侵蚀型红壤植被恢复后土壤养分含量与物理性质的变化

为了解侵蚀型红壤植被恢复后土壤养分含量与物理性质的变化状况,采集了植被恢复17年和9年的两个定位试验点土壤样品。分析结果表明：侵蚀型红壤植被恢复后土壤养分含量明显增加。恢复17年的木荷、杉木林0～0．2m土层土壤全氮和有机质含量分别比对照增加了3．92倍、2．96倍、5．80倍和3．52倍,土壤有效养分中土壤有效磷含量增加幅度最大。植被恢复后土壤物理性质得到极大改善．表现在土壤容量明显降低,土壤总孔度、通气孔度增加和大于1mm大团聚体与大于0．25mm水稳性团聚体总量的增加。总的来看,恢复17年的木荷和恢复9年的黑麦草两处理．土壤物理性质改善最为明显．此两处理0～0．2m表层土壤容量比对照区降低了27．9％和20．41％,大于0．25mm水稳性团聚体总量分别比对照区增加了31．09％和29．96％,土壤总孔度和通气孔度分别是对照区的1．34倍、1．25倍、2．59倍和2．14倍。     

两种氮水平下CO2浓度升高对冬小麦生长和氮磷浓度的影响

预计到 2 1世纪末期大气CO2 浓度将会比目前水平增加 1倍 ,约 70 0 μmolmol- 1 左右。因此CO2 浓度升高对作物的影响研究十分重要。本文探讨在两种氮 (N)水平下 ,CO2 浓度升高对冬小麦 (TriticumaestivumL cv Xinong 872 7)生长和地上部N、磷 (P)浓度的影响及原因。试验设 3 5 0 μmolmol- 1 和 70 0 μmolmol- 1 两种CO2 浓度水平和 45kghm- 2 和 90kghm- 2 两种N肥施用水平。结果表明 ,CO2 浓度升高 ,冬小麦株高和叶面积指数 (LAI)均增加 ,净同化率 (NAR)值增加 ,叶面积比率 (LAR)下降 ,比叶重 (SLW )不增加。高CO2 浓度对相对生长率 (RGR)的影响因施N水平而异 ,低N时RGR不增加 ,高N时明显增加。CO2 浓度增加 ,小麦抽穗提早 7～ 8d ,叶鞘、茎杆和地上部干物重提高 ,叶片、叶鞘和茎杆N、P浓度降低 ,但叶片、叶鞘和茎杆N、P吸收量增加均不明显。CO2 浓度升高 ,氮磷利用效率 (NUE和PUE)提高 ,而对相对氮磷累积速率 (RNAR和RPAR)影响不大。高CO2 浓度冬小麦体内N、P浓度下降是由于稀释效应以及NUE和PUE提高之故。     

Recovery of cover-crop-N in the soil-plant system in the Guinea savannah zone of Ghana

In order to understand the efficiency of residue-N use and to estimate the minimum input required to obtain a reasonable level of crop response, it is important to quantify the fate of the applied organic-N. The recovery of N from ¹⁵N-labelled Crotalaria juncea was followed in the soil and the succeeding maize crop. Apparent N recovery (ANR) by maize from unlabelled Crotalaria juncea, Crotalaria retusa, Calopogonium mucunoides, Mucuna pruriens and mineral fertilizer at three locations were also evaluated. The maize crop recovered 4.7% and 7.3% of the ¹⁵N-labelled C. juncea-N at 42 days after sowing (DAS) and at final harvest, respectively. The corresponding ¹⁵N recovery from the soil was 92.4% and 58.5%. The highest mean ANR of 57.4% was with mineral fertilizer, whereas the mean ANR of 14.3% from C. retusa was the lowest. A large pool substitution and added-N interaction effect was observed when comparing N recovery from the labelled and unlabelled C. juncea. The amount of residue-N accounted for by the isotope dilution method at 42 DAS was 97.1% and at final harvest 65.8%. The large residue-N recovery in the soil organic-N pool explains the residual effect usually observed with organic residue application.     

