Citation: | LIN Dan, JIN Meng-gui, LI Xiu-juan. 2017: Risk assessment of heavy metals in topsoil along the banks of theYangtze River in Huangshi, China. Journal of Groundwater Science and Engineering, 5(2): 162-172. |
CHEN Chan-ling, LI Xiao-suo, et al. 2006. Heavy metal pollution along the highway area using the geo-accumulation index method. Malong Center for Disease Control and Prevention. Journal of Public Health & Preventive Medicine, 17(6): 19-21.
|
CHEN Man-huai. 2005. Environmental edaph-ology (1st edition). Beijing: Science Press.
|
Rinklebe J, Shaheen S M. 2014. Assessing the mobilization of cadmium, lead, and nickel using a seven-step sequential extraction technique in contaminated floodplain soil profiles along the central Elbe River, Germany. Water, Air & Soil Pollution, 225(8): 1-20.
|
LI Chang-an, DU Yun, et al. 2001. Environmental evolution and flood control countermeasures in mid-Yangtze River. Wuhan: China University of Geosciences Press.
|
YANG Zhong-fang, CHENG Hang-xin, et al. 2005. Regional ecological geochemical assessment: Ideas and prospects. Geological Bulletin of China, 24(8): 687-693.
|
HE Yuan, WANG Xian, et al. 2007. Forms of heavy metals in soils typical of Zoumadai of Quanzhou. Soil, 39(2): 257-262.
|
LIAO Guo-li, WU Chao. 2006. The pollution and control of environmental heavy metals under resource exploitation (1st Edition). Changsha: Central South University Press.
|
WU He-xin, HU Xue-feng, et al. 2004. Contents and differential characteristics of heavy metals in soils found in Baoshan District, Shanghai. Journal of Shanghai University (Natural Science), 10(4): 400-405.
|
José A R M, Manuel L A, José M G C. 2006. Heavy metal contents in agricultural topsoil in the Ebro basin (Spain), application of the multivariate geoestatistical method to study spatial variations. Environmental Pollution 114(3): 1001-1012.
|
Muller G. 1969. Index of geo-accumulation in sediments of the Rhine River. Geo Journal, 2(3): 108–118.
|
Brazauskiene D M, Paulauskas V, Sabiene N. 2008. Speciation of Zn, Cu, and Pb in the soil depending on soil texture and fertilization with sewage sludge compost. Journal of Soils and Sediments, 8(3):184-192.
|
Hakanson L. 1980. An ecological risk index of aquatic pollution control: A sedimentological approach. Water Research, 14(8): 975-1001.
|
ZHOU Sheng-lu, LIAO Fu-qiang, et al. 2008. Studies of heavy metal element contents in soil profiles typical of farmland in Yixing city. Chinese Science Bulletin, 53(S1): 153-161.
|
CHEN J S, WANG Z, LIU Y J. 1989. Potential risk of heavy metal pollution in water: assessment by sedimentology measures. Environment and Science and Technology, 9(1): 16-25.
|
WANG Yan-xin. 2007. Groundwater contamina?tion. Beijing: Higher education press.
|
XU Zheng-qi, NI Shi-jun, et al. 2008. Calculation of heavy metals’ toxicity coefficient in the evaluation of potential ecological risk index. Environmental Science and Technology, 31(2): 112-115.
|
LI Xiu-juan, JIN Meng-gui, et al. 2010a. Distribution characteristics and safety evaluation of Cd in crops along Yangtze River in Huangshi City. Research of agricultural modernization, 31(4): 509-512.
|
FU Hua, WU Yan-hua, WEI Li-hua. 2006. Distribution and evaluation of heavy metals in agricultural soil in southern area of Beijing. Journal of Agro-Environment Science, 25(1): 182-185.
|
PAN Gen-xing, Andrew C Chang, Albert L Page. 2002. Modeling transfer and partitioning of potentially toxic pollutants in soil crop system for human food security. Chinese Journal of Applied Ecology 13(7): 854-858.
