Retardation capacity of organophilic bentonite for anionic fission products

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OriginalspracheEnglisch
Seiten (von - bis)255-264
Seitenumfang10
FachzeitschriftJournal of contaminant hydrology
Jahrgang47
Ausgabenummer2-4
PublikationsstatusVeröffentlicht - 2001

Abstract

Sorption and diffusivity of iodide and pertechnetate (I- and TcO4-) on MX-80 bentonite with different hexadecylpyridinium (HDPy+) loadings were studied using equilibrium solutions of different ionic strengths. In HDPy+-modified bentonite, iodide and pertechnetate ions exhibited increasing sorption (characterized by the distribution ratio, Rd), while Cs+ and Sr2+ showed decreasing sorption with increasing organophilicity. In case of medium-loading levels, the simultaneous sorption of anions (I- and TcO4-) and cations (Cs+ and Sr2+) was observed.Sorption of ions was influenced by the composition of the electrolytes employed. It decreased gradually with increasing ionic strength of the electrolyte solutions.The experiments revealed the general tendency that the diffusivity (Da [cm2·s-1]) for iodide and pertechnetate decreases with increasing organophilicity and increases with increasing ionic strength of the equilibrium solutions, confirming the results of the sorption experiments.Additionally, some mineralogical and chemical investigations, like IR spectral analysis of the organo-bentonite samples and exchange behavior of HDPy+, were performed. On the basis of these analyses, it was concluded that the alkylammonium ions are sorbed as (1) HDPy+ cations, (2) HDPyCl molecules and (3) micelles with decreasing binding intensities in this order.

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Retardation capacity of organophilic bentonite for anionic fission products. / Riebe, B.; Bors, J.; Dultz, St.
in: Journal of contaminant hydrology, Jahrgang 47, Nr. 2-4, 2001, S. 255-264.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Riebe B, Bors J, Dultz S. Retardation capacity of organophilic bentonite for anionic fission products. Journal of contaminant hydrology. 2001;47(2-4):255-264. doi: 10.1016/S0169-7722(00)00154-6
Riebe, B. ; Bors, J. ; Dultz, St. / Retardation capacity of organophilic bentonite for anionic fission products. in: Journal of contaminant hydrology. 2001 ; Jahrgang 47, Nr. 2-4. S. 255-264.
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abstract = "Sorption and diffusivity of iodide and pertechnetate (I- and TcO4-) on MX-80 bentonite with different hexadecylpyridinium (HDPy+) loadings were studied using equilibrium solutions of different ionic strengths. In HDPy+-modified bentonite, iodide and pertechnetate ions exhibited increasing sorption (characterized by the distribution ratio, Rd), while Cs+ and Sr2+ showed decreasing sorption with increasing organophilicity. In case of medium-loading levels, the simultaneous sorption of anions (I- and TcO4-) and cations (Cs+ and Sr2+) was observed.Sorption of ions was influenced by the composition of the electrolytes employed. It decreased gradually with increasing ionic strength of the electrolyte solutions.The experiments revealed the general tendency that the diffusivity (Da [cm2·s-1]) for iodide and pertechnetate decreases with increasing organophilicity and increases with increasing ionic strength of the equilibrium solutions, confirming the results of the sorption experiments.Additionally, some mineralogical and chemical investigations, like IR spectral analysis of the organo-bentonite samples and exchange behavior of HDPy+, were performed. On the basis of these analyses, it was concluded that the alkylammonium ions are sorbed as (1) HDPy+ cations, (2) HDPyCl molecules and (3) micelles with decreasing binding intensities in this order.",
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note = "Funding information: The work was supported by the European Commission {\textquoteleft}Nuclear Fission Safety{\textquoteright} programme (1994–1998) under contract FI4WCT950012. The skillful experimental work by Gabriele Erb-Bunnenberg and R{\"u}diger Sachse is gratefully acknowledged.",
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Download

TY - JOUR

T1 - Retardation capacity of organophilic bentonite for anionic fission products

AU - Riebe, B.

AU - Bors, J.

AU - Dultz, St

N1 - Funding information: The work was supported by the European Commission ‘Nuclear Fission Safety’ programme (1994–1998) under contract FI4WCT950012. The skillful experimental work by Gabriele Erb-Bunnenberg and Rüdiger Sachse is gratefully acknowledged.

PY - 2001

Y1 - 2001

N2 - Sorption and diffusivity of iodide and pertechnetate (I- and TcO4-) on MX-80 bentonite with different hexadecylpyridinium (HDPy+) loadings were studied using equilibrium solutions of different ionic strengths. In HDPy+-modified bentonite, iodide and pertechnetate ions exhibited increasing sorption (characterized by the distribution ratio, Rd), while Cs+ and Sr2+ showed decreasing sorption with increasing organophilicity. In case of medium-loading levels, the simultaneous sorption of anions (I- and TcO4-) and cations (Cs+ and Sr2+) was observed.Sorption of ions was influenced by the composition of the electrolytes employed. It decreased gradually with increasing ionic strength of the electrolyte solutions.The experiments revealed the general tendency that the diffusivity (Da [cm2·s-1]) for iodide and pertechnetate decreases with increasing organophilicity and increases with increasing ionic strength of the equilibrium solutions, confirming the results of the sorption experiments.Additionally, some mineralogical and chemical investigations, like IR spectral analysis of the organo-bentonite samples and exchange behavior of HDPy+, were performed. On the basis of these analyses, it was concluded that the alkylammonium ions are sorbed as (1) HDPy+ cations, (2) HDPyCl molecules and (3) micelles with decreasing binding intensities in this order.

AB - Sorption and diffusivity of iodide and pertechnetate (I- and TcO4-) on MX-80 bentonite with different hexadecylpyridinium (HDPy+) loadings were studied using equilibrium solutions of different ionic strengths. In HDPy+-modified bentonite, iodide and pertechnetate ions exhibited increasing sorption (characterized by the distribution ratio, Rd), while Cs+ and Sr2+ showed decreasing sorption with increasing organophilicity. In case of medium-loading levels, the simultaneous sorption of anions (I- and TcO4-) and cations (Cs+ and Sr2+) was observed.Sorption of ions was influenced by the composition of the electrolytes employed. It decreased gradually with increasing ionic strength of the electrolyte solutions.The experiments revealed the general tendency that the diffusivity (Da [cm2·s-1]) for iodide and pertechnetate decreases with increasing organophilicity and increases with increasing ionic strength of the equilibrium solutions, confirming the results of the sorption experiments.Additionally, some mineralogical and chemical investigations, like IR spectral analysis of the organo-bentonite samples and exchange behavior of HDPy+, were performed. On the basis of these analyses, it was concluded that the alkylammonium ions are sorbed as (1) HDPy+ cations, (2) HDPyCl molecules and (3) micelles with decreasing binding intensities in this order.

KW - Anion-sorption

KW - Diffusion

KW - Iodine

KW - Organo-clays

KW - Radioactive waste

KW - Technetium

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SP - 255

EP - 264

JO - Journal of contaminant hydrology

JF - Journal of contaminant hydrology

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IS - 2-4

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