蓝藻沼肥对土壤的影响

采用不结球小白菜四季青盆栽实验,设置新鲜蓝藻(T1)、当年蓝藻发酵沼渣沼液(T2)、前一年蓝藻发酵沼渣沼液(T3)、化学肥料(T4)、空白对照(CK)5个施肥处理,研究了施用蓝藻发酵沼渣沼液对土壤的影响。实验结果表明T2和T3处理土壤全N含量相对处理前土壤(CK0)增加了49.1%和12.3%;土壤有效P含量相对CK0增加了52.3%和11.7%;土壤有机质含量相对CK0增加了33.3%和14.1%;土壤pH分别减少了0.16和0.23个单位,均有显著差异,同时植株产量和株高相对空白对照(CK)有显著提高。     

Differences in soil respiration between different tropical ecosystems

We examined the relationship between soil respiration rate and environmental determinants in three types of tropical forest ecosystem—primary forest, secondary forest, and an oil palm plantation in the Pasoh Forest Reserve on the Malaysian Peninsula. In August 2000, the soil respiration rate and environmental factors (soil temperature, soil water content, soil C and N contents, biomass of fine roots, and microbes) were measured at 12–16 points in research quadrats. Soil respiration rates were 831 ± 480, 1104 ± 995, 838 ± 143, 576 ± 374, and 966 ± 578 (mean ± S.D.) mg CO₂ m⁻² h⁻¹ in the primary forest canopy and gap site, secondary forest canopy and gap site, and oil palm plantation, respectively. Although the mean soil respiration rates in the three forest ecosystems did not differ significantly, differences were evident in the environmental factors affecting the soil respiration. The major causes of spatial variation in soil respiration were fine root biomass, soil water content, and soil C content in the primary and secondary forests and oil palm plantation, respectively.     

传统耕作和免耕的红壤生态系统土壤动物种群的分异

In a field experiment ,the popultions of major soil fauna groups including earthworms,enchytraeids,arthropods and nematodes were examined in conventional tillage(CT) and no-tillage(NT) red soil ecosystems to evaluate their responses to tillage disturbance.Earthworms,macro- and micro-arthropods were stimulated under NT with earthworms showing the highest population increase by four times ,while enchytraeids and nematodes favored CT system predicting certain adaptability of these animals to plow-disturbed soil envi-ronment ,On the basis of relative response index it was found that soil fauna was more sensitive to tillage than soil resource base(C and N pools) and microflora.The population structure of soil fauna was also affected by tillage treatments.Analysis on nematode trophic groups showed that bacteria-feeding and plant parasitic nematodes were more abundant in CT soil whereas the proportions of fungivores and onmivore-predators increased in NT soil.Possible reasons for the differentiaion in both size and structure of the fauna populaion were discussed and the ecological significance involved in these changes was emphasized.     

Temperature sensitivity of soil respiration in different ecosystems in China

Understanding the sensitivity of soil respiration to temperature change and its impacting factors is an important base for accurately evaluating the response of terrestrial carbon balance to future climatic change, and thus has received much recent attention. In this study, we synthesized 161 field measurement data from 52 published papers to quantify temperature sensitivity of soil respiration in different Chinese ecosystems and its relationship with climate factors, such as temperature and precipitation. The results show that the observed Q₁₀ value (the factor by which respiration rates increase for a 10 °C increase in temperature) is strongly dependent on the soil temperature measurement depth. Generally, Q₁₀ significantly increased with the depth (0 cm, 5 cm, and 10 cm) of soil temperature measuring point. Different ecosystem types also exhibit different Q₁₀ values. In response to soil temperature at the depth of 5 cm, alpine meadow and tundra has the largest Q₁₀ value with magnitude of 3.05 ± 1.06, while the Q₁₀ value of evergreen broadleaf forests is approximately half that amount (Q₁₀ = 1.81 ± 0.43). Spatial correlation analysis also shows that the Q₁₀ value of forest ecosystems is significantly and negatively correlated with mean annual temperature (R = −0.51, P < 0.001) and mean annual precipitation (R = −0.5, P < 0.001). This result not only implies that the temperature sensitivity of soil respiration will decline under continued global warming, but also suggests that such acclimation of soil respiration to warming should be taken into account in forecasting future terrestrial carbon cycle and its feedback to climate system.     

