CORRELATION OF SOIL PROPERTIES AND SOIL CADMIUM ACTIVITY: AN ENTROPY WEIGHT ANALYSIS PERSPECTIVE, 3-10.

Lili Huo,∗ Yue Li,∗∗,∗∗∗ Ruixue Liu,∗ Qing Xia,∗ Sainbuyan Bayarsaikhan,∗∗∗∗ and Yi An∗

References

1. [1] H. Khodaverdiloo and A. Samadi, Batch equilibrium studyon sorption, desorption, and immobilization of cadmium insome semi-arid zone soils as affected by soil properties, SoilResearch, 49, 2011, 444–454.
2. [2] P. Loganathan, S. Vigneswaran, J. Kandasamy, and R. Naidu,Cadmium sorption and desorption in soils: A review, CriticalReviews in Environmental Science and Technology, 42, 2012,489–533.
3. [3] S.M. Shaheen, C.D. Tsadilas, and J. Rinklebe, A review of thedistribution coefficients of trace elements in soils: Influenceof sorption system, element characteristics, and soil colloidalproperties, Advances in Colloid and Interface Science, 201–202(3), 2013, 43–56.
4. [4] X. Fu, C. Dou, Y. Chen, and X. Chen, Subcellular distributionand chemical forms of cadmium in Phytolacca americana L,Journal of Hazardous Materials, 186(1), 2011, 103–107.
5. [5] F. Qi, D. Lamb, R.S. Naidu, and N. Bolan, Cadmium solubilityand bioavailability in soils amended with acidic and neutralbiochar, Science of the Total Environment, 610–611, 2017,1457–1466.
6. [6] C. Srilert and K. Niruch, Facilitated transport of cadmium withmontmorillonite KSF colloids under different pH conditionsin water-saturated sand columns: Experiment and transportmodeling, Water Research, 146, 2018, 216–231.
7. [7] T. Bur, A. Probst, A. Bianco, and L. Gandois, Determiningcadmium critical concentrations in natural soils by assessingcollembola mortality, reproduction and growth, Ecotoxicologyand Environmental Safety, 73, 2010, 415–422.
8. [8] L. Gandois, A. Probst, and C. Dumat, Modelling trace metalextractability and solubility in French forest soils by usingsoil properties, European Journal of Soil Science, 61, 2010,271–286.8
9. [9] H.H. Gu, H. Qiu, T. Tian, and S.S. Zhan, Mitigation effects ofsilicon rich amendments on heavy metal accumulation in rice(Oryza sativa L.) planted on multi-metal contaminated acidicsoil, Chemosphere, 83(9), 2011, 1234–1240.
10. [10] H.Y. Yu, X. Ding, F. Li, and X. Wang, The availabilities ofarsenic and cadmium in rice paddy fields from a mining area:The role of soil extractable and plant silicon. EnvironmentalPollution, 215, 2016, 258–265.
11. [11] Q.B. He and B.R. Singh, Effect of organic matter on thedistribution, extractability and uptake of cadmium in soils,European Journal of Soil Science, 44, 1993, 641–650.
12. [12] P. Roivainen, S. Makkonen, T. Holopainen, and J. Juutilainen,Element interactions and soil properties affecting the soil-to-plant transfer of six elements relevant to radioactive waste inboreal forest, Radiat, Radiation and Environmental Biophysics,51, 2012, 69–78.
13. [13] N. Yu, C.J. Wu, and Y.L. Zhang, Application of TOPSIS modelmethod based on entropy weight to evaluate coupling effect ofirrigation and fertilization of greenhouse tomato, Journal ofShenyang Agricultural University, 43(4), 2012, 456–460.
14. [14] S.Z. Huang, J.X. Chang, G.Y. Leng, and Q. Huang, Integratedindex for drought assessment based on variable fuzzy set theory:A case study in the Yellow River basin, China, Journal ofHydrology, 527, 2015, 608–618.
15. [15] Y.L. Jiang, R.H. Wang, Q. Peng, and X. Quan, Soil nutri-ents evaluation based on entropy weight and matter element(EWME) model: A case study on artificial oasis in the Ebinurlake basin an arid zone of Xinjiang, Journal of Ecology & RuralEnvironment, 33(9), 2017, 852–859.
16. [16] P. Andr´aˇs and J.X. Matos, I. Turisov´a, and J.B. Maria, Theinteraction of heavy metals and metalloids in the soil-plantsystem in the S˜ao Domingos mining area (Iberian Pyrite Belt,Portugal), Environmental Science and Pollution Research,25(21), 2018, 20615–20630.
