40 kg hm^-2 a^-1)和高氮(HN,+80 kg hm^-2 a^-1)。测定不同处理土壤基本理化性质、微生物生物量、酶活性和CUE,并使用高通量测序对微生物群落结构和多样性进行测定。结果表明,N添加显著影响微生物CUE,随着N添加水平的增加,CUE逐渐增加;相反,土壤pH、可提取有机碳(EOC)和微...     

有机肥对设施番茄周年栽培土壤环境和产量的影响

日光温室早春茬-秋冬茬连作栽培番茄是我国北方设施蔬菜周年栽培的主要种植模式之一。以该种植模式下农户习惯施肥量为对照(CK,100%化肥),设15%(T₁)、30%(T₂)、45%(T₃)、60%(T₄)、75%(T₅)、100%有机肥替代化肥(T₆)处理,探讨有机肥替代部分化肥对土壤环境和番茄产量的影响。结果表明: 土壤细菌数量随有机肥用量的增加总体呈现上升趋势;放线菌数量以T₁处理最多,为12.12×10⁶ cfu·g^-1。有机肥替代部分化肥可提高土壤脲酶活性,降低过氧化氢酶活性,提高土壤有机质、速效磷和速效钾含量,说明有机肥对改善设施土壤理化性质、促进养分积累具有显著效果。其中,T₁处理蔗糖酶活性和速效磷含量最高,分别为1.36 mg·^-1、305.4 mg·kg^-1,T₂处理的速效钾含量最高,为582.6 mg·kg^-1。T₂处理>0.25 mm水稳性团聚体含量最大,为94.2%。各有机肥处理可改善番茄果实品质,提高产量,其中,T₁处理番茄红素含量最高,达5.69,糖酸比以T₁和T₂处理最好,分别为8.19、8.70;产量以T₁处理最高,T₂处理次之,较CK分别增产16.6%、5.8%。综上,农户习惯施肥量中15%~30%的化肥用有机肥替代为该种植模式下较佳的施肥措施。     

Soil microbial activities in a constructed soil reed-bed under cheese-dairy farm effluents

Soil microbial activities in a reed-bed used for effluent purification of a small cheese-dairy farm under a Mediterranean climate were described and studied. This work aims to demonstrate (i) whether certain enzyme activities used as bioindicators of dairy waste degradation (beta-galactosidase and protease) vary over time, which might influence organic matter degradation and (ii) whether specific microbial communities are selected through contact with the discarded effluent using community level catabolic profiles (CLCPs). beta-galactosidase and protease activities were followed in a 14-month monitoring experiment. These enzyme activities were strongly expressed during the whey-discarding period from February to May. CLCPs using Biolog Ecoplate showed great microbial diversity, as described by Shannon-Weaver index, and no difference was observed in microbial diversity between areas at the receiving end of the reed-bed (where effluent was discarded) and those at the opposite end. This may be explained by successive environmental factors which made enzyme activities vary: whey discarded from February to May and Mediterranean climate conditions (drying-rewetting effects on summer). Microbial enumeration using epifluorescence microscopy also showed a pattern linked to Mediterranean conditions with a drastic decrease in biomass during summer drought. These results on functional biodiversity were correlated with high purification yields: the minimum decrease in Biological Demand in Oxygen was 84% and that in suspended solids was 75%.     

土壤微生物生物量氮对不同腐熟度有机肥的响应及对土壤矿质氮的调控作用

为探究化肥配施不同腐熟度有机肥对土壤微生物生物量氮(MBN)的影响及土壤MBN调控土壤矿质氮的作用,将堆肥过程与土壤培养试验相结合,设置常规化肥对照(CK)、化肥+腐熟度为50%(种子发芽指数为50%,下同)的有机肥(CO1)、化肥+腐熟度为80%的有机肥(CO2)、化肥+腐熟度为100%的有机肥(CO3)共4个处理,测定土壤MBN、矿质氮(NH₄⁺-N、NO₃^--N)、净硝化速率、微生物生物量碳(MBC)、可溶性有机碳(DOC)、脲酶和蛋白酶,并揭示土壤MBN对矿质氮的调控作用。结果表明: 到培养结束时,与CK处理相比,有机肥处理(CO1、CO2、CO3)的土壤MBN、NH₄⁺-N含量显著提高50.1%～62.4%、109.9%～147.1%,土壤NO₃^--N、净硝化速率显著降低23.3%～46.8%、26.2%～51.5%,土壤MBC、DOC含量、脲酶和蛋白酶活性分别显著提高33.8%～69.6%、7.4%～20.8%、11.2%～69.0%、9.4%～25.1%,且CO2、CO3的变化幅度均显著高于CO1。冗余分析和结构方程模型显示,较高腐熟度有机肥(腐熟度≥80%)对MBC、MBN、NH₄⁺-N含量、脲酶和蛋白酶活性具有正向调控作用,对土壤净硝化速率具有负向调控作用。化肥配施较高腐熟度有机肥可以明显增加土壤MBN,提升脲酶、蛋白酶活性,增加NH₄⁺-N含量,降低土壤净硝化速率。因此,在实际应用中,建议采用腐熟度为80%的有机肥与化肥配施,减少有机肥生产成本及时间,实现有机固体废弃物的资源化利用。     