Biological soil crust development affects physicochemical characteristics of soil surface in semiarid ecosystems

Water and nutrients are scarce resources in arid and semiarid ecosystems. In these regions, biological soil crusts (BSCs) occupy a large part of the soil surface in the open spaces surrounding patches of vegetation. BSCs affect physicochemical soil properties, such as aggregate stability, water retention, organic carbon (OC) and nitrogen (N) content, associated with primary ecosystem processes like water availability and soil fertility. However, the way BSCs modify soil surface and subsurface properties greatly depends on the type of BSC. We hypothesised that physicochemical properties of soil crusts and of their underlying soils would improve with crust development stage. Physicochemical properties of various types of soil crusts (physical crusts and several BSC development stages) and of the underlying soil (soil layers 0–1 cm and 1–5 cm underneath the crusts) in two semiarid areas in SE Spain were analysed. The properties that differed significantly depending on crust development stage were aggregate stability, water content (WC) (at −33 kPa and −1500 kPa), OC and N content. Aggregate stability was higher under well-developed BSCs (cyanobacterial, lichen and moss crusts) than under physical crusts or incipient BSCs. WC, OC and N content significantly increased in the crust and its underlying soil with crust development, especially in the first centimetre of soil underneath the crust. Our results highlight the significant role of BSCs in water availability, soil stability and soil fertility in semiarid areas.     

Parameters of the productivity of soil algae in terrestrial ecosystems

A review is presented of the recent state of the problem of soil algae productivity in terrestrial ecosystems on the basis of literature data and our own research. It is shown that the organic matter accumulated by soil algae is highly mobile. The following parameters were analyzed: the biological production, the time of the biomass turnover, and the rate of the algal organic matter renewal in the soil. The average monthly production of algae ranged from 0.9 to 765 g/m², the rate of the organic matter renewal ranged from 0.03 to 25.5 g/m² per day, and the time of the algal biomass renewal ranged from 0.1 to 7 days.     

中国典型生态系统土壤硝化强度的整合分析

针对国内外1959年至2013年间发表的2 900篇中国土壤硝化相关论文,获得288组中国土壤硝化强度数据,涉及26个省份,初步构建了开放式的中国土壤硝化信息系统。进一步利用整合分析,评估了土壤理化性质与土壤硝化强度的可能联系。结果表明:不同生态系统之间硝化速率由大到小依次为:农田(NO-3-N 1.39±0.27 mg kg-1d-1)、草地(0.74±0.17)、森林(0.66±0.16)、沙漠(0.17±0.08)、湿地(0.06±0.04)。在统计显著性的前提下,硝化强度与环境因子之间表现出一定的相关性趋势:即硝化强度与p H、有效磷、硝态氮正相关,与有机碳、速效氮和碳氮比负相关。在较大时空尺度下,生态系统类型是土壤硝化过程地理分异规律的最优解释因子,可能在硝化微生物形成与演替过程中发挥了重要作用。     

