多氯联苯复合污染土壤的土著微生物修复强化措施研究

通过室内模拟试验,以不同C源、C/N比、水分及通透性为调控因子,对多氯联苯(PCBs)长期复合污染土壤的土著微生物强化修复进行了初步研究。结果表明,PCBs长期复合污染土壤中,在土壤水分含量为田间持水量的60%时,加入淀粉、葡萄糖和琥珀酸钠均在一定程度上增加了细菌和真菌数量,从而促进土壤中PCBs的土著微生物降解。不同种类的C源对PCBs污染土壤的土著微生物降解效果存在明显差异,且其降解效果与C源的施用剂量密切相关。当淀粉加入量为C1.0g/kg土时,土壤中PCBs的降解效果较好,而葡萄糖和琥珀酸钠加入量为C0.2g/kg土时,PCBs的降解效果明显。土壤C/N比为10:1的处理效果优于C/N比为25:1和40:1。土壤人为翻动有利于PCBs污染土壤中细菌和真菌的生长,提高土著微生物的代谢活性,从而促进土壤中PCBs的自然降解。这为进一步探讨加速土壤中PCBs降解的最适条件和研发POPs污染土壤的生物修复技术提供了科学依据。     

黄河生态系统特征及生态保护目标识别

根据黄河流域生态和环境状况,对黄河流域进行了生态分区,并阐述了各生态区的特征。在黄河河道湿地研究和黄河水体内顶级物种(鱼类)的调查分析基础上,确定了黄河不同类型生态保护区的生态保护目标:从流域角度而言,黄河上游的主要生态保护目标是植被和水源涵养林;中游应以水土保持为主,主要是恢复和保护植被;下游以保护湿地类型和维持湿地面积为重点,保护生物多样性和重要鸟类资源。黄河水生态系统中的主要保护物种应是珍贵经济鱼类北方铜鱼、河口洄游鱼类刀鱼、鲤鱼等,主要保护的生态区包括库区湿地、河口湿地、河道湿地以及景观娱乐水域等。     

鲁中水土保持生态修复区种子植物区系特征

 为鲁中石质山地水土保持生态修复过程中适宜植物种类的选择、保护与合理经营提供理论依据,对淄川峨庄水土保持生态修复区内植物区系组成和地理成分进行分析。结果表明:1)该植物区系内共有种子植物271种,隶属于61科157属,分别占我国种子植物区系科、属、种的17.28%、4.90%和0.998%,其中单种科和极小科（含29种）所含的种数占总种数的91.6%,单种属和含2～4种的属有161个,占总属数的96.18%,可以看出该研究区内植物科和属的分布是比较均匀和丰富的;2)该区植物区系温带成分,特别是北温带成分具有明显优势,热带性质属在该区系中占有较大的比例,说明该地区植物区系与热带植物区系有较密切渊源,并具有一定的亚热带热带区系的过渡性;3)该区植物区系的特有性较低。     

Chemical and biochemical properties in a silty loam soil under conventional and organic management

To improve soil fertility, efforts need to be made to increase soil organic matter content. Conventional farming practice generally leads to a reduction of soil organic matter. This study compared inorganic and organic fertilisers in a crop rotation system over two cultivation cycles: first crop broad bean (Vicia faba L.) and second crop mixed cropped melon-water melon (Cucumis melo-Citrullus vulgaris) under semi-arid conditions. Total organic carbon (TOC), Kjeldahl-N, available-P, microbial biomass C (Cmic), and N (Nmic), soil respiration and enzymatic activities (protease, urease, and alkaline phosphatase) were determined in soils between the fourth and sixth year of management comparison. The metabolic quotient (qCO₂), the Cmic/Nmic ratio, and the Cmic/TOC ratio were also calculated. Organic management resulted in significant increases in TOC and Kjeldahl-N, available-P, soil respiration, microbial biomass, and enzymatic activities compared with those found under conventional management. Crop yield was greater from organic than conventional fertilizer. The qCO₂ showed a progressive increase for both treatments during the study, although qCO₂ was greater with conventional than organic fertilizer. In both treatments, an increase in the Cmic/Nmic ratio from first to second crop cycle was observed, indicating a change in the microbial populations. Biochemical properties were positively correlated (p < 0.01) with TOC and nutrient content. These results indicated that organic management positively affected soil organic matter content, thus improving soil quality and productivity.     

