土壤矿物钾的释放及其在植物营养中的意义

本文对土壤钾的形态、矿物钾释放的影响因素及钾的固定、土壤含钾矿物与土壤供钾能力间关系、矿物钾的植物有效性进行了综述 ,表明土壤钾素从有效性的角度进行划分时 ,不能仅把速效性钾和1mol/L热硝酸提取的缓效性钾列为作物吸钾的主要来源 ,而忽视矿物钾的作用 .     

带状种植系统养分供给与利用研究进展

带状种植是1种以固N植物篱为核心、农作物与植物篱相间种植的农林复合经营模式，植物篱通过修剪避免对农作物遮光，其枝叶作为覆盖物和有机肥，可提高土壤肥力。阐述了植物篱枝叶N素矿化和利用、枝叶有机碳矿化及其对土壤有机质的影响以及固N植物篱对土壤P素和其他矿质元素的供给状况，并评价了该模式下土壤养分和有机质动态。     

江淮丘陵区水稻钾、氮吸收特性与施钾效应研究

江淮地区水稻田间小区施钾效应试验结果表明,施钾能明显提高水稻产量,改善水稻生育性状,在氮磷肥充足时,钾肥的增产效果极其显著。水稻钾吸收量明显以秸秆吸钾量为主,约为籽粒吸钾量的5倍。N来自土壤的数量为120.30 kg hm-2;K2O来自土壤的数量为72.83kg hm-2。NPK全素施钾处理吸钾总量平均高出NP处理48.79%,籽粒和秸秆分别平均增加9.21%和56.8%;说明钾吸收量增加对秸秆产量贡献明显小于对籽粒产量的贡献。除最高施钾量和不施氮处理外,其余处理均出现不同程度钾素亏缺,说明在不施氮肥或氮肥不足的情况下,水稻对肥料钾的吸收量也相应减少。本试验钾肥(K2O)产投比以NPK2处理最高为2.54。综上所述,本地区同等肥力土壤,水稻钾肥推荐用量为120kg hm-2,根据土壤钾素平衡状况,水稻施钾量可适当增加。     

作物氮素营养诊断方法研究进展

改进氮素管理对农业生产和生态环境保护具有重要的意义。本文综述了几种氮素营养诊断方法的优缺点,重点介绍了主动遥感光谱仪G reenSeeker的特点,及其进行氮素诊断的机理、研究进展和其在国内的应用前景。     

种植沉水植物和疏浚底泥对氮磷营养水平的影响

通过对五里湖沉积物进行不同疏浚深度(30 cm和60 cm)沉水植物恢复实验研究,结果表明:对于未种植水草的疏浚沉积物来说,疏浚并不能很好地降低水体中氮磷水平,在一定时间内,氮磷水平有恢复增加的可能;种植菹草的疏浚沉积物,除在开始阶段氮磷水平有所增加外,随时间的延长,对上覆水中的氮磷有很好的控制。所以将底泥疏浚与沉水植物的恢复相结合起来,在控制湖泊内源污染方面将达到更好的效果。     

C and N natural abundance of the soil microbial biomass

Stable isotope analysis is a powerful tool in the study of soil organic matter formation. It is often observed that more decomposed soil organic matter is ¹³C, and especially ¹⁵N-enriched relative to fresh litter and recent organic matter. We investigated whether this shift in isotope composition relates to the isotope composition of the microbial biomass, an important source for soil organic matter. We developed a new approach to determine the natural abundance C and N isotope composition of the microbial biomass across a broad range of soil types, vegetation, and climates. We found consistently that the soil microbial biomass was ¹⁵N-enriched relative to the total (3.2 ‰) and extractable N pools (3.7 ‰), and ¹³C-enriched relative to the extractable C pool (2.5 ‰). The microbial biomass was also ¹³C-enriched relative to total C for soils that exhibited a C3-plant signature (1.6 ‰), but ¹³C-depleted for soils with a C4 signature (−1.1 ‰). The latter was probably associated with an increase of annual C3 forbs in C4 grasslands after an extreme drought. These findings are in agreement with the proposed contribution of microbial products to the stabilized soil organic matter and may help explain the shift in isotope composition during soil organic matter formation.     

