Effect of Ionic Strength on Mercury Adsorption on Contaminated Soil
Mercury adsorption on soil was investigated at
different ionic strengths using Ca(NO3)2 as a background electrolyte.
Results fitted the Langmuir equation and the adsorption isotherms
reached a plateau at higher equilibrium concentrations. Increasing
ionic strength decreased the sorption of mercury, due to the
competition of Ca ions for the sorption sites in the soils. The
influence of ionic strength was related to the mechanisms of heavy
metal sorption by the soil. These results can be of practical
importance both in the agriculture and contaminated soils since the
solubility of mercury in soils are strictly dependent on the adsorption
and release process.
[1] D. Wang, X. Shi, S. Wie, "Accumulation and transformation of
atmospheric mercury in soil," Sci. Tot. Environ., vol. 304, pp. 209-214,
2003.
[2] F. Pedron, G. Petruzzelli, M. Barbafieri, E. Tassi, "Remediation of a
Mercury-Contaminated Industrial Soil Using Bioavailable Contaminant
Stripping," Pedosphere, vol. 23, pp. 104-110, 2013.
[3] E. Schuster, "The behavior of mercury in the soil with special emphasis
on complexation and adsorption processes: a review of the literature,"
Water Air Soil Pollut., vol. 56, pp. 653-667, 1991.
[4] G. Petruzzelli, "Soil Sorption of heavy metals," in Ecological Issues and
Environmental Impact Assessment, P. N. Cheremisinoff, Ed. Gulf
Publishing Company Houston, 1997, pp. 145-174.
[5] M. Vidal, M. J. Santos, T. Abrão, J. Rodríguez, A. Rigol, "Modeling
competitive metal sorption in a mineral soil," Geoderma, vol. 149, pp.
189-198, 2009.
[6] E. Vistoso, B. K. G. Theng, N. S. Bolan, R. L. Parfitt, and M. L. Mora,
"Competitive sorption of molybdate and phosphate in Andisols," J. Soil
Sci. Pl. Nutr., vol. 12, pp. 59-72, 2012.
[7] G. W. Thomas, "Soil pH and soil acidity," in Methods of Soil Analysis,
Part 3 - Chemical Methods, D. L. Sparks, Ed. Soil Science Society of
America Book Series, Soil Science Society of America Inc., Madison,
USA, 1996, pp. 475-490.
[8] M. E. Sumner, and W. P. Miller, "Cation exchange capacity and
exchange coefficients," in Methods of Soil Analysis, Part 3 - Chemical
Methods, D. L. Sparks, Ed. Soil Science Society of America Book
Series, Soil Science Society of America Inc., Madison, USA, 1996, pp.
1201-1230.
[9] G. W. Gee, and J. W. Bauder, "Particle-size analysis," in Methods of soil
analysis. Part 1. Physical and mineralogical methods, A. Klute, Ed.
Agronomy Monograph N┬░9, American Society of Agronomy/Soil
Science Society of America, Madison, WI., 1986, pp. 383-411.
[10] D. W. Nelson, and L. E. Sommers, "Total carbon, organic carbon and
organic matter," in Methods of Soil Analysis, Part 3 - Chemical
Methods, D. L. Sparks, Ed. Soil Science Society of America Book
Series, Soil Science Society of America Inc., Madison, USA, 1996,
pp.961-1010.
[11] U.S. Environmental Protection Agency, Method 7473, Mercury in solids
and solutions by thermal decomposition, amalgamation, and atomic
absorption spectrophotometry, 1998.
[12] C. H. Giles, D. Smith, A. Huitson, "A general treatment and
classification of the solute adsorption isotherm. I. Theoretical," Journal
of Colloid and Interface Science, vol. 47, pp. 755-765, 1974.
[13] K. F. Hayes, C. Papelis, J. O. Leckie, "Modeling ionic strength effects
on anion adsorption at hydrous oxide/solution interfaces," J. Coll. Interf.
Sci., vol. 125, pp. 717-726, 1988.
[14] R. Xu, Y. Wang, D. Tiwari, H. Wang, "Effect of ionic strength on
adsorption of As(III) and As(V) on variable charge soils," J. Environ.
Sci., vol. 21, pp. 927-32, 2009.