控释氮肥对水稻的增产效应及提高肥料利用率的研究

田间试验在日本山形县鹤冈市进行 ,探讨了树脂包膜类控释氮肥基施与尿素、硫铵分次施肥对单季稻的增产效应 ;应用15N示踪法研究了不同施肥处理水稻的吸氮模式及肥料利用率。结果表明 ,移栽稻以尿素与控释氮肥 (LPS-100)按 1∶1混合基施产量最高 ,分别比尿素和硫铵分次施肥增产23.6%和9.2% ;直播稻以LP-100基施产量最高 ,分别增产 9.2%和4.0% ;控释肥基施 ,水稻自移栽 (或直播 )至幼穗分化期吸氮量明显高于尿素或硫铵分次施肥。15N示踪研究表明 ,最高分蘖前水稻从尿素和硫铵基肥中吸收的氮素只占基肥氮总吸收量的 33%～ 45% ,水稻从基肥中吸收氮素可延续至抽穗期 ,而从LP-100中吸氮可持续至收获期。15N示踪法测得的氮素总回收率 ,以尿素处理最高 ,硫铵和LP-100接近 ;差减法测得的氮素总回收率以LP-100为最高 ,尿素 /LPS-100、尿素、硫铵三者接近 ;基肥的氮素回收率以LP-100硫铵 尿素。尿素 /LPS-100和LP-100一次基施 ,氮素生理效率和农学效率明显高于尿素和硫铵 ,是高产的主要原因     

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。     

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。     

不同形态氮肥对磷肥生物有效性的影响

利用盆栽试验研究了潮土中不同形态氮肥对磷肥生物有效性的影响。结果表明:不同形态氮肥处理均有抑制油菜生长初期磷素累积的作用,氯化铵处理抑制作用最突出,其次是尿素,再次是硫酸铵、硝酸铵和硝酸钙处理;油菜生长后期不同形态氮肥处理均逐渐显著促进油菜的磷累积,但氯化铵处理的促进作用仍然低于其它氮肥处理,这与不同形态氮肥处理对油菜生长的影响较一致。土壤有效磷含量受不同形态氮肥处理影响较小,而水溶性磷含量因施用不同形态氮肥均表现显著地下降,氯化铵和硫酸铵处理使土壤水溶性磷下降较多,硝酸铵、硝酸钙和尿素处理使土壤水溶性磷下降较少。     

Comparative effects of applying leguminous and non-leguminous green manures and inorganic N on biomass yield and nitrogen uptake in flooded rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

The beneficial role of green manures in rice production is generally ascribed to their potential of supplying plant nutrients, particularly nitrogen (N). However, the mechanisms through which green manures enhance the crop productivity are poorly understood. Pot experiments were conducted using a ¹⁵N-tracer technique: (1) to compare the biomass production potential of sesbania (Sesbania aculeata Pers.) and maize (Zea mays L.) as green manuring crops for lowland rice and (2) to compare the effect of the two types of green manure and inorganic N on the dry matter accumulation and N uptake by two rice (Oryza sativa L.) cultivars, viz. IR-6 and Bas-370. Although maize produced three times higher shoot biomass compared with sesbania, the latter showed higher N concentration; and thus the total N yield was similar in the two types of plants. Applying the shoot material of the two plants to flooded rice significantly enhanced the dry matter yield and N uptake by the two rice cultivars, the positive effects generally being more pronounced with sesbania than with maize amendment. The difference in the growth-promoting potential of the two plant residues was related more to an increased uptake of the native soil N rather than to their direct role as a source of plant-available N. A positive added nitrogen interaction (ANI) was observed due to both plant residues, the effect was much more pronounced with the application of sesbania than with maize residues. In both rice cultivars, inorganic N also caused a substantial ANI, particularly at higher application rate. Losses from the applied N were 2–3 times lower from sesbania, compared with maize treatment. Green manuring with sesbania also caused much lower N losses than the inorganic N applied at equivalent or higher rates. The overall benefit of green manuring to rice plants was higher than inorganic N applied at comparable rates. The two rice cultivars differed in their response to green manuring, IR-6 generally being more responsive than Bas-370.     

The influence of nitrogen fertilisation on bacterial activity in the rhizosphere of barley

The effect of nitrogen addition on the activity of rhizosphere bacteria was studied using barley seedlings. Three different nitrogen sources were added to the soil (nitrate, ammonium and ammonium+nitrate) at four different concentrations (0, 100, 300 and 500 mg N kg⁻¹ soil) and the plants were allowed to grow for 6 weeks. The bacterial activity was estimated by measuring thymidine and leucine incorporation into bacteria extracted using homogenisation-centrifugation. Bulk soil bacterial activity was low compared with that of rhizosphere bacteria. Nitrogen addition did not affect the activity of the bulk soil bacteria, indicating that the activity was not nitrogen limited. The thymidine and leucine incorporation rates of rhizosphere bacteria decreased when ammonium or ammonium+nitrate was applied compared with the non-amended controls. No effect on bacterial activity was found following nitrate addition. There was a significant positive correlation between rhizosphere bacterial activity and rhizosphere pH. Shoot length following ammonium treatment was significant lower than in the non-amended control, while nitrate and ammonium+nitrate addition had no effect. This indicates that the varying effects due to nitrogen sources on rhizosphere bacterial activity were not due to effects on plant growth.