Integrating land use functions and heavy metal contamination to classify village types
暂无分享,去创建一个
Hongliang Chu | Wenkai Hu | Qing Xiang | Tao Xu | Lingfan Ju | H. Yu | Mengke Hu | Hong Huang
[1] Mehmet Çetin,et al. Evaluation of UTFVI index effect on climate change in terms of urbanization , 2023, Environmental Science and Pollution Research.
[2] F. Nworie,et al. Functionalized Biochars for Enhanced Removal of Heavy Metals from Aqueous Solutions: Mechanism and Future Industrial Prospects , 2022, Journal of Human, Earth, and Future.
[3] Xu Zhou,et al. Zoning Strategy for Basin Land Use Optimization for Reducing Nitrogen and Phosphorus Pollution in Guizhou Karst Watershed , 2022, Water.
[4] Congrong Li,et al. An Analysis of Eco–Environmental Changes in Rural Areas in China Based on Sustainability Indicators between 2000 and 2015 , 2022, Land.
[5] M. Cetin,et al. Exploring different organic manures in the production of quality basil seedlings , 2022, Environmental Science and Pollution Research.
[6] M. Cetin,et al. Using Topsoil Analysis to Determine and Map Changes in Ni Co Pollution , 2022, Water, Air, & Soil Pollution.
[7] Wei Zhou,et al. An innovative digitization evaluation scheme for Spatio-temporal coordination relationship between multiple knowledge driven rural economic development and agricultural ecological environment—Coupling coordination model analysis based on Guangxi , 2022, Journal of Innovation & Knowledge.
[8] Bin Liu,et al. Spatial distribution characteristics and ecological risk of heavy metals in the surface sediments of Hongfeng Lake , 2022, Arabian Journal of Geosciences.
[9] Huanyun Yu,et al. The potential ecological risk assessment of soil heavy metals using self-organizing map. , 2022, The Science of the total environment.
[10] Ihor Bloshchynskyi,et al. Soil Quality Evaluation in Urban Ecosystems during the Covid-19 Pandemic , 2022, HighTech and Innovation Journal.
[11] M. Cetin,et al. The Use of Cupressus arizonica as a Biomonitor of Li, Fe, and Cr Pollution in Kastamonu , 2022, Water, Air, & Soil Pollution.
[12] Jiang Liu,et al. The Design of a Remediation Device for Heavy Metal Contaminated Soil Under Digital Economy , 2022, Frontiers in Energy Research.
[13] M. Costa,et al. Geochemical assessment of trace element concentrations in the Farmington River, Connecticut, Northeastern, USA , 2022, Environmental Monitoring and Assessment.
[14] S. Gergel,et al. Landscape indicators as a tool for explaining heavy metal concentrations in urban streams , 2022, Landscape and Urban Planning.
[15] Anju Gupta,et al. Temporal Trends of Rainfall and Temperature over Two Sub-Divisions of Western Ghats , 2022, HighTech and Innovation Journal.
[16] C. Deutsch,et al. Combination of Machine Learning and Kriging for Spatial Estimation of Geological Attributes , 2022, Natural Resources Research.
[17] M. Cetin,et al. Evaluation of comparing urban area land use change with Urban Atlas and CORINE data , 2022, Environmental Science and Pollution Research.
[18] D. Baragaño,et al. A holistic methodology to study geochemical and geomorphological control of the distribution of potentially toxic elements in soil , 2022, CATENA.
[19] C. Afangideh,et al. Spatiotemporal Variability Assessment of Rainwater Quality in Oil and Gas Exploration Region of Nigeria , 2021, Journal of Human, Earth, and Future.
[20] B. Bate,et al. Soil heavy metal pollution of industrial legacies in China and health risk assessment. , 2021, The Science of the total environment.
[21] Cong-Qiang Liu,et al. Sulfur dynamics in forest soil profiles developed on granite under contrasting climate conditions. , 2021, Science of the Total Environment.
[22] wenbo deng,et al. A combination of finite mixture distribution model with geo-statistical models to study spatial patterns and hazardous areas of heavy metals in cropland soils of the Guanzhong Plain, Northwest China. , 2021, Chemosphere.
[23] Xuan Song,et al. Temporal and spatial variations of soil C, N contents and C:N stoichiometry in the major grain-producing region of the North China Plain , 2021, PloS one.
[24] Laura H. Jessup,et al. Spatial identification and determinants of trade-offs among multiple land use functions in Jiangsu Province, China. , 2021, The Science of the total environment.
[25] Shenglu Zhou,et al. Temporal and spatial distributions and sources of heavy metals in atmospheric deposition in western Taihu Lake, China. , 2021, Environmental pollution.
[26] F. Camargo,et al. The use of vegetal tissue multi-element content as an indicator of soil or substrate type employed to cultivate Cannabis sativa L. (marijuana) , 2021 .
[27] M. Cetin,et al. The usability of Cupressus arizonica annual rings in monitoring the changes in heavy metal concentration in air , 2021, Environmental Science and Pollution Research.
[28] T. Ediagbonya,et al. Risk assessment and elemental quantification of anthropogenic activities in soil , 2021, Environmental Geochemistry and Health.
[29] R. Southard,et al. Soil type modulates the response of C, N, P stocks and stoichiometry after native forest substitution by exotic plantations , 2021 .
[30] Chongjin Zhao,et al. Using fuzzy C-means Clustering to Identify Heavy Metal Polluted Soil in a Certain Area of Shanghai , 2021 .
[31] R. Zare,et al. Assessment and zoning of environmental hazard of heavy metals using the Nemerow integrated pollution index in the vineyards of Malayer city , 2020, Acta Geophysica.