|
LI Xiao-xiu, LU An-xiang, et al. 2006. Analysis and assessment of soil environmental quality of some farmlands in Beijing. Transactions of the CSAE, 22(2): 60-63.
|
MENG Fan-qiao, SHI Ya-juan, WU Wen-liang. 2000. Development of soil environmental quality standards of heavy metal for non-polluted agricultural products in China. Agro-environmental Protection, (19): 356- 359.
|
Morton-Bermea O, Hernández-álvarez E, et al. 2009. Assessment of heavy metal pollution in urban topsoils from the metropolitan area of Mexico City. Journal of Geochemical Exploration, 101(3): 218-224.
|
Chinese National Environmental Protection Agency (NEPA). 1990. Background values for elements in soil in China. Beijing: Chinese Environmental Science Press.
|
LIU Yang, LIU Kai, et al. 2015. Cadmium contamination of soil and crops is affected by intercropping and rotation systems in the lower reaches of the Minjiang River in south-western China. Environmental geochemistry and health, 38(3): 811-820.
|
ZHOU Sheng-lu, LIAO Fu-qiang, et al. 2008. Studies of heavy metal element contents in soil profiles typical of farmland in Yixing city. Chinese Science Bulletin, 53(S1): 153-161.
|
YANG Zhong-fang, CHENG Hang-xin, et al. 2005. Regional ecological geochemical assessment: Ideas and prospects. Geological Bulletin of China, 24(8): 687-693.
|
WEI Bing-gan, JIANG Feng-qing, et al. 2010. Heavy metal induced ecological risk in the city of Urumqi, NW China. Environmental monitoring and assessment, 160(1-4): 33-45.
|
LI Xiu-juan, JIN Meng-gui, et al. 2010b. Speciation characteristics and bioavailability of cadmium in soils along Yangtze River in Huangshi. Environmental Science & Technology, 33(5): 25-29.
|
ZHONG Xiao-lan, ZHOU Sheng-lu, et al. 2007. Spatial variability of soil heavy metals contamination in the Yangtze River delta: A case study of Taicang city in Jiangsu Province. Acta Pedologica Sinica, 44(1): 33-40.
|
XU Zheng-qi, NI Shi-jun, et al. 2008. Calculation of heavy metals’ toxicity coefficient in the evaluation of potential ecological risk index. Environmental Science and Technology, 31(2): 112-115.
|
ZHONG Xiao-lan, ZHOU Sheng-lu, et al. 2007. Spatial variability of soil heavy metals contamination in the Yangtze River delta: A case study of Taicang city in Jiangsu Province. Acta Pedologica Sinica, 44(1): 33-40.
|
XI Xiao-huan. 2004. Eco-geochemical research and eco-geochemical evaluation. Geophysical and Geochemical Exploration, 28(1): 10-15.
|
MA Zhen-dong, ZHANG De-cun, et al. 2005. Origin of cadmium high-value zones along the Yangtze River and Hanjiang River in Wuhan, Hubei, China. Regional Geology of China, 24(8): 740-743.
|
ZHOU Xiu-yan, WANG En-de. 2004. Method on how to apply index of geo-accumulation to evaluate heavy metal pollution as result of inter-tidal sediments in Liaodong bay. Journal of Safety and Environment, 4(2): 22-24.
|
Chinese National Environmental Protection Agency (NEPA). 1995. Soil environmental quality standard. Beijing: Standard Press of China.
|
ZHOU Xiu-yan, WANG En-de. 2004. Method on how to apply index of geo-accumulation to evaluate heavy metal pollution as result of inter-tidal sediments in Liaodong bay. Journal of Safety and Environment, 4(2): 22-24.
|
Chinese Geological Survey. 2005. Technical standard for Chinese geological survey (DD2005-03): Technical requirements for sample analysis for ecological geochemical assessment.
|
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