土地利用方式对紫色土丘陵区土壤剖面碳、氮影响

采取野外调查与室内分析相结合的方法研究了紫色土丘陵区林地、撂荒地、水田、旱地土壤剖面(0～40 cm)有机碳、全氮变化特征.结果表明.有机碳、全氮均随土层深度增加而逐渐减小,且林地、撂荒地有机碳递减幅度高于水田、旱地.相对于撂荒地和旱地,水田、林地更利于有机碳、全氮的积累.林地有机碳和全氮在0～5 cm土层表现出绝对优势;随土层递增,与水田、撂荒地和旱地的差异逐渐减小.水田有机碳和全氮在大于10 cm土层显示最大值.而撂荒地有机碳和全氮仅在土壤表层高于旱地.有机碳与全氮存在显著正相关关系;w(C)/w(N)随土层深度增加而降低,且林地、撂荒地降低幅度较大.因此相对于水田、旱地,林地和撂荒地w(C)/w(N)仅在0～10 cm显示较大值.可见,土地利用方式对陆地生态系统碳、氮蓄积有明显影响,通过旱地还林或撂荒可以增加土壤特别是表层土壤对碳、氮的积累.     

利用方式对紫色水稻土有机碳与颗粒态有机碳的影响

土壤是陆地生态系统中重要的动态碳库,其微小的变化可能带来对全球大气CO2浓度的较大变化。颗粒态有机碳在土壤中周转速度较快,比土壤总有机碳更易受土地利用方式的影响,对于评价土地利用变化对土壤碳固定过程影响具有重要意义。采集不同的耕作、轮作和施肥处理的14年28茬的紫色土长期试验土壤,分析有机碳与颗粒态有机碳含量在土壤及不同深度分布特点,结果表明:长期垄作免耕并实行水稻(Oryza sativa)油菜(Brassica)轮作的利用方式下,0～10cm土层土壤有机碳与颗粒态有机碳含量明显高于其他利用方式下,而稻油水旱轮作平作利用方式下最低。整个耕层0～30cm深度的土壤有机碳含量介于8.92～29.98g·kg-1之间,颗粒态有机碳含量变幅为0.54～3.43g·kg-1之间,且存在随深度递增而降低的趋势。土壤有机碳与颗粒态有机碳都可用作评价利用方式影响紫色水稻土土壤质量变化与固碳能力的有效指标,但颗粒有机碳对于管理措施的响应更为敏感。从总有机碳与颗粒有机碳的关系来看,不同管理下有机碳的增加与土壤物理保护能力的提高有关。垄作免耕(稻油)的利用方式最有利于有机碳的保护和稳定。     

岩溶山区不同土地利用方式对土壤活性有机碳动态的影响

对贵州茂兰自然保护区内三种典型土地利用方式(林地、草地和耕地)下土壤活性有机碳组分(土壤溶解有机碳和土壤微生物量碳)的月变化及其对环境因子的响应进行了研究,结果表明在不同的土地利用方式下上覆植被类型不同,其凋落物数量、质量及分解行为不同,有机质的输入量及质量也不相同,从而形成不同的土壤溶解有机碳含量差异,土壤有机碳的大小也存在较大差别。研究结果显示:从全年平均值来看,林地土壤溶解有机碳分别比草地和耕地高25%、48%;从3月到8月,三者均随气温的上升呈增加的趋势,林地和耕地在8月均达到最大值,而草地则在10月达到最大值;林地和草地土壤微生物量碳分别高于耕地81%和45%,林地和草地在10月达到最大值。不同的土地利用方式导致土壤活性有机碳的差异较大,这说明岩溶生态系统中土地利用方式对土壤碳库的大小有较大影响。不同土地利用方式下土壤活性有机碳对环境因子的响应也各不相同,这表明土壤活性碳受众多因素的制约而呈现出一种动态平衡关系,进一步的机理仍需要进行深入研究。     

土地利用/覆被变化对土地生态系统有机碳库的影响——以吉林省通榆县为例

土地利用/覆被变化对陆地碳循环影响显著.文章基于实地采集的土壤、植物样品的测试数据和1989、2004两年8月陆地卫星TM遥感影像数据,采用生态系统类型法分析吉林省通榆县1989-2004年耕地、林地、草地、盐碱地、沙地等11 种地类之间土地利用变化对土地生态系统有机碳库的影响.计算结果表明1989-2004年通榆县土地生态系统有机碳库共损失了3.18 TgC(1Tg=106t),年均损失约为0.265 Tgc.其中,湿地、草地有机碳库分别损失5.54 TgC和3.71 TgC,盐碱地面积的增加导致有机碳库损失4.75 TgC.林地面积增加和沙地面积减少分别使有机碳库增加了4.58 TgC和3.75 TgC.研究区总体上为一个碳失汇,草地退化、湿地萎缩、土地沙化和盐碱化造成了有机碳库的碳损失,而植树造林、草地植被的恢复和重建等活动则可以显著增加土壤有机碳储量.该研究对于评估自然环境与人为活动影响下,特别是大规模土地整治与生态修复对土壤有机碳的增汇潜力和固碳效应的影响具有重要的理论意义和应用价值.     

