渭–库绿洲土壤盐分时空分异特征研究
Spatial and Temporal Characteristics of Soil Salinity in gan-Kuqa Oasis
DOI: 10.12677/SD.2015.52006, PDF, HTML, XML, 下载: 3,129  浏览: 9,357  国家自然科学基金支持
作者: 吐尔逊•艾山:新疆维吾尔自治区农业资源区划办公室,新疆 乌鲁木齐;玉苏甫•买买提, 买合皮热提•吾拉木:新疆师范大学地理科学与旅游学院,新疆 乌鲁木齐;买买提•沙吾提:新疆大学资源与环境科学学院,新疆 乌鲁木齐
关键词: 渭–库绿洲土壤盐分空间变异性地统计学gan-Kuqa Oasis Soil Salinity Spatial Variation Geostatistics
摘要: 绿洲土壤特性的空间变异性是土壤的重要属性之一。不同尺度上的土壤空间变异性的定量化研究可以使人们了解植物与土壤的关系,养分和水分对植物的影响以及植物的空间格局等具有重要的参考价值。本文运用GIS技术,采用传统统计学和地统计学相结合的方法,分析渭–库绿洲土壤含盐量的时空变异情况,及其揭示其绿洲土壤盐分的时空变异规律。结果表明,各时期表层土壤盐分拟合的理论模型都符合球状模型;研究区盐渍化土壤主要集中于研究区的东部和东南部,该区域土壤含盐量相当高,形成了区域积盐中心;研究区西部和西北部含盐量较低;土壤含盐量大体上有从研究区的西北、西边区域向研究区东南和东部区域的方向增加的趋势。渭–库绿洲气候与土壤条件非常适宜种植棉花,是新疆的主要棉花生产区域之一。这对研究区土地的合理利用、了解土壤的结构和功能、合理的水资源灌溉利用、土壤盐碱化防治、棉田的优化布局和棉花产业的可持续发展提供科学依据,从而对保护渭–库绿洲生态环境的稳定性做出贡献。
Abstract: Spatial variation of soil properties is one of the important properties of oasis soils. Quantitative research on spatial variation of soils on different scales could help people learn the soil-plant re-lationships and the effects of soil moisture and nutrients on plant growth, and spatial patterns of plant community. In this paper, we used GIS technology combined with traditional statistics and geostatistics to analyze Spatial and temporal characteristics of soil salinity in Ögan-Kuqa Oasis. Results showed that, the theoretical model of the surface soil salt fitting the spherical model; soil salinization in the study area is mainly concentrated in the east and southeast of this area with quite high salinity, formed a regional center of salt deposition; in western and northwestern area, low salt content were observed. The oasis climate is very suitable for cotton plantation, and thus this area is one of the main cotton production bases of Xinjiang. Results from this research should provide a scientific basis for rational use of the soils, understanding the structure and function of soil, reasonable irrigation water resources utilization, soil salinity control, optimize the layout of cotton fields, and provide a scientific basis for the sustainable development of cotton industry, thus to protect the stability of oasis ecological environment.
文章引用:吐尔逊•艾山, 玉苏甫•买买提, 买合皮热提•吾拉木, 买买提•沙吾提. 渭–库绿洲土壤盐分时空分异特征研究[J]. 可持续发展, 2015, 5(2): 35-42. http://dx.doi.org/10.12677/SD.2015.52006