[15] A. Voegelin, V. M. Vulava, and R. Kretzschmar, "Reaction based model
describing competitive sorption and transport of Cd,Zn, and Ni in acidic
soil," Env. Sci. Technol., vol. 35, pp. 1651-1657, 2001.
[16] G. L. J. Gaines, and H. C. Thomas, "Adsorption studies on clay
minerals," J. Chem Phys., vol. 21 pp. 714-718, 1953.
[17] M. C. Gabriel, D. G. Williamson, "Principal biogeochemical factors
affecting the speciation and transport of mercury through the terrestrial
environment," Environ. Geochem. Hlth., vol. 26, pp. 421-434, 2004.
[18] S. Gupta, K. G. Bhattacharyya, "Adsorption of Ni(II) on clays," J.
Colloid Interf. Sci., vol. 295, pp. 21-32, 2006.
[19] M. R. Soares, J. C. Casagrande, E. R. Mouta, "Effects of soil solution
parameters on cadmium adsorption by Brazilian variable charge soils,"
Commun. Soil Sci. Plan., vol. 40, pp. 2132-2151, 2009.
[20] M. R. Soares, J. C. Casagrande, and E. R. Mouta, "Nickel Adsorption by
Variable Charge Soils: Effect of pH and Ionic Strength," Braz. Arch.
Biol. Technol., vol. 54, pp. 207-220, 2011.
[21] F. Pedron, G. Petruzzelli, M. Barbafieri, E. Tassi, P. Ambrosini, and L.
Patata, "Mercury Mobilization in a Contaminated Industrial Soil for
Phytoremediation," Commun. Soil Sci. Plant Anal., vol. 42, pp. 2767-
2777, 2011.
[22] L. Cassina, E. Tassi, F. Pedron, G. Petruzzelli, P. Ambrosini, M.
Barbafieri, "Using a plant hormone and a thioligand to improve
phytoremediation of Hg-contaminated soil from a petrochemical plant,"
J. Haz. Mater., vol. 231, pp. 36-42, 2012.
[1] D. Wang, X. Shi, S. Wie, "Accumulation and transformation of
atmospheric mercury in soil," Sci. Tot. Environ., vol. 304, pp. 209-214,
2003.
[2] F. Pedron, G. Petruzzelli, M. Barbafieri, E. Tassi, "Remediation of a
Mercury-Contaminated Industrial Soil Using Bioavailable Contaminant
Stripping," Pedosphere, vol. 23, pp. 104-110, 2013.
[3] E. Schuster, "The behavior of mercury in the soil with special emphasis
on complexation and adsorption processes: a review of the literature,"
Water Air Soil Pollut., vol. 56, pp. 653-667, 1991.
[4] G. Petruzzelli, "Soil Sorption of heavy metals," in Ecological Issues and
Environmental Impact Assessment, P. N. Cheremisinoff, Ed. Gulf
Publishing Company Houston, 1997, pp. 145-174.
[5] M. Vidal, M. J. Santos, T. Abrão, J. Rodríguez, A. Rigol, "Modeling
competitive metal sorption in a mineral soil," Geoderma, vol. 149, pp.
189-198, 2009.
[6] E. Vistoso, B. K. G. Theng, N. S. Bolan, R. L. Parfitt, and M. L. Mora,
"Competitive sorption of molybdate and phosphate in Andisols," J. Soil
Sci. Pl. Nutr., vol. 12, pp. 59-72, 2012.
[7] G. W. Thomas, "Soil pH and soil acidity," in Methods of Soil Analysis,
Part 3 - Chemical Methods, D. L. Sparks, Ed. Soil Science Society of
America Book Series, Soil Science Society of America Inc., Madison,
USA, 1996, pp. 475-490.
[8] M. E. Sumner, and W. P. Miller, "Cation exchange capacity and
exchange coefficients," in Methods of Soil Analysis, Part 3 - Chemical
Methods, D. L. Sparks, Ed. Soil Science Society of America Book
Series, Soil Science Society of America Inc., Madison, USA, 1996, pp.
1201-1230.
[9] G. W. Gee, and J. W. Bauder, "Particle-size analysis," in Methods of soil
analysis. Part 1. Physical and mineralogical methods, A. Klute, Ed.
Agronomy Monograph N┬░9, American Society of Agronomy/Soil
Science Society of America, Madison, WI., 1986, pp. 383-411.