崇明岛典型土地利用方式对土壤有机碳和酶活性的影响

为了研究上海崇明岛不同土地利用方式对土壤有机碳以及酶活性的影响,对冬小麦地、蔬菜地、柑桔地和冬绿肥地4种土地利用方式的土壤进行了调查、样品测定和分析。结果表明,土地利用方式对有机碳和4种酶活性的影响极显著。冬小麦地总有机碳和活性有机碳质量分数均最高,分别为19.23g·kg^-1和2.26mg·g^-1,柑桔地土壤脲酶、碱性磷酸酶、纤维素酶和蛋白酶等4种酶活性均高于其他3种土地利用方式,表明采用秸秆还田式的冬小麦地,可以增加土壤总有机碳和活性有机碳质量分数;常年处于免耕状态的柑桔地可以使土壤酶活性增强。     

吉林西部不同土地利用方式下的生长季土壤CO2排放通量日变化及影响因素

利用GXH-3051A红外线分析仪,采用动态闭合气室法对吉林西部4种土地利用方式下土壤CO2排放通量日变化进行了定位测量,系统分析了环境因子及土壤理化性质等因素对土壤CO2排放通量日变化的影响。结果表明,水田、旱田、草地和盐碱地土壤CO2排放通量日变化均呈单峰曲线,但排放通量的日均值有较大差异,其中水田和草地排放量较高,分别为1．69μmol·m-2．S-1和1．24μmaol·m-2s-1;旱田和盐碱地较低,为0．50μmol·m-2．S-1和0．63μmol·m-2．S-1。各地类土壤C02排放通量的日均值与其每天上午10：00土壤CO2排放通量值最为接近,即可用该时间测得的土壤CO2排放通量估测日平均值。土地利用方式和大气温度是造成土壤CO2日排放通量差异的主要因素,多年来该区土地利用方式的变化,改变了土壤表层10cm内的土层温度、土壤含水率、有机碳含量、水解氮含量,进而影响土壤呼吸和CO2排放通量;区内水田土壤CO2排放通量与温度的相关性最高（R2=0．8375）,其次为旱田和草地。     

Effect of land use and land cover change on soil erosion and the spatio-temporal variation in Liupan Mountain Region, southern Ningxia, China

The Liupan Mountains are located in the southern Ningxia Hui Autonomous Region of China, that forms an important divide between landforms and biogeographic regions. The populated part of the Liupan Mountain Region has suffered tremendous ecological damage over time due to population pressure, excessive demand and inappropriate use of agricultural land resources. To present the relationship between land use/cover change and spatio-temporal variation of soil erosion, data sets of land use between the late 1980s and 2000 were obtained from Landsat Thematic Mapper (TM) imagery, and spatial models were used to characterize landscape and soil erosion conditions. Also, soil erosion in response to land use and land cover change were quantified and analyzed using data from geographical information systems and remote sensing. Soil erosion by water was the dominant mode of soil loss, while soil erosion by wind was only present on a relatively small area. The degree of soil erosion was classified into five severity classes: slight, light, moderate, severe, and very severe. Soil erosion in the Liupan Mountain Region increased between the late 1980s and 2000, both in terms of acreage and severity. Moderate, severe, and very severe eroded areas accounted for 54.86% of the total land area. The lightly eroded area decreased, while the moderately eroded area increased by 368817 ha (22%) followed by severe erosion with 146552 ha (8.8%), and very severe erosion by 97067.6 ha (5.8%). Soil loss on sloping cropland increased with slope gradients. About 90% of the cropland was located on slopes less than 15°. Most of the increase in soil erosion on cropland was due to conversion of steep slopes to cropland and degradation of grassland and increased activities. Soil erosion was severe on grassland with a moderate or low grass cover and on dry land. Human activities, cultivation on steep slopes, and overgrazing of pastures were the main reasons for the increase in erosion severity.     