参考文献

[1] Burgess, T.M. and Webster, R. (1980) Optimal interpolation and isarithmic mapping of soil properties: 1. The semi- variogram and punctual Kriging. Journal of Soil Science, 31, 315-341.
[2] Dercon, G., Deckers, J., Govers, G., et al. (2003) Spatial variability in soil properties on slow-forming terraces in the Andes region of Ecuador. Soil and Tillage Research, 72, 31-41.
[3] White, J.G., Welch, R.M. and Norvell, W.A. (1997) Soil zinc map of the USA using geo-statiscs and geographic information systems. Soil Science Society of America Journal, 61, 185-194.
[4] Webster, R. (1983) Spatial variation in soil and the role of Kriging. Agricultural Water Management, 6, 111-121.
[5] 胡克林, 李保国, 林启美等 (1999) 农田土壤养分的空间变异性特征. 农业工程学报, 9, 33-38.
[6] 李菊梅, 李生秀 (1998) 几种营养元素在土壤中的空间变异. 干旱地区农业研究, 16, 58-64.
[7] 孙波, 赵其国, 闾国年 (2002) 低丘红壤肥力的时空变异. 土壤学报, 3, 190-198.
[8] 雷志栋, 杨诗秀 (1985) 土壤特性空间变异性初步研究. 水利学报, 9, 10-20.
[9] 李毅, 刘建军 (2000) 土壤空间变异性研究方法. 石河子大学学报(自然科学版), 4, 33 l-338.
[10] 周慧珍, 龚子同 (1996) 土壤空间变异性研究. 土壤学报, 33, 232-240.
[11] 李晓燕, 张树文, 王宗明, 张惠琳 (2004) 吉林省德惠市土壤特性空间变异特征与格局. 地理学报, 6, 989-997.
[12] 姚荣江, 杨劲松, 刘广明 (2006) 黄河三角洲地区典型地块土壤盐分空间变异特性研究. 农业工程学报, 6, 61- 66.
[13] 杨玉玲, 文启凯, 田长彦, 等 (2000) 土壤空间变异性现状及展望. 中国土壤学会土壤肥力与生态专业委员会学术研讨会论文, 2, 51-55.
[14] 韩茜, 熊黑钢 (2008) 新疆奇台县绿洲土壤特性空间变异及盐渍化逆向演替研究. 博士论文, 新疆大学, 乌鲁木齐, 6-17.
[15] 陈彦, 吕新 (2005) 基于GIS和地统计学的土壤养分空间变异特征研究——以新疆农七师125团为例. 中国农学通报, 7, 389-405.
[16] 江红南, 塔西甫拉提•特依拜, 丁建丽, 徐佑成 (2008) 新疆渭干河灌区土地盐渍化时空变化影响因子分析. 干旱区地理, 6, 885-891.
[17] 王春得, 赵忠贤 (2006) 新疆渭干河灌区水文地质条件变化及排水措施探讨. 地下水, 6, 87-89.
[18] 陈小兵, 杨劲松, 杨朝晖, 胡顺军, 刘广明 (2008) 渭干河灌区灌排管理与水盐平衡研究. 农业工程学报, 4, 59- 65.
[19] Jin, J.Y. and Jiang, C. (2002) Spatial variability of soil nutrients and site-specific nutrient management in the P.R. China. Computers and Electronics in Agriculture, 36, 165-172.
[20] Qiu, Y., Fu, B.J., Wang, J. and Chen, L.D. (2001) Spatial variability of soil moisture content and its relation to environmental indices in a semi-arid gully catchment of the Loess Plateau, China. Journal of Arid Environments, 49, 723- 750.
[21] Qiu, Y., Fu, B.J. and Wang, J. (2001) Soil moisture variation in relation to to-pography and land use in a hillslope catchment of the Loess Plateau, China. Journal of Hydrology, 24, 243-263.
[22] 徐建华 (2002) 现代地理学中的数学方法. 高等教育出版社, 北京.
[23] Pucci, A.A. and Murashige, J.A.E. (1987) Application of universal Kriging to an aquifer study in New Jersey. Ground Water, 25, 672-678.
[24] Theodossiou, N. and Latinopoulos, P. (2006) Evaluation and optimization of groundwater observation networks using the Kriging me-thodology. Environmental Modelling and Software, 21, 991-1000.
[25] Triantafilis, J., Odeh, I.O.A., Warr, B. and Ahmed, M.F. (2004) Mapping of salinity risk in the lower Namoi valley using non-linear Kriging methods. Agricultural Water Management, 69, 203-231.
[26] 汤国安, 杨西 (2006) ArcGIS地理信息系统空间分析实验教程. 科学出版社, 北京, 363-422.
[27] 胡玉福, 邓良基, 张世熔, 倪福全, 张杰 (2009) 四川盆地西缘浅层地下水铁、锰含量的空间变异特征. 生态学报, 2, 797-803.
[28] Zhang, S.R., Sun, B., Zhao, Q.G., Xiao, P.F. and Shu, J.Y. (2004) Temporal-spatial variability of soil organic carbon stocks in rehabilitating ecosystem. Pedosphere, 14, 501-508.
[29] 王雪梅 (2010) 干旱区典型绿洲土壤盐渍化及其生态效应研究. 博士论文, 新疆大学, 乌鲁木齐.

为你推荐