[10] D. W. Nelson, and L. E. Sommers, "Total carbon, organic carbon and
organic matter," in Methods of Soil Analysis, Part 3 - Chemical
Methods, D. L. Sparks, Ed. Soil Science Society of America Book
Series, Soil Science Society of America Inc., Madison, USA, 1996,
pp.961-1010.
[11] U.S. Environmental Protection Agency, Method 7473, Mercury in solids
and solutions by thermal decomposition, amalgamation, and atomic
absorption spectrophotometry, 1998.
[12] C. H. Giles, D. Smith, A. Huitson, "A general treatment and
classification of the solute adsorption isotherm. I. Theoretical," Journal
of Colloid and Interface Science, vol. 47, pp. 755-765, 1974.
[13] K. F. Hayes, C. Papelis, J. O. Leckie, "Modeling ionic strength effects
on anion adsorption at hydrous oxide/solution interfaces," J. Coll. Interf.
Sci., vol. 125, pp. 717-726, 1988.
[14] R. Xu, Y. Wang, D. Tiwari, H. Wang, "Effect of ionic strength on
adsorption of As(III) and As(V) on variable charge soils," J. Environ.
Sci., vol. 21, pp. 927-32, 2009.
[15] A. Voegelin, V. M. Vulava, and R. Kretzschmar, "Reaction based model
describing competitive sorption and transport of Cd,Zn, and Ni in acidic
soil," Env. Sci. Technol., vol. 35, pp. 1651-1657, 2001.
[16] G. L. J. Gaines, and H. C. Thomas, "Adsorption studies on clay
minerals," J. Chem Phys., vol. 21 pp. 714-718, 1953.
[17] M. C. Gabriel, D. G. Williamson, "Principal biogeochemical factors
affecting the speciation and transport of mercury through the terrestrial
environment," Environ. Geochem. Hlth., vol. 26, pp. 421-434, 2004.
[18] S. Gupta, K. G. Bhattacharyya, "Adsorption of Ni(II) on clays," J.
Colloid Interf. Sci., vol. 295, pp. 21-32, 2006.
[19] M. R. Soares, J. C. Casagrande, E. R. Mouta, "Effects of soil solution
parameters on cadmium adsorption by Brazilian variable charge soils,"
Commun. Soil Sci. Plan., vol. 40, pp. 2132-2151, 2009.
[20] M. R. Soares, J. C. Casagrande, and E. R. Mouta, "Nickel Adsorption by
Variable Charge Soils: Effect of pH and Ionic Strength," Braz. Arch.
Biol. Technol., vol. 54, pp. 207-220, 2011.
[21] F. Pedron, G. Petruzzelli, M. Barbafieri, E. Tassi, P. Ambrosini, and L.
Patata, "Mercury Mobilization in a Contaminated Industrial Soil for
Phytoremediation," Commun. Soil Sci. Plant Anal., vol. 42, pp. 2767-
2777, 2011.
[22] L. Cassina, E. Tassi, F. Pedron, G. Petruzzelli, P. Ambrosini, M.
Barbafieri, "Using a plant hormone and a thioligand to improve
phytoremediation of Hg-contaminated soil from a petrochemical plant,"
J. Haz. Mater., vol. 231, pp. 36-42, 2012.
@article{"International Journal of Earth, Energy and Environmental Sciences:50703", author = "G. Petruzzelli and F. Pedron and I. Rosellini and E. Tassi and F. Gorini and B. Pezzarossa and M. Barbafieri", title = "Effect of Ionic Strength on Mercury Adsorption on Contaminated Soil", abstract = "Mercury adsorption on soil was investigated at
different ionic strengths using Ca(NO3)2 as a background electrolyte.
Results fitted the Langmuir equation and the adsorption isotherms
reached a plateau at higher equilibrium concentrations. Increasing
ionic strength decreased the sorption of mercury, due to the
competition of Ca ions for the sorption sites in the soils. The
influence of ionic strength was related to the mechanisms of heavy
metal sorption by the soil. These results can be of practical
importance both in the agriculture and contaminated soils since the
solubility of mercury in soils are strictly dependent on the adsorption
and release process.", keywords = "Heavy metals, bioavailability, remediation, competitive sorption.", volume = "7", number = "6", pages = "271-4", }