三江源地区高寒草原土壤微生物活性和微生物量

为了揭示青藏高原高寒草地土壤微生物活性和微生物量碳、氮情况,同时探讨气候变化对土壤微生物的影响,以青藏高原腹地三江源自然保护区高寒草原土壤为研究对象,选择土壤质地、植被类型基本一致,海拔高度不同（3400—4200m）的4个样地,分析测定了土壤微生物（细菌、真菌、放线菌和部分生理功能微生物群）数量、土壤微生物量（碳、氮）、土壤酶（纤维素酶、蛋白酶、脲酶用、蔗糖酶）活性。结果表明：研究区域均含有较丰富的土壤有机碳和养分,微生物数量多少为细菌>放线菌>真菌,主要功能微生物菌群数量为氨化细菌>好气性固氮菌>硝化细菌>亚硝化细菌,样地间的微生物生物量碳、氮含量差异显著。相关性分析表明,除与亚硝酸细菌具有弱正相关性外,海拔高度与其它因子均具有负相关性,其中与细菌和氨化细菌具有极显著负相关性,与好气性固氮菌和硝酸细菌具有显著负相关性。因此,温度的升高可能明显的影响了三江源地区高寒草原的土壤微生物活性。     

An evaluation of carbon disulphide as a sulphur fertilizer and as a nitrification inhibitor

There was little release of extractable SO₄-S during four weeks from CS₂ applied by injecting into two S-deficient soils. In this incubation experiment, the rate of CS₂ was 30 μg S g⁻, placement was injection at 9 cm depth, soil temperature was 20°C, and soil moisture tension was 33 kPa. The yield of barley forage after seven weeks in the greenhouse showed only small increases from 10 or 30 μg S g⁻¹ of CS₂ as compared to Na₂SO₄, on the two soils. While CS₂ supplied little plant available S in the short term, it was an effective inhibitor of nitrification. In the laboratory, or in the field, the injection of CS₂ (with N fertilizers) at a point 9 cm into the soils either stopped or reduced nitrification. In one laboratory experiment, 35 μg of CS₂ g⁻¹ of soil with urea reduced nitrification for at least four weeks; and in another experiment 20 μg of CS₂ g⁻¹ of soil with aqua NH₃ nearly or completely inhibited nitrification at 20 days. In two field experiments, 3 and 12 μg of CS₂ g⁻¹ of soil (or 6 and 24 kg ha⁻¹) with aqua NH₃ inhibited nitrification from October to the subsequent May. In addition, CS₂ reduced the amount of ammonium produced from the soil N, both in these two field experiments and in the laboratory experiments. That is to say, CS₂ injected at a point, inhibited both nitrification and ammonification. In other field experiments, CS₂ at a rate of 10 kg ha⁻¹ was injected in bands 9 cm deep with urea in October, and by May there was still reduced nitrification. Less than half of the fall-applied urea alone was recovered as mineral N, but with the application of CS₂ the recovery was increased to three-quarters. The yield and N uptake of barley grain was increased where fall-applied banded urea or aqua NH₃ received banded CS₂, (NH₄)₂CS₃, or K₂CS₃. The average increase in yield from fall-applied fertilizer, from inhibitor with fall-applied fertilizer, and from spring-applied fertilizer was 800, 1370, and 1900 kg ha⁻¹, respectively. In the same order, the apparent % recovery of fertilizer N in grain was 24, 42, and 60.     