Decomposition of pea and maize straw in Pakistani soils along a gradient in salinity

Maize straw and pea straw were added to five Pakistani soils from a gradient in salinity to test the following hypotheses: Increasing salinity at high pH decreases proportionally (1) the decomposition of added straw and (2) the resulting net increase in microbial biomass. In the non-amended control soils, salinity had depressive effects on microbial biomass C, biomass N, but not on biomass P and ergosterol. The ratios microbial biomass C-to-N and biomass C-to-P decreased consistently with increasing salinity. In contrast, the ergosterol-to-microbial biomass C ratio was constant in the four soils at pH>8.9, but nearly doubled in the most saline, but least alkaline, soil (pH 8.2). The addition of the maize and pea straw always increased the contents of microbial biomass C, biomass N, biomass P and ergosterol, but without clear effects of salinity. Highest mean contents of microbial biomass C and biomass N were measured at day 0, immediately after the straw was added. Straw amendments increased the CO₂ evolution rates of all five soils without any effect of salinity. The same was true for total C and total N in the two fractions of particulate organic matter (POM) 63–400 μm and >400 μm. Lowest percentage of straw-derived CO₂-C and highest recoveries of POM-C and POM-N were observed in the maize straw treatment and the reverse in the pea straw treatment. Yield coefficients were calculated for maize and pea straw based on the assumption that the balance gap between CO₂ and the amount of POM can be fully assigned to microbial products.     

Soil microbial, fungal, and nematode responses to soil fumigation and cover crops under potato production

Sodium N-methyldithiocarbamate (metam sodium) and 1,3 dichloropropene are widely used in potato production for the control of soil-borne pathogens, weeds, and plant parasitic nematodes that reduce crop yield and quality. Soil fumigation with metam sodium has been shown in microcosm studies to significantly reduce soil microbial populations and important soil processes such as C and N mineralization. However, few published data report the impact of metam sodium on microbial populations and activities in potato production systems under field conditions. Fall-planted white mustard (Brassica hirta) and sudangrass (Sorghum sudanense) cover crops may serve as an alternative to soil fumigation. The effect of metam sodium and cover crops was determined on soil microbial populations, soil-borne pathogens (Verticillium dahliae, Pythium spp., and Fusarium spp.), free-living and plant-parasitic nematodes, and C and N mineralization potentials under potato production on five soil types in the Columbia Basin of Eastern Washington. Microbial biomass C was 8–23% greater in cover crop treatments compared to those fumigated with metam sodium among the soil types tested. Replacing fumigation with cover crops did not significantly affect C or N mineralization potentials. Cumulative N mineralized over a 49-day laboratory incubation averaged 18 mg NO₃-N kg⁻¹ soil across all soil types and treatments. There was a general trend for N mineralized from fumigated treatments to be lower than cover-cropped treatments. Soil fungal populations and free-living nematode levels were significantly lowered in fumigated field trials compared to cover-cropped treatments. Fumigation among the five soil types significantly reduced Pythium spp. by 97%, Fusarium spp. by 84%, and V. dahliae by 56% compared to the mustard cover crop treatment. The percentage of bacteria and fungi surviving fumigation was greater for fine- than coarse-textured soils, suggesting physical protection of organisms within the soil matrix or a reduced penetration and distribution of the fumigants. This suggests the potential need for a higher rate of fumigant to be used in fine-textured soils to obtain comparable reductions in soil-borne pathogens.     

