Oxidation of Binary DNAPL Mixtures Using Potassium Permanganate with a Phase Transfer Catalyst

Seol, Yongkoo; Schwartz, Franklin W.; Lee, Sangsuk

doi:10.1111/j.1745-6592.2001.tb00308.x

Cited by 19 publications

(5 citation statements)

References 12 publications

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“…Hence, significant attention has been devoted to the investigation of the efficacy of various biological and abiological remediation processes which may accelerate the degradation of chlorinated ethylenes. In particular, remediation of chlorinated ethylenes by oxidation using permanganate has recently been the subject of numerous studies because of the following: oxidation with permanganate is rapid and results in essentially complete mineralization to produce environmentally benign compounds (CO 2 , chloride); permanganate is not scavenged by carbonate or bicarbonate as may be the case with other oxidants; permanganate has a high aqueous solubility in contrast to some other oxidants; permanganate has a long history of use for treatment of drinking water; and remediation using permanganate may be implemented at relatively low cost ( − ).…”

Section: Introductionmentioning

confidence: 99%

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Poulson

Naraoka

2002

Environ. Sci. Technol.

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Permanganate oxidation of chlorinated ethylenes is an attractive technique to effect remediation of these important groundwater contaminants. Stable carbon isotope fractionation associated with permanganate oxidation of trichloroethylene (TCE), tetrachloroethylene (PCE), and cis-1,2-dichloroethylene (cDCE) has been measured, to study the possibility of applying stable carbon isotope analysis as a technique to assess the efficacy of remediation implemented by permanganate oxidation. Average carbon isotope fractionation factors of alphaTCE = 0.9786, alphaPCE = 0.9830, and alphacDCE = 0.9789 were obtained, although the fractionation factor for PCE may be interpreted to change from a value of 0.9779-0.9871 during the course of the reaction. The fractionation factors for all three compounds are quite similar, in contrast to the variation of fractionation factors vs degree of chlorination observed for other degradative processes, such as microbial dechlorination. This may be due to a common rate-determining step for permanganate oxidation of all three compounds studied. The large fractionation factors and the relative lack of dependence of the fractionation factors upon other environmental factors (e.g. oxidation rate, presence of multiple contaminants, incomplete oxidation, presence of chloride in solution) indicate that monitoring delta13C values of chlorinated ethylenes during oxidation with permanganate may be a sensitive, and potentially quantitative, technique to investigate the extent of degradation.

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Section: Introductionmentioning

confidence: 99%

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Poulson

Naraoka

2002

Environ. Sci. Technol.

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“…The use of phase-transfer catalyst in an environmental context has only been sparingly studied. Seol and Schwartz [32] and Seol et al [33] found that PTPP paired with MnO 4 − increased the dechlorination rate of TCE and PCE. Experiments by Seol and Schwartz [32] were confined to 60 min batch reactions where Cl − released and MnO 4 − consumed were measured and used to corroborate an improved rate of TCE removal.…”

Section: Discussionmentioning

confidence: 99%

“…The idea for using phase-transfer catalysts would be to allow some of the oxidant (i.e., MnO 4 − ) to partition into the non-aqueous phase DNAPL so that oxidation can occur in both the organic and bulk aqueous phases and reduce the time needed to remove the non-aqueous phase product. Seol and Schwartz [32] and Seol et al [33] used the phase transfer catalyst, pentyltriphenylphosphonium bromide (PTPP) in bench studies and reported increased dechlorination of both TCE and PCE. Although the initial results were promising, reports of using phase-transfer catalysts under transport conditions have not yet been reported.…”

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confidence: 99%

Improving the treatment of non-aqueous phase TCE in low permeability zones with permanganate

Chokejaroenrat

Comfort²,

Sakulthaew

et al. 2014

Journal of Hazardous Materials

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“…Since its discovery in 1659, potassium permanganate has a long history of application to different fields, such as catalysis, medicine and electrochemical and mechanical areas [12]. It is used as an oxidant in drinking water, wastewater and industrial processes [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28]. The use of potassium permanganate in the synthesis area was achieved to prepare many manganese oxide nanostructures [29][30][31][32][33][34][35][36][37][38][39][40][41].…”

Section: Introductionmentioning

confidence: 99%

Exploitation of KMnO₄material as precursors for the fabrication of manganese oxide nanomaterials

Ahmed

2016

Journal of Taibah University for Science

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Since the first synthesis of KMnO 4 using pyrolusite mineral and potassium carbonate, the experimental synthesis of manganese oxide nanostructures and their application to multiple scientific disciplines have been undertaken extensively. In this review, potassium permanganate raw materials were shown to be more effective and versatile than other addition materials; therefore, they have been widely used to synthesize a variety of manganese oxide nanomaterials, including manganese dioxides, trioxides, tetraoxides, oxyhydroxides and metal-incorporated oxide nanomaterials. Recent progress focused on the synthesis and analysis of the novel characteristics of Mn-oxide nanostructures, emphasizing critical experiments to determine the chemical and physical parameters and the interplay between synthetic conditions and nanoscale morphologies. The Crystal Maker Demo program was applied to estimate the anisotropic transformations from KMnO 4 to Mn-oxide nanomaterials.

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Oxidation of Binary DNAPL Mixtures Using Potassium Permanganate with a Phase Transfer Catalyst

Cited by 19 publications

References 12 publications

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Improving the treatment of non-aqueous phase TCE in low permeability zones with permanganate

Exploitation of KMnO₄material as precursors for the fabrication of manganese oxide nanomaterials

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Oxidation of Binary DNAPL Mixtures Using Potassium Permanganate with a Phase Transfer Catalyst

Cited by 19 publications

References 12 publications

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Carbon Isotope Fractionation during Permanganate Oxidation of Chlorinated Ethylenes (cDCE, TCE, PCE)

Improving the treatment of non-aqueous phase TCE in low permeability zones with permanganate

Exploitation of KMnO4material as precursors for the fabrication of manganese oxide nanomaterials

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Exploitation of KMnO₄material as precursors for the fabrication of manganese oxide nanomaterials