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Characteristics of Solidification/Carbonation in the Heavy-Metal-Contaminated Sediment Treated by MgO-Based Binder
Hwang, Kyung-Yup;Seo, Jeong-Yun;Phan, Hoang Quang Huy;Ahn, Jun-Young;Hwang, Inseong;
School of Civil & Environmental Engineering, Pusan National University;School of Civil & Environmental Engineering, Pusan National University;School of Civil & Environmental Engineering, Pusan National University;School of Civil & Environmental Engineering, Pusan National University;School of Civil & Environmental Engineering, Pusan National University;
MgO 기반 고화제를 이용하여 처리한 중금속 오염 준설토의 고형화/탄산염화 특성
황경엽;서정윤;판 꽝 후이 호앙;안준영;황인성;
부산대학교 사회환경시스템공학부;부산대학교 사회환경시스템공학부;부산대학교 사회환경시스템공학부;부산대학교 사회환경시스템공학부;부산대학교 사회환경시스템공학부;

Abstract

A novel MgO-based binder was developed and applied to treat the anoxic sediment that was collected from Seonakdong river, Korea and was contaminated with heavy metals. The treated sediment was evaluated by measuring compressive strength, expansion, leaching of heavy metals and storage characteristics for $CO_2$. Initially, an optimal blending ratio of lime (L)/fly ash (FA)/blast furnace slag (BFS) that was to be mixed with MgO was screened to be $L_{0.3}-FA_{0.1}-BFS_{0.6}$. Long-term strengths of the sediments that were treated by various mixtures of MgO and $L_{0.3}-FA_{0.1}-BFS_{0.6}$ were then evaluated and the blending ratios between 4 : 6 and 6 : 4 were found optimal, which yielded a compressive strength of 4.09 MPa. On this basis, the optimal MgO-based binder was selected to be a 5 : 5 mixture of MgO and $L_{0.3}-FA_{0.1}-BFS_{0.6}$. The good performance of the MgO-based binder was believed to be due to the formation of Mg $(OH)_2$, which filled the micropores and also increased the density of the solidified matrices. The MgO-based binder exhibited an average stabilizing capacities for heavy metals of 92.9%, which was similar to or higher than that of Portland cement. It was found that 69.1 kg of carbon dioxide could be sequestrated after 365 days of curing when treating a ton of anoxic sediments.

Keywords: MgO;Sediment;Heavy Metals;Solidification;Carbonation;

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This Article

2013; 18(1): 102-111

Published on Feb 28, 2013
10.7857/JSGE.2013.18.1.102
Received on Jan 4, 2013
Revised on Jan 29, 2013
Accepted on Jan 29, 2013

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