Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems

Andrew L. Lynch; Dibakar Bhattacharyya

Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The use of polystyrene ion-exchange resin for iron immobilization offers distinct advantages in overcoming Iron(III) precipitation and low selectivity in Fenton's reaction trichloroethylene decontamination. This resin provides ion-exchange sites which can be loaded initially with Iron(II) and, upon reaction with hydrogen peroxide, Iron(III). By effectively chelating Iron(III), and preventing its precipitation, these ion-exchange sites act as an immobilized chelating agent. Additionally, due to the high porosity of this resin gained from its ∼80 nm pores, the bulk of iron is internally immobilized, reducing side reactions with external materials and increasing selectivity. The use of ion-exchange nanoparticles in the form of polystyrene resin to facilitate the Fenton's reaction in natural near-neutral pH systems has significant potential to increase the effectiveness of the Fenton's reaction for groundwater remediation. This study builds on preliminary efforts already published to begin to develop and quantify these advantages.

Original language	English
Title of host publication	American Chemical Society - 235th National Meeting, Abstracts of Scientific Papers
State	Published - 2008
Event	235th National Meeting of the American Chemical Society, ACS 2008 - New Orleans, LA, United States Duration: Apr 6 2008 → Apr 10 2008

Publication series

Name	ACS National Meeting Book of Abstracts
ISSN (Print)	0065-7727

Conference

Conference	235th National Meeting of the American Chemical Society, ACS 2008
Country/Territory	United States
City	New Orleans, LA
Period	4/6/08 → 4/10/08

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

Cite this

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title = "Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems",

abstract = "The use of polystyrene ion-exchange resin for iron immobilization offers distinct advantages in overcoming Iron(III) precipitation and low selectivity in Fenton's reaction trichloroethylene decontamination. This resin provides ion-exchange sites which can be loaded initially with Iron(II) and, upon reaction with hydrogen peroxide, Iron(III). By effectively chelating Iron(III), and preventing its precipitation, these ion-exchange sites act as an immobilized chelating agent. Additionally, due to the high porosity of this resin gained from its ∼80 nm pores, the bulk of iron is internally immobilized, reducing side reactions with external materials and increasing selectivity. The use of ion-exchange nanoparticles in the form of polystyrene resin to facilitate the Fenton's reaction in natural near-neutral pH systems has significant potential to increase the effectiveness of the Fenton's reaction for groundwater remediation. This study builds on preliminary efforts already published to begin to develop and quantify these advantages.",

author = "Lynch, {Andrew L.} and Dibakar Bhattacharyya",

year = "2008",

language = "English",

isbn = "9780841269859",

series = "ACS National Meeting Book of Abstracts",

booktitle = "American Chemical Society - 235th National Meeting, Abstracts of Scientific Papers",

note = "235th National Meeting of the American Chemical Society, ACS 2008 ; Conference date: 06-04-2008 Through 10-04-2008",

}

Lynch, AL & Bhattacharyya, D 2008, Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems. in American Chemical Society - 235th National Meeting, Abstracts of Scientific Papers. ACS National Meeting Book of Abstracts, 235th National Meeting of the American Chemical Society, ACS 2008, New Orleans, LA, United States, 4/6/08.

Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems. / Lynch, Andrew L.; Bhattacharyya, Dibakar.
American Chemical Society - 235th National Meeting, Abstracts of Scientific Papers. 2008. (ACS National Meeting Book of Abstracts).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems

AU - Lynch, Andrew L.

AU - Bhattacharyya, Dibakar

PY - 2008

Y1 - 2008

N2 - The use of polystyrene ion-exchange resin for iron immobilization offers distinct advantages in overcoming Iron(III) precipitation and low selectivity in Fenton's reaction trichloroethylene decontamination. This resin provides ion-exchange sites which can be loaded initially with Iron(II) and, upon reaction with hydrogen peroxide, Iron(III). By effectively chelating Iron(III), and preventing its precipitation, these ion-exchange sites act as an immobilized chelating agent. Additionally, due to the high porosity of this resin gained from its ∼80 nm pores, the bulk of iron is internally immobilized, reducing side reactions with external materials and increasing selectivity. The use of ion-exchange nanoparticles in the form of polystyrene resin to facilitate the Fenton's reaction in natural near-neutral pH systems has significant potential to increase the effectiveness of the Fenton's reaction for groundwater remediation. This study builds on preliminary efforts already published to begin to develop and quantify these advantages.

AB - The use of polystyrene ion-exchange resin for iron immobilization offers distinct advantages in overcoming Iron(III) precipitation and low selectivity in Fenton's reaction trichloroethylene decontamination. This resin provides ion-exchange sites which can be loaded initially with Iron(II) and, upon reaction with hydrogen peroxide, Iron(III). By effectively chelating Iron(III), and preventing its precipitation, these ion-exchange sites act as an immobilized chelating agent. Additionally, due to the high porosity of this resin gained from its ∼80 nm pores, the bulk of iron is internally immobilized, reducing side reactions with external materials and increasing selectivity. The use of ion-exchange nanoparticles in the form of polystyrene resin to facilitate the Fenton's reaction in natural near-neutral pH systems has significant potential to increase the effectiveness of the Fenton's reaction for groundwater remediation. This study builds on preliminary efforts already published to begin to develop and quantify these advantages.

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M3 - Conference contribution

AN - SCOPUS:77955607369

SN - 9780841269859

T3 - ACS National Meeting Book of Abstracts

BT - American Chemical Society - 235th National Meeting, Abstracts of Scientific Papers

T2 - 235th National Meeting of the American Chemical Society, ACS 2008

Y2 - 6 April 2008 through 10 April 2008

ER -

Functionalized polystyrene resin for enhanced oxidation of trichloroethylene in near-neutral pH systems

Abstract

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Conference

ASJC Scopus subject areas

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