产漆酶真菌对高寒草甸土壤有机质矿化特性的研究

为了了解产漆酶微生物真菌对高寒草甸土壤有机质的矿化作用及其特性，实验采用室内密闭静置培养法，对添加产漆酶真菌Marasmius tricolor 310b发酵粗酶液对高寒草甸土壤生物活性有机碳库的影响进行了研究。结果表明：与对照组相比，添加产漆酶真菌Marasmius tricolor 310b发酵粗酶液后，在整个培养期内土壤CO₂释放量和微生物生物量碳含量随培养时间的延长，呈现不断下降的趋势，35 d后趋于稳定；在整个培养周期，微生物呼吸熵的变化总体呈对数降低趋势，处理组符合方程y=-9.964ln （x）+32.281（R²=0.9744），对照组符合方程y=-9.788ln （x）+28.683（R²=0.95），处理组土壤CO₂的累计释放量始终高于对照组（P<0.05），说明菌株310b促进了土壤有机质矿化作用。土壤有机碳含量在培养前期开始降低，但差异不显著，15 d后处理组的土壤有机碳含量低于对照组（P<0.05），说明不同阶段产漆酶真菌对有机质的周转速率不同，推测产漆酶真菌对有机质的转化作用与土壤环境条件有关。     

长期施肥对黑土呼吸过程的影响

土壤呼吸是土壤有机C矿化分解,释放无机养分的重要生物化学过程。对公主岭地区长期有机肥(不施有机肥、施中量和高量有机肥处理)与化肥(不施化肥、施用N、NP、NPK化肥)配合施用的12个处理的黑土进行室内好气培养(196天),采用一级动力学方程模拟土壤的呼吸过程,结果表明,有机肥和化肥的施用能显著增加土壤呼吸释放的CO2 -C的累积量,提高土壤中潜在矿化的有机碳含量及其占土壤有机质的比例,促进土壤有机质中无机养分的释放,有利于提高土壤养分的有效性,改善黑土的供肥状况。有机肥与NPK化肥配合施用效果更为明显。     

Impacts of anthropogenic N additions on nitrogen mineralization from plant litter in exotic annual grasslands

Urban regions of southern California receive up to 45 kg N ha^-1 y^-1 from nitrogen (N) deposition. A field decomposition study was done using ¹⁵N-labelled litter of the widespread exotic annual grass Bromus diandrus to determine whether elevated soil N is strictly from N deposition or whether N mineralization rates from litter are also increased under N deposition. Tissue N and lignin concentrations, which are inversely related in field sites with high and low N deposition, determine the rate at which N moves from plant litter to soil and becomes available to plants. The effect of soil N on N movement from litter to soil was tested by placing litter on high and low N soil in a factorial experiment with two levels of litter N and two levels of soil N. The litter quality changes associated with N deposition resulted in faster rates of N cycling from litter to soil. Concentrations of litter-derived N in total N, NH₄⁺, NO₃⁻, microbial N and organic N were all higher from high N/low lignin litter than from low N/high lignin litter. Litter contributed more N to soil NH₄⁺ and microbial N in high N than low N soil. At the end of the study, N mineralized from high N litter on high N soil accounted for 46% of soil NH₄⁺ and 11% of soil NO₃⁻, compared to 35% of soil NH₄⁺ and 6% of soil NO₃⁻ from low N litter on low N soil. The study showed that in high N deposition areas, elevated inorganic soil N concentrations at the end of the summer N deposition season are a result of N mineralized from plant litter as well as from N deposition.     

Phosphorus and nitrogen dynamics during field incubations in forest and fallow subarctic soils

A knowledge of the nutrient dynamics that occur with land use changes, e.g., in clearing forests for farmland, is useful in choosing the most efficient soil and fertilizer management practices. To determine net in situ P and N mineralization and nitrification rates of forest floor materials and their nutrient value for agricultural crops, plastic bags containing different materials (moss, O horizon, and A horizon) collected from a subarctic black spruce (Picea mariana Mill.) forest were incubated for 2 years in their respective forest horizons and at 7.5 cm depth in a nearby fallow field. Net amounts of P and N mineralized were highest in moss and were similar in forest and field when the temperature and moisture content were similar, but smaller in forest when the water content was higher. Net nitrification was negligible in O and A horizon material but significant in moss during the 2nd year, occurring sooner and producing higher NO _inf3 ^sup- levels in the field (171 mg ha^-1) than in the forest (13 mg ha^-1). Moss P and N mineralization rates were correlated in the fallow field. Temperature, moisture content, and substrate quality were important factors controlling P and N dynamics of forest floor materials in a subarctic fallow field and native forest. In subarctic regions, incorporation and mineralization of forest floor materials could provide an early source of N and P (70 and 17 kg ha^-1, respectively) for succeeding agricultural crops.     