吉林西部不同土地利用方式下的生长季土壤CO2排放通量日变化及影响因素

利用GXH-3051A红外线分析仪,采用动态闭合气室法对吉林西部4种土地利用方式下土壤CO2排放通量日变化进行了定位测量,系统分析了环境因子及土壤理化性质等因素对土壤CO2排放通量日变化的影响。结果表明,水田、旱田、草地和盐碱地土壤CO2排放通量日变化均呈单峰曲线,但排放通量的日均值有较大差异,其中水田和草地排放量较高,分别为1.69μmol.m-2.s-1和1.24μmol.m-2.s-1;旱田和盐碱地较低,为0.50μmol.m-2.s-1和0.63μmol.m-2.s-1。各地类土壤CO2排放通量的日均值与其每天上午10:00土壤CO2排放通量值最为接近,即可用该时间测得的土壤CO2排放通量估测日平均值。土地利用方式和大气温度是造成土壤CO2日排放通量差异的主要因素,多年来该区土地利用方式的变化,改变了土壤表层10 cm内的土层温度、土壤含水率、有机碳含量、水解氮含量,进而影响土壤呼吸和CO2排放通量;区内水田土壤CO2排放通量与温度的相关性最高(R2=0.837 5),其次为旱田和草地。     

Vertical distributions of soil carbon and nitrogen fractions as affected by land-uses in the Ili River Valley

In this study, soil samples were collected to a depth of 100?cm from different land-uses, including maize field (MZ), wheat field (WT), paddy field (PD), apple orchard (OC), grassland (GL) and wetland (WL) in the Ili River Valley in northwest China, to investigate the effects of land-use on vertical distributions of soil carbon (C) and nitrogen (N) fractions, and examine whether such effects were different between topsoil (0–40?cm) and subsoil (40–100?cm). The results showed that soil organic C, water-extractable organic C, microbial biomass C, total N and microbial biomass N of croplands (MZ, WT, PD and OC) were significantly lower than those of natural lands (GL and WL) in both topsoil and subsoil, indicating that contents of soil C and N fractions can be reduced by agricultural land-uses, and the reductions are not limited to topsoil. However, the contents of soil ammonium N and nitrate N showed complex trends under different land-uses, possibly due to that the plant species and agricultural practices (e.g. application rate of fertiliser and irrigation) are considerably different among land-uses. Therefore, we suggest that more nutrient inputs should be applied to croplands to improve soil fertility in the Ili River Valley.     

Soil biological characteristic,nutrient contents and stoichiometry as affected by different types of remediation in a smelter-impacted soil

ABSTRACT

In order to evaluate the ecological risk reductions of copper (Cu) and cadmium (Cd) and the change of nutrient contents and stoichiometry in a smelter-impacted farmland in Guixi, Jiangxi Province, China, with ～ 800?mg Cu kg^?1 soil and 0.8?mg Cd kg^?1 soil, an three years in situ experiment was conducted. The field trial consisted of 4 ×?5?m plots in a completely randomised block design. Hydroxyapatite was added at 10?g kg^?1 soil and Sedum plumbizincicola, Elsholtzia splendens, and Pennisetum sp. were planted. Post-treatment soil and plant samples were collected annually and analysed for Cu and Cd bioaccessibility, soil carbon: nitrogen: phosphorus (C:N:P), and the stoichiometries of soil β-glucosidase (BG), N-acetylglucosaminidase (NAG), and acid phosphatase (AP) activity levels. The results indicated that the hydroxyapatite treatments significantly reduced Cu and Cd bioaccessibility as well as the ratio of C:P and N:P. Moreover, BG, NAG, and AP activity levels all increased relative to those in untreated soil. Plants may also influence soil BG, NAG, and AP activity. This study demonstrated that in situ Cu and Cd stabilisation by hydroxyapatite and phytoextraction is ecologically safe and can alter soil mineral nutrient ecological stoichiometry and enzyme activity.     

Assessment of ecological risks induced by land use and land cover changes in Xiamen City,China

The landscape ecological risk (LER) in Xiamen City, China, from 1990 to 2030 was studied using an urban land use and land cover change (LUCC) model and LER analysis. The LUCC model was used to predict the LUCC of Xiamen from 2020 to 2030. We analyzed the characteristics of LUCC and landscape pattern changes and, finally, evaluated the effect of rapid LUCC on LER. Of the six landscape types investigated, built-up land and farmland demonstrated the most significant changes. The area of built-up land increased by 1.5 times in 2010 and is predicted to increase by 2.7 times in 2030 than that in 1990. The area of farmland increased from 34.5% in 1990 to 24.5% in 2010 and is predicted to decrease to 15.1% in 2030. The number of patches (NP) of built-up land decreased with increasing area, which promoted the dominance of built-up land over other landscape types. Five landscape types, those other than built-up land, increased in NP, landscape fragmentation, segmentation, and disturbance but decreased in dominance. The LER of Xiamen in 2010 was slightly lower than that in 1990. However, with the acceleration of urbanization, the LER in 2020 and 2030 will increase by 7.6% and 12.5% than that in 2010. The LER will significantly increase in areas such as the Huandong sea area, the second urban core of Xiamen, and northern Xiang'an. For the areas, some measures (e.g. optimum urban spatial growth patterns and control of coastal reclamation) must inevitably increase to reduce the LER posed by rapid urbanization.