Tillage-induced environmental conditions in soil and substrate limitation determine biogenic gas production

Tillage changes soil environmental conditions and controls the distribution of residues in the soil, both actions that affect the production and emission of soil biogenic gases (CO₂, N₂O, and CH₄). The objective of this study was to determine how tillage-induced environmental conditions and substrate quality affect the mineralization rate of easily metabolizable compounds and the subsequent production of these gases. Carbon compounds, with and without nitrogen, were applied to soil cropped to maize under tilled and no-till systems. Following substrate application in the spring and summer, biogenic gases were measured periodically at the soil surface (flux) and within the profile (concentration) at 10-, 20-, and 30-cm depths (i.e., within, at the bottom of, and below the plough layer). Strong CO₂ and N₂O responses to sucrose and glycine in both the field and the laboratory indicate that the soil was C- and N-limited. Surface fluxes of CO₂ and N₂O were greater in soils amended with glycine than with sucrose and were greater in tilled than no-till soils. Transient emission of CH₄ following the addition of glycine was observed and could be attributed to inhibition of N mineralization and nitrification processes on CH₄ oxidation. Laboratory and field measurements indicated that the larger substrate-induced CO₂ emission from the tilled soils could not be attributed to differences in the total biomass or the basal respiratory activity of the soils. Thus, there appears to be no underlying difference in the functional capacity of the microbial communities under different tillage regimes. Comparison of gas profiles indicates relative accumulation of CO₂ at depth in soils under no-till, as well as greater decline in profile CO₂ content with time in the tilled compared to the no-till soil. These results support the conclusion that greater CO₂ efflux from the tilled soils resulted from more rapid gas diffusion through the profile. Hence, the observed differences in gas fluxes between tilled and no-till soils can be attributed to differences in physical environment.     

接种蚯蚓对潮土氮素矿化特征的影响

在室内恒温（20℃）培养，间歇破坏性采样（于培养后第2、6、13、20、27、41、55天采样）的条件下，研究蚯蚓活动对土壤中氮素矿化特征的影响。共设置4个处理：（1）对照处理-不接种蚯蚓不添加秸秆（S）；（2）仅接种蚯蚓不添加秸秆处理（E）；（3）不接种蚯蚓仅添加秸秆处理（O）；（4）接种蚯蚓并添加秸秆处理（0E）。结果表明：在整个培养时期中，仅接种蚯蚓处理（E）的土壤铵态氮和硝态氮含量均较对照处理（S）有显著提高（P〈0．05），分别较同期对照处理（S）高出0．54-5．71倍和0．04-2．01倍；接种蚯蚓添加秸秆处理（OE）的土壤中的铵态氮含量较同期仅添加秸秆处理（0）增高了0．42-7．26倍，并达到显著性差异（P〈0．05），但两处理的硝态氮含量无显著性差异（P〉0．05）。从整体水平来看，无论是否添加秸秆，接种蚯蚓处理（E，OE）的土壤矿质氮水平均较相应的对照处理（S，O）有显著提高（P〈0．05），到培养55d时，分别增加了1．93倍和2．36倍。仅接种蚯蚓处理（E）的土壤氮素矿化速率和累积矿化速率较对照处理（S）有显著提高（P〈0．05）；添加秸秆后，无论是否接种蚯蚓，土壤累积矿化速率均为负值，表现为对土壤矿质氮的净固定，而从土壤氮素矿化速率的变化来看，前期的各个时间段中主要表现为矿质氮的净固定，后期逐渐表现为一定程度的矿化。此外，仅接种蚯蚓处理（E）的全氮含量除了培养2d外，其他培养时期均与对照处理（S）有显著差异（P〈0．05），到培养55d时，其全氮含量较同期对照处理（S）增高了6．55％。相关性分析结果表明，在仅接种蚯蚓处理（E）中，培养前后蚯蚓鲜重的减少量与土壤全氮含量之间存在极显著正相关（P〈0.01），根据一元线性方程将蚯蚓损失的鲜重换算为蚯蚓体损失的氮量后发现，在整个培养期中蚯蚓体本身排泄的氮大约占土壤全氮含量增加量的百分比为42％-100％。     

土壤中可溶性有机氮含量及其影响因素研究

研究了农田和日光温室2个生态系统土壤中可溶性有机氮(SON)的含量及施肥和栽培模式对其含量的影响。结果表明,农田和日光温室土壤中SON的含量平均分别为39.19 mg kg-1和320.16 mg kg-1,分别占可溶性总氮(TSN)的80%和73%,说明SON是土壤氮素中不可忽视的氮素组分。不同栽培模式对土壤中SON的含量及其占TSN的比例的影响因生育时期的不同而异。覆草显著增加了小麦拔节期0~5 cm土层土壤中SON的含量,覆膜各土层SON含量均较常规模式有所提高;开花期覆草和覆膜模式土壤中TSN和SON含量较拔节期的显著下降。施用无机氮肥对土壤中SON的含量无显著影响。     

土壤无机氮解吸模型及其特征值生物效应研究

8种土壤126个氮素解吸实验表明,解吸模型C=ClH-a能模拟土壤铵态氮、硝态氮的解吸动态规律,其中有125个实验的复相关系数达到极显著水平。盆栽试验和田间试验结果表明,对生长期较短的空心菜、菜心和莴苣而言,土壤氮素可解吸量Q和土壤溶液氮素初始浓度C li与供试蔬菜的氮素吸收量和产量之间有显著的抛物线型关系,为评价土壤氮素生物有效性和临界指标提供了一种新方法。