Compared effects of long-term pig slurry applications and mineral fertilization on soil denitrification and its end products (N2O, N2)

The long-term (9 years) effect of pig slurry applications vs mineral fertilization on denitrifying activity, N₂O production and soil organic carbon (C) (extractable C, microbial biomass C and total organic C) was compared at three soil depths of adjacent plots. The denitrifying activities were measured on undisturbed soil cores and on sieved soil samples with acetylene method to estimate denitrification rates under field or potential conditions. Pig slurry applications had a moderate impact on the C pools. Total organic C was increased by +6.5% and microbial biomass C by ≥25%. The potential denitrifying activity on soil suspension was stimulated (×1.8, P<0.05) 12 days after the last slurry application. This stimulation was still apparent, but not significant, 10 months later and, according to both methods of denitrifying activity measurement (r ²=0.916, P<0.01 on sieved soil; r ²=0.845, P<0.001 on soil cores), was associated with an increase in microbial biomass C above a threshold of about 105 mg kg⁻¹. The effect of pig slurry on denitrification and N₂O reduction rates was detected on the surface layer (0–20 cm) only. However, no pig slurry effect could be detected on soil cores at field conditions or after NO₃ ⁻ enrichments at 20°C. Although the potential denitrifying activity in sieved soil samples was stimulated, the N₂O production was lower (P<0.03) in the plot fertilized with pig slurry, indicating a lower N₂O/(N₂O + N₂) ratio of the released gases. The pig-slurry-fertilized plot also showed a higher N₂O reduction activity, which is coherent with the lower N₂O production in anaerobiosis.     

沼气工程对生态畜牧业系统的影响

以周口村为例，对周口村生态畜牧业系统进行能流分析，评估了引入沼气工程对村生态畜牧业系统的影响。结果表明，在生态畜牧业系统中引入沼气工程，可以将生产过程中产生的废弃物进行物质和能量的转化，实现对资源的多层次利用，形成了系统内部物质的良性循环，改善农村环境，促进经济、社会和生态环境的协调发展。     

基于地形梯度的三峡库区景观生态风险特征

景观生态风险评价可以较好地反映外界压力源对生态系统的负面影响,分析景观生态风险等级在地形梯度上的分布特征,可为三峡库区生态文明建设和人类活动管控提供科学依据。利用Landsat(OLI/ETM+)2000年、2010年、2020年影像数据,采用GIS网格法、克里金插值法构建景观生态风险指数模型,选取高程、坡度、地形位指数,基于地形梯度对三峡库区景观态风险等级特征进行了研究。结果表明：(1)三峡库区景观生态风险等级分布呈现较强的空间分异特征,各景观生态风险等级面积呈现动态变化。整个研究期间,低风险区、中风险区、高风险区面积增加,较低风险区和较高风险区面积减少。(2)景观格局发生改变的区域优势分布集中在地形位指数小于1.24的区域。景观生态风险等级变化类型以稳定型为主,其次是前期变化型、后期变化型、反复变化型、持续变化型,在前期和后期景观生态风险等级转化分别呈现为“较高—高—高”“较高—较高—中”型的转换特征。(3)景观生态风险等级地形梯度特征表现为库区上游的低风险区向地形位指数大于0.62的区域扩散较多,较低风险区的分布向地形位指数小于1.03的区域集中,库区中下游的较高风险区则主要向高...     

山西黄河流域不同土地利用类型NDVI时空变化及其对气温、降水的响应

[目的]了解山西黄河流域不同土地利用类型NDVI时空变化及其对气温、降水的响应关系,对该流域生态保护、修复和高质量发展具有重要的意义。[方法]基于1998—2018年NDVI数据,利用NDVI变化趋势、变异系数、空间自相关等方法,对山西黄河流域不同土地利用类型NDVI时空变化特征及其与气温、降水的关系进行分析。[结果]不同土地利用类型NDVI变化趋势均呈向好态势,草地和林地覆盖状况优于整体水平。NDVI在空间上整体呈南北纵列、高低相间的分布格局,吕梁山和太岳山—中条山高,西部高原丘陵区和汾河谷地低。NDVI变化趋势的空间异质性显著,植被以显著改善为主。林地改善趋势的稳定性最好。NDVI表现出明显的空间集聚性特征,其中耕地NDVI变化趋势聚集特征最明显。不同土地利用类型NDVI对降水的敏感性强于气温。[结论]山西黄河流域不同土地利用类型NDVI时空变化差异显著,并对气温和降水存在响应关系,此研究将为该流域生态保护和建设提供更精准的植被恢复数据及其和气温、降水关系的基础资料。