[32] Guanyi Yin,et al. Effect of terrain gradient on cadmium accumulation in soils , 2020 .
[33] M. Cetin,et al. Application of artificial neural networks to predict the heavy metal contamination in the Bartin River , 2020, Environmental Science and Pollution Research.
[34] Dazhuan Ge,et al. Land use transition and rural spatial governance: Mechanism, framework and perspectives , 2020, Journal of Geographical Sciences.
[35] D. She,et al. Source identification of soil elements and risk assessment of trace elements under different land uses on the Loess Plateau, China , 2020, Environmental Geochemistry and Health.
[36] Junwei Ma,et al. Effects of climate factors and soil properties on soil nutrients and elemental stoichiometry across the Huang–Huai–Hai River Basin, China , 2020, Journal of Soils and Sediments.
[37] T. Ciupa,et al. Trace metals in surface soils under different land uses in Kielce city, south-central Poland , 2019, Environmental Earth Sciences.
[38] A. V. Smirnov,et al. Application of NDVI in Digital Mapping of Phosphorus Content in Soils and Phosphorus Supply Assessment in Plants , 2019, Izvestiya, Atmospheric and Oceanic Physics.
[39] Lei Deng,et al. Dynamics of soil microbial C:N:P stoichiometry and its driving mechanisms following natural vegetation restoration after farmland abandonment. , 2019, The Science of the total environment.
[40] M. Cetin,et al. Heavy metal accumulation in rosemary leaves and stems exposed to traffic-related pollution near Adana-İskenderun Highway (Hatay, Turkey) , 2019, Environmental Monitoring and Assessment.
[41] V. Chéret,et al. Soil and climate differently impact NDVI patterns according to the season and the stand type. , 2019, The Science of the total environment.
[42] Lizardo Reyna-Bowen,et al. Soil-Organic-Carbon Concentration and Storage under Different Land Uses in the Carrizal-Chone Valley in Ecuador , 2018, Applied Sciences.
[43] Chen Li,et al. Linkages of C: N: P stoichiometry between soil and leaf and their response to climatic factors along altitudinal gradients , 2018, Journal of Soils and Sediments.
[44] Ozgur Kisi,et al. Fuzzy c-means and K-means clustering with genetic algorithm for identification of homogeneous regions of groundwater quality , 2018, Neural Computing and Applications.
[45] J. Minár,et al. The mapping of soil taxonomic units via fuzzy clustering – A case study from the Outer Carpathians, Czechia , 2018, Geoderma.
[46] P. Burgess,et al. Land use change and soil carbon pools: evidence from a long-term silvopastoral experiment , 2018, Agroforestry Systems.
[47] S. Tadesse,et al. Estimating the spatial risk of tuberculosis distribution in Gurage zone, southern Ethiopia: a geostatistical kriging approach , 2018, BMC Public Health.
[48] S. Asmaryan,et al. Continuous impact of mining activities on soil heavy metals levels and human health. , 2018, The Science of the total environment.
[49] Birhan Asmame Miheretu,et al. Spatial variability of selected soil properties in relation to land use and slope position in Gelana sub-watershed, Northern highlands of Ethiopia , 2018 .
[50] T. Xiao,et al. Micro-characteristics of soil aggregate breakdown under raindrop action , 2018 .
[51] Yongming Luo,et al. Pollution, ecological-health risks, and sources of heavy metals in soil of the northeastern Qinghai-Tibet Plateau. , 2018, Chemosphere.
[52] E. Solgi,et al. Spatial patterns, hotspot, and risk assessment of heavy metals in different land uses of urban soils (case study: Malayer city) , 2018 .
[53] M. Rezakazemi,et al. Removal of Heavy Metals from Industrial Wastewaters: A Review , 2017 .
[54] M. K. Eghbal,et al. Impacts of topographic attributes on Soil Taxonomic Classes and weathering indices in a hilly landscape in Northern Iran , 2016 .
[55] L. Haines,et al. A comparison of plug-in predictors for lognormal kriging , 2016 .
[56] H. Arslan,et al. Estimation of spatial distribution of heavy metals in groundwater using interpolation methods and multivariate statistical techniques; its suitability for drinking and irrigation purposes in the Middle Black Sea Region of Turkey , 2015, Environmental Monitoring and Assessment.
[57] K. Adachi,et al. Characterization of heavy metal particles embedded in tire dust. , 2004, Environment international.
[58] G. Stamou,et al. Response of soil chemical and biological variables to small and large scale changes in climatic factors , 2004 .
[59] C. Reimann,et al. Geochemical background – can we calculate it? , 2000 .
[60] R. Salminen,et al. Considerations regarding the definition of a geochemical baseline of elements in the surficial materials in areas differing in basic geology , 2000 .
[61] A. Buscaroli,et al. Spatial distribution of elements in near surface sediments as a consequence of sediment origin and anthropogenic activities in a coastal area in northern Italy , 2021 .
[62] Xiaoping Liu,et al. Spatially varying impacts of built environment factors on rail transit ridership at station level: A case study in Guangzhou, China , 2020 .
[63] Xianguo Lu,et al. Distribution characteristics of iron, carbon, nitrogen and phosphorus in the surface soils of different land use types near Xingkai Lake , 2018, Journal of Soils and Sediments.
[64] Bao Lira. Element Geochemical Baseline and Distributions in Soil in Chongqing West Economic Zone,China , 2015 .
[65] Yunfeng Xie,et al. Spatial distribution of soil heavy metal pollution estimated by different interpolation methods: accuracy and uncertainty analysis. , 2011, Chemosphere.