17. [17] D. Wei, and X. Chen, Entropy of function of uncertain variables.Math, Computer Model, 55, 2012, 754–760.
18. [18] Y. Kai, Sine entropy of uncertain set and its applications,Applied Soft Computing, 22, 2014, 432–442.
19. [19] J.X. Yang, Y.X. Zhou, K. Gao, and J. Xiong, Identifyingof structure material decay based on acceleration informationentropy, International Journal of Robotics & Automation,34(2), 2019, 130–134.
20. [20] J. Liang, Z. Yang, L. Tang, and G. Zeng, Changes in heavymetal mobility and availability from contaminated wetlandsoil remediated with combined biochar-compost, Chemosphere,181, 2017, 281–288.
21. [21] L. Bing, Y. Lan, Q.W. Chang, and S.Q. Zheng, Effects oforganic-inorganic amendments on the cadmium fraction in soiland its accumulation in rice (Oryza sativa L.), EnvironmentalScience and Pollution Research, 25, 2018, 1–11.
22. [22] D.X. Zhang, G.H. Du, D. Chen, and G.L. Shi, Effect ofelemental sulfur and gypsum application on the bioavailabilityand redistribution of cadmium during rice growth, Science ofTotal Environment, 657, 2019, 1460–1467.
23. [23] X.Y. Zhou, W.Q. Feng, Y.S. Qin, H. Yu, M.L. Liao, Y.C. Liu,C.Q. Wang, and S.H. Tu, Effects of magnesium, manganese,activated carbon and lime and their interactions on cadmiumuptake, Journal of Soil and Water Conservation, 26(6), 2012,199–208.
24. [24] L.S. Kasmaei and Fekri M. Application of Cu fertilizer onCu recovery and desorption kinetics in two calcareous soils,Environmental Earth Sciences, 67(7), 2012, 2121–2127.
25. [25] P. Akkajit and C. Tongcumpou. Fractionation of metals incadmium contaminated soil: Relation and effect on bioavailablecadmium, Geoderma, 156(3–4), 2010, 126–132.
26. [26] H.W. Sun, J. Ha, S.X. Liang, and W.J. Kang. Protective roleof selenium on garlic growth under cadmium stress, Com-munications in Soil science & Plant Analysis, 41(10), 2010,1195–1204.
27. [27] L. Zhao, Y.Z. Huang, Y. Zhu, and J. Li, The interactions orarsenate or vanadium with cadmium and the effects of arsenateand vanadium on the adsorption of cadmium by soil, ChinaEnvironmental Chemistry, 23, 2004, 409–412.
28. [28] H. Toshimitsu, O. Hirotomo, M. Tomoyuki, and O. Takuji,Relationship between cadmium fractions obtained by sequentialextraction of soil and the soil properties in contaminated anduncontaminated paddy soils, The Journal of Chemical Physics,2015, 1–9.
29. [29] I. Mohamed, B. Ahamadou, M. Li, C. Gong, P. Cai, W.Liang, and Q. Huang, Fractionation of copper and cadmiumand their binding with soil organic matter in a contaminatedsoil amended with organic materials, Journal of Soils andSediments, 10(6), 2010, 973–982.
30. [30] Z. Liu, S. Pan, Z. Sun, R. Ma, and L. Chen, Heavy metal spatialvariability and historical changes in the Yangtze River estuaryand North Jiangsu tidal flat, Marine Pollution Bulletin, 98,2015, 115–129.
31. [31] B. Murawska, E. Spychajfabisiak, T. Knapowski, and B.Gowacki, Ionic equilibrium in maize grain depending on thefertilisation and soil type, Journal of Central European Agri-culture, 14, 2013, 1518–1529.
32. [32] H. Jankowska-huflejt, Nutritive value and the content of macroelements in fodder and in soil from organic grasslands, Journalof Agricultural Engineering Research, 59, 2014, 91–97.
33. [33] C. Acevedo-Opazo, H. Vald´es-G´omez, J.A. Taylor, A. Avalo,and N. Verdugo-V´asquez, Assessment of an empirical spatialprediction model of vine water status for irrigation managementin a grapevine field, Agricultural Water Management, 124,2013, 58–68.

Important Links:

• Abstract
• DOI: 10.2316/J.2022.206-0727
• From Journal (206) International Journal of Robotics and Automation - 2022

Go Back