Nitrogen availability in some Wisconsin forests: comparisons of resin bags and on-site incubations

Summary Estimates of ammonium and nitrate availability in conifer and hardwood forests using an ion exchange resin (IER) bag method and with on-site incubations of soil cores in buried bags were compared. Correlations between the two methods were generally high. Correlation coefficients (r) between IER nitrate and buried-bag mineralized nitrate ranged from 0.87 to 0.92. Both methods also correlated well with aboveground net primary production, litter fall N content, and fine root biomass. The major differences between the methods related to the relative importances of ammonium and nitrate forms of available N. The IER method indicated that both ammonium and nitrate were important on all sites, with nitrate predominating in most soils. The buried-bag results indicated that available N was primarily in the form of nitrate (all ammonium was oxidized), but that nitrate was insignificant on infertile sites.     

菜地土壤氮素矿化和硝化作用的特征

采用培养试验对南京郊区 6 对菜地土和水稻土的土壤 N 素矿化和硝化作用特征进行了研究。菜地土为相同类型水稻土改种蔬菜约 20 年的土壤。结果表明,培养 28 天期间,6 对供试土壤中有 4 对土壤都是菜地土壤矿化 N 量低于相同类型水稻土,其日矿化速率也低于相应的水稻土,而其他 2 对供试土壤之间无明显差异。大多数菜地土的土壤硝化率低于相应的水稻土。培养28 天时的矿化率和硝化率与土壤 pH、速效 P 呈显著相关。     

Relations Between Net Nitrogen Mineralization and Soil Characteristics Within an Arable Field

Within-field variations in plant-available soil nitrogen (N) are likely to be affected by differences in soil characteristics. To study this, a 3- year field investigation was conducted during 1998-2000 on a 15 ha arable field in Sweden with considerable within-field soil texture variability. In 34 plots soil N uptake by crops, net nitrogen mineralization (Nm) during the growing season and soil mineral N in spring and shortly after harvest were determined. Beside these parameters, topography, soil organic matter content (SOM), clay content, pH(H 2 O) and grain yield were recorded. The variations in Nm were considerably large both within the field and between years. The within-field variation in Nm could partly be explained by the variation in SOM and clay content (adjusted coefficient of determination = 0.23, P <0.001). The pattern in Nm differed between years, partly because of seasonal variations in soil moisture. For these reasons, the pattern of Nm is difficult to predict without seasonal adjustments.     

Nitrogen mineralization in sandy loam soils under an intensive double-cropping forage system with dairy-cattle slurry applications

Nitrogen (N) mineralization and soil mineral N contents were measured at 2-week intervals over a 2-year period (June 1994–May 1996) on two different sites in the North West region of Portugal. The experiment was established in fields, which had for many years been under a double-cropping forage system with maize from May to September and a winter crop (mixture of cereals and Italian ryegrass) during the rest of the year. In addition to N fertilizers, dairy-cattle slurry was applied regularly at the sowing of each crop. On this intensive forage system, quantification of N released from slurry, crop residues and soil organic matter becomes important when better N use efficiency and reduced environmental impact from agricultural practices are required. Net N mineralization rates of the 0–10 cm soil layer fluctuated considerably between consecutive incubation periods and ranged from −0.88 to 1.87 mg N kg⁻¹ day⁻¹ with annual average rates of between 0.41 and 0.65 mg N kg⁻¹ day⁻¹. The total N mineralized in the 10 cm depth soil layer reached values between 122 and 224 kg N ha⁻¹ year⁻¹, showing that mineralization was a very important N source for the crops. The amounts of N released during the cold season (November–February) were equivalent to 27–48% of the yearly total. Regression analysis indicated that seasonal variation in N mineralization was only poorly explained by soil moisture and temperature. The changing balance during the year between soil moisture and temperature will contribute to the relatively constant N mineralization rates. Soil mineral N contents during the maize crop were high and exceeded the nutrient requirements for the optimum yield of this crop. Under the climatic conditions of the region and due to the poor development of the winter crop plants at the time, the mineral N left in the soil after the maize crop and released by mineralization during the cold season is particularly vulnerable to nitrate leaching losses.     

土壤氮素矿化研究进展

本文总结了有机氮矿化方面的研究成果,对土壤有机氮矿化不同数学模式进行了归纳和分类,分析了模型的适用条件,提出了今后研究的思路。     

采用15N同位素稀释法研究不同层次土壤氮素总转化速率

采用15N同位素稀释方法,开展短期(7天)室内培养实验,估算了一水稻土0~20、20~60和60~90 cm土层土壤主要N素转化过程的总转化速率,结果表明,标记N溶液加入后2 h内各土层土壤的总矿化、硝化、固定速率显著高于其他时间段(p<0.01)。2 h后,矿化速率在小范围内起伏。0~20 cm土层土壤N素的硝化速率随培养时间延长而降低,另外两层土壤则基本保持稳定,硝化速率的变化与硝化作用底物NH4+-N浓度的变化呈显著正相关。值得注意的是,外源无机N溶液加入后2 h内,大量NH4+-N和NO3--N被固定,并认为N素的非生物固定起主导作用。2 h后,出现了N素在固定与再矿化间反复转换的现象。实验结果表明,与净转化速率相比总转化速率能更好地描述单个N素转化过程,但由于外源N加入对N素转化的影响、再矿化作用以及忽略了N素转化过程中的气体损失、DNRA(硝态氮异化还原为铵)过程等,本研究结果与真实值间存在一定差异。