Fate and effects of insect-resistant Bt crops in soil ecosystems

Recent applications of biotechnology, especially genetic engineering, have revolutionized crop improvement and increased the availability of valuable new traits. A current example is the use of the insecticidal Cry proteins from the bacterium, Bacillus thuringiensis (Bt), to improve crops, known as Bt crops, by reducing injury from various crop pests. The adoption of genetically modified (GM) crops has increased dramatically in the last 11 years. However, the introduction of GM plants into agricultural ecosystems has raised a number of questions, including the ecological impact of these plants on soil ecosystems. Crop residues are the primary source of carbon in soil, and root exudates govern which organisms reside in the rhizosphere. Therefore, any change to the quality of crop residues and rhizosphere inputs could modify the dynamics of the composition and activity of organisms in soil. Insect-resistant Bt crops have the potential to change the microbial dynamics, biodiversity, and essential ecosystem functions in soil, because they usually produce insecticidal Cry proteins through all parts of the plant. It is crucial that risk assessment studies on the commercial use of Bt crops consider the impacts on organisms in soil. In general, few or no toxic effects of Cry proteins on woodlice, collembolans, mites, earthworms, nematodes, protozoa, and the activity of various enzymes in soil have been reported. Although some effects, ranging from no effect to minor and significant effects, of Bt plants on microbial communities in soil have been reported, using both culturing and molecular techniques, they were mostly the result of differences in geography, temperature, plant variety, and soil type and, in general, were transient and not related to the presence of the Cry proteins. The respiration (i.e., CO₂ evolution) of soils cultivated with Bt maize or amended with biomass of Bt maize and other Bt crops was generally lower than from soils cultivated with or amended with biomass of the respective non-Bt isolines, which may have been a result of differences in chemical composition (e.g., the content of starch, soluble N, proteins, carbohydrates, lignin) between Bt plants and their near-isogenic counterparts. Laboratory and field studies have shown differences in the persistence of the Cry proteins in soil, which appear to be the result primarily of differences in microbial activity, which, in turn, is dependent on soil type (e.g., pH, clay mineral composition, other physicochemical characteristics), season (e.g., temperature, water tension), crop species (e.g., chemical composition, C:N ratio, plant part), crop management practices (e.g., till vs. no-till), and other environmental factors that vary with location and climate zones. This review discusses the available data on the effects of Cry proteins on below-ground organisms, the fate of these proteins in soil, the techniques and indicators that are available to study these aspects, and future directions.     

Effects of shifting cultivation on soil ecosystems in Sarawak,Malaysia

Experimental shifting cultivation was conducted at the Balai Ringin (B. Ringin) and Sabal sites in Sarawak, Malaysia. At the sites, plots (10 x 10 m²) were burned with the fuel of aboveground biomass amounting to 0 (control), 100, 200, and 300 Mg ha^-1. At the B. Ringin site, the soils were clayey and strongly weathered with a strongly acidic characteristic. Ash addition enabled to alleviate the soil acidity and to increase the amounts of nutrients of the soils, especially the surface soils. It was indicated that 1) N addition from ash to the soils was negligible, 2) the losses of nutrients by runoff water were not substantial compared with the amounts of nutrients contained in ash, 3) ash alkalinity seemed to be consumed for inactivating exchangeable AI mainly in the surface soils, and 4) development of variable negative charges could contribute to the retention of inorganic bases derived from ash. After harvest of upland rice, the soil chemical properties in the plots treated with 100 and 200 Mg ha-1 fuel returned to the levels before burning, indicating the rapid loss of nutrients due to leaching and erosion as well as the uptake by plants. However, the soils treated with 300 Mg ha^-1 fuel still showed high contents of exchangeable bases and a low content of exchangeable AI. On the other hand, the soils at the Sabal site were sandy and were characterized by a very low nutrient status. The changes in the amounts of nutrients by ash addition were similar to those at the B. Ringin site. However, the changes in the level of exchangeable AI which were not appreciable were probably due to the low AI content. It was postulated that because of the sandy texture and low CEC of the soils, inorganic bases contained in ash were only suspended in the soil solution. Taking into account the low yield of rice and low level of secondary biomass, it appeared that most of the nutrients were lost downward in soils by leaching.     