鱼蛋白有机液肥对小粉土酶活性和微生物生物量碳、氮的影响

采用恒温土壤培养方法,研究了4种不同鱼蛋白有机液肥施用量[0(对照)、0.5、1.5、2.5 ml·kg-1]条件下小粉土酶活性和微生物生物量碳、氮的变化,及其与土壤养分的相关关系.结果表明:在整个培养过程中,不同鱼蛋白有机液肥施用量处理下土壤pH值变化范围为7.07～7.31,与对照无显著差异;土壤磷酸酶活性显著增强,分别为对照的1.27、1.90、1.96倍;土壤脲酶活性分别比对照提高39.81%、78.06%、173.24%;蛋白酶活性比对照提高56.37%、108.29%、199.98%;土壤微生物生物量碳、氮均随肥料添加量的增加而逐渐增大,分别为对照的1.67、3.95、4.74倍和1.21、2.43、4.06倍.土壤脲酶和蛋白酶活性以及土壤微生物生物量碳、氮在不同施用量处理下达到峰值点的时间不同.土壤磷酸酶、脲酶和蛋白酶活性、土壤微生物生物量碳、氮与土壤养分均呈显著正相关.施用鱼蛋白有机液肥可以显著促进小粉土微生物的生长及酶活性的提高,从而促进土壤有机质的分解转化和速效养分的释放.     

秸秆还田土壤改良培肥基质和复合菌剂配施对土壤生态的影响

通过田间试验,研究水旱轮作（冬小麦-夏水稻）中水稻秸秆全量还田条件下土壤改良培肥基质和复合菌剂配施对小麦土壤养分、土壤物理结构和土壤生物学性质及土壤微生物区系的影响,为快速土壤培肥、提高中低产农田产量提供实践基础和技术支持。试验于江苏省盐城市滨海县黄河湾项目基地进行,共设置五个处理：①土壤改良培肥基质+复合菌剂+常规化肥（MOS+CMA+CF）;②复合菌剂+常规化肥（CMA+CF）;③土壤改良培肥基质+常规化肥（MOS+CF）;④常规化肥（CF）;⑤不施肥对照（CK）。对小麦返青期（S1）、拔节孕穗期（S2）和成熟期（S3）分别进行土壤理化性质、土壤酶活性、微生物量碳氮和微生物区系分析。结果表明,与CK相比,MOS+CMA+CF处理能够在短时期内提高土壤速效养分含量（其中速效氮提高了23.59%、速效磷提高了40.74%、速效钾提高了43.78%）,降低土壤容重,提高土壤孔隙度,显著提高土壤微生物量氮含量和土壤脲酶活性;同时,该处理还能在小麦返青期和拔节孕穗期增加土壤细菌和真菌多样性,提高微生物丰度,最终提高了小麦产量（与CK和CF相比,产量分别提高了149.29%和24.93%）。CMA+CF能够显著提高土壤纤维素酶活及土壤微生物量碳含量,表现出有较好的秸秆降解能力;并且在提高土壤理化指标含量、提高脲酶酶活、提高微生物量氮含量和小麦产量方面仅次于联合处理。由于MOS富含有机质,MOS+CF处理能够维持并提高土壤有机质含量、改善土壤物理环境。总之,短期内,MOS+CMA+CF处理提升土壤肥力,提高小麦产量的效果是最显著的;但CMA+CF处理在加速秸秆养分还田、改善土壤理化状况,增强微生物活性和丰富以及提高小麦产量方面也表现出优势,且复合菌剂经济方便有效,具有很好的田间技术推广价值。     

硝化抑制剂对蔬菜土硝化和反硝化细菌的影响

土壤N素循环主要是微生物驱动的转化过程,然而对其的驱动与调控机理了解还很不够。选取长沙黄兴镇蔬菜基地两种蔬菜土研究硝化抑制剂(DCD)对N素转化过程及功能微生物的影响。试验通过室内土壤培养,处理为单施尿素(CK)和尿素与硝化抑制剂双氰胺配合施用(DCD),重复3次。在培养过程中系统监测了土壤中NH₄⁺-N、NO₃^--N含量变化,同时采用荧光定量PCR(real-time PCR)方法研究硝化抑制剂对土壤中氮素转化功能基因丰度的影响。结果表明:在培养过程中DCD处理使两个供试土壤的NH₄⁺浓度稳定在较高水平,而NO₃^-浓度则明显低于对照;施用DCD导致土壤中硝化基因amoA丰度显著减少,而对16S rRNA和反硝化基因nirK丰度没有产生明显影响。因此,DCD在菜地土壤中主要通过抑制氨氧化细菌的繁衍来抑制硝化作用。