Determinants of soil organic matter chemistry in maritime temperate forest ecosystems

While the influence of climate, vegetation, management and abiotic site factors on total carbon budgets and turn-over is intensively assessed, the influences of these ecosystem properties on the chemical complexity of soil organic matter (SOM) remains poorly understood. This study addresses the chemical composition of NaOH-extracted SOM from maritime temperate forest sites in Flanders (Belgium) by pyrolysis-GC/MS. The studied forests were chosen based on dominant tree species (Pinus sylvestris, Fagus sylvatica, Quercus robur and Populus spp.), soil texture and soil-moisture conditions. Differences in extractable-SOM pyrolysis products were correlated to site variables including dominant tree species, management of the woody biomass, site history, soil properties, total carbon stocks and indicators for microbial activity. Despite of a typical high intercorrelation between these site variables, the influence of the dominant tree species is prominent. The extractable-SOM composition is strongly correlated to litter quality and available nutrients. In nutrient-poor forests with low litter quality, the decomposition of relatively recalcitrant compounds (i.e. short and mid-chain alkanes/alkenes and aromatic compounds) appears hampered, causing a relative accumulation of these compounds in the soil. However, if substrate quality is favorable, no accumulations of recalcitrant compounds were observed, not even under high soil-moisture conditions. Former heathland vegetation still had a profound influence on extractable-SOM chemistry of young pine forests after a minimum of 60 years.     

Impact of fire on soil gross nitrogen transformations in forest ecosystems

Purpose

Forests play a key role in the global carbon (C) and nitrogen (N) cycling. Fire is a global phenomenon occurring in many forest ecosystems, which has several environmental and ecological effects. The objective of this review was to improve our understanding of the effect of fire on soil gross N transformations in forest ecosystems.

Methods and results

We have reviewed the published studies using ¹⁵N pool dilution technique with analytical data analysis method to study the effect of fires on gross N transformations in forest ecosystems. Wildfires increased gross N mineralization rates in the short term and the effect disappeared from 3 years after the fire, while the effect of prescribed fires disappeared from 2 years after the burning. Both wildfires and prescribed fires reduced gross nitrification in the short term, while their effects varied from 6 months following the burning.

Conclusions

The different responses of gross N transformations to the fires in forest ecosystems depended on many factors including forest types, the intensity and frequency of fires, the time elapsed between the fires and sampling events, incubation conditions (field or laboratory incubation), climatic conditions and so on. In view of many factors influencing the effect of fires on gross N transformations, more comprehensive studies with physical, chemical, microbial and ecological characterization are needed to improve our knowledge about the effect of fires on soil gross N transformations and then N cycling in forest ecosystems.

     

The use of integrated soil microcosms to predict effects of pesticides on soil ecosystems

Most studies that aim at assessing the effects of pesticides on soil organisms or soil ecosystem processes are related to a single species of organism or soil process. Such individual studies are usually performed according to standard test guidelines, prepared by national or international authorities or approved test organizations and used in risk assessment. Over the last four years, with scientists from Germany and Russia, we have tested integrated soil microcosms, as model terrestrial ecosystems, to assess simultaneously the overall effects of a single pesticide, on a range of representative soil organisms, ecosystem processes, and environmental fate. This integrated approach takes account of interactions between organisms and processes which may influence the overall environmental impact and fate of a pesticide. Results from a detailed study of the environmental impact of the fungicide carbendazim are presented and some results on the impact of copper on soil systems are also reviewed. Some ecosystem structural parameters that were affected include: microbial activity, nematode communities, earthworm numbers and masses and plant growth. Some of the ecosystem processes affected include: nitrogen mineralization, and nutrient transformations.     

Spatial structure of microbial biomass and activity in prairie soil ecosystems

Management of soil ecosystems requires assessment of key soil physicochemical and microbial properties and the spatial scale over which they operate. The objectives were to determine the spatial structure of microbial biomass and activity and related soil properties, and to identify spatial relationships of these properties in prairie soils under different management histories. Soil were sampled along a transect at 0.2 m intervals in each of five long-term treatments, namely, undisturbed, cattle grazed at two intensities, and cultivated with either wheat (Triticum aestivum L.) or cotton (Gossypium hirsutum L.). Contents of organic carbon (C_org), dissolved organic C (DOC), soluble nitrogen (N_sol), and microbial biomass C (C_mic) and N (N_mic) as well as dehydrogenase activity (DH) in 70 samples were evaluated. Results showed that long-term soil management altered the spatial structure and dependence of C_org and microbial biomass and activity. Cultivation has contributed to high nugget variance for C_org, C_mic, N_mic and DH which interfered with detection of spatial structure at the sampling scale used. Contents of C_org were spatially connected to microbial biomass and activity and to DOC in the uncultivated but not in the cultivated soils, indicating that various factors affected by management may operate at different spatial scales.     

The role of soil fauna in ecosystems: A historical review

The research development in this review is divided into successive periods: (1) “From Darwin to Satchell”, covering the “pre-experimental” decades dealing with the functions of earthworms, (2) “Litterbag Studies”, characterized by field experiments on the faunal influence on litter decomposition, (3) “The Time of IBP”, concentrating on community energetics, (4) “The Microcosm Era”, laboratory studies that started with simple systems, followed by increasing complexity of experimental setup and community of organisms, including living plants, and ending to laboratory-scale “ecosystems”, (5) the recent “Biodiversity Boom”, analysing the relations between soil biodiversity and ecosystem functions, and (6) the current “Holistic View” that tends to link the diversity and functions of aboveground and belowground communities. These “periods” started roughly in this order, but are largely overlapping, since the early techniques are in continuing use together with the modern ones. The current knowledge on the role of soil biota, their diversity and various components has accumulated mainly during the last 30 years, resulting in the modern view of soil fauna as a part of the ecosystem.     

Relative abundance and activity of melanized hyphae in different soil ecosystems

Here we report on the frequency of melanized fungal hyphae in 323 soils, covering different land use types. The proportion of total hyphae that was melanized averaged 61%. Arable fields with loamy sand, heathlands and city parks on sandy soils had the highest percentage of melanized hyphae. In addition to the frequency determinations, a microcosm study was performed on the role of melanized hyphae in two different ecosystems: an ex-arable field and a forest. Melanized hyphae appeared to be part of the active hyphae in the forest soil but not in the ex-arable soil. In conclusion, our results indicate that (1) melanized hyphae represent a large proportion of the total fungal biomass in soils and that (2) their function might differ between ecosystems.     

The behavior of the clay fraction in model ecosystems of soil lysimeters

Changes in the mineralogical composition of the clay fraction (<0.001 mm) sampled from soils of the model lysimetric experiment of Moscow State University have been studied. The mineralogical composition of clay is represented by the paragenetic association of minerals typical of noncalcareous mantle loams in the center of the Russian Plain. The predominant smectitic phase consists of complex mixed-layered minerals (mica-smectite with high and low contents of the smectitic layers, chlorite-smectite with different ratios between the chloritic and smectitic layers) and individual smectites. Tri-and dioctahedral hydromica, kaolinite, chlorite, and clay-sized quartz are present in lower amounts. At the early stages of the experiment, the distribution of the smectitic phase in the soil profile is more contrasting than the distribution of the clay fraction. Under the impact of artificially planted meadows, forests, and agrocenoses, soil profiles with different distribution patterns of the clay fraction are formed. The weakly pronounced eluvial distribution pattern of the clay fraction has been registered. Under spruce and mixed stands, the loss of the clay fraction from the upper horizons is due to the hydrolysis of smectitic minerals in the acidified medium. Under broad-leaved stands, perennial herbs, agroecenoses, and fallow, the depletion of smectites from the upper horizons is due to lessivage. The relative accumulation of hydromica and kaolinite is observed in the uppermost soil layer.     

Nutrient and phytotoxic contributions of residue to soil in no-till continuous-corn ecosystems

Summary An understanding of no-till ecosystems is essential for increased acceptance of conservation tillage practices. The primary objective of the present research was to assess the nutrient contributions of leachates from decomposing corn residue to soil in continuous-corn no-till ecosystems. A secondary objective was to estimate the phytotoxic effects of these leachates on corn seedling growth. The effects of moisture, temperature, and resident and non-resident microflora on leachates recovered from decomposing surface-applied corn residue were also studied. Leachates were analyzed for organic C, total N, PO ₄ ^3– -P, acid and alkaline phosphatase activity, urease activity, and phytotoxic effects. Within the first 90 days of a 215-day field study 73%, 83%, and 60% of C, N, and P, respectively, were leached. In terms of nutrient concentration, this suggests two distinct phases of release of nutrients onto the soil: A high initial flux of nutrients that is followed by a low-concentration release. No phytotoxic effect of field leachates was observed. Acid and alkaline phosphatase activity was highest on days 39 and 47 whereas urease activity peaked on day 149. In laboratory studies, alterations in temperature or moisture had little effect on the leachate nutrient concentration, or phytotoxic or enzyme activity. Increasing amounts of organic C and N were extracted over time. No phytotoxic effects were expressed in the laboratory. Overall, it appears that the maximum leaching of nutrients occurs early in the decomposition process and that in no-till systems no phytotoxicity can be associated with decomposition of surface residues.Paper No. 11871 of the Purdue University Agricultural Experiment Station Series     

农林复合杨树土壤养分的根际效应

用对比试验的方法,研究农林复合中杨树+留兰香、杨树+小麦、杨树+红薯和杨树纯林4种林地的杨树生长量、林地土壤物理性状和土壤养分以及杨树和间作物养分的根际效应。结果表明:1)杨树+留兰香林地的杨树生长量明显小于对照,显著小于杨树+小麦和红薯林地;2)间作林地的土壤物理性状、土壤pH值、非根际土壤养分不是影响杨树生长的关键因素,而根际土壤养分及根际效应的变化对杨树生长有直接影响;3)在杨树根际土壤中,杨树+小麦和红薯林地杨树根际土壤养分质量分数均高于对照;杨树+留兰香林地的杨树根际土壤有机质和速效磷质量分数高于对照,速效钾和速效氮质量分数则低于对照,而留兰香的根际养分质量分数除速效氮外均高于小麦和红薯;4)从养分的根际效应来看,杨树+留兰香林地杨树的养分根际效应值除有机质外小于对照并小于留兰香,杨树+小麦林地杨树的养分根际效应值除速效磷外均大于对照并大于小麦,杨树+红薯林地杨树的养分根际效应值除速效磷外均小于对照,除速效氮外均大于红薯。     

典型黑土区不同生态系统下土壤团聚体中胡敏酸的结构特征

为了揭示生态系统类型对土壤团聚体中腐殖质分子结构的影响,本研究以黑土区24 a长期定位试验处理下的自然草地(GL)、耕地(CL)和裸地(BL)土壤为研究对象,采用湿筛法将土壤团聚体分为2 mm、2～0.25 mm、0.25～0.053 mm和0.053 mm 4个粒级,运用元素分析、红外光谱和差热分析技术,对团聚体中胡敏酸(HA)的结构性质进行了研究。结果表明,生态系统类型对团聚体中HA的分子结构产生了影响。耕地各级团聚体中HA的O+S含量以及(O+S)/C比值(摩尔比)普遍高于草地相应粒级团聚体,反映了耕地土壤团聚体中HA的氧化程度高于草地;差热分析中,耕地和裸地土壤团聚体中HA的中温放热量低于草地相应粒级团聚体,且二者的热量高/中比值均高于草地,说明耕地和裸地土壤团聚体中HA的芳香性/脂族性高于草地;草地和耕地土壤团聚体中HA在2 920和2 850 cm-1处代表脂族聚亚甲基和末端甲基中C-H伸缩振动的吸收峰明显强于裸地,脂族碳/羧基碳(2 920/1 720)以及脂族碳/芳香碳(2 920/1 620)比值高于后者。与自然草地相比,耕地和裸地生态系统会增强土壤团聚体中HA的缩合度、氧化度和芳香性,提高其分子结构的稳定性。