• Changes in the Physicochemical Properties of Soil According to Soil Remediation Methods
  • Yi, Yong-Min;Oh, Cham-Teut;Kim, Guk-Jin;Lee, Chul-Hyo;Sung, Ki-June;
  • Department of Ecological Engineering, Pukyong National University;OIKOS Co. Ltd.;OIKOS Co. Ltd.;OIKOS Co. Ltd.;Department of Ecological Engineering, Pukyong National University;
  • 토양 정화 방법에 따른 토양의 물리화학적 특성 변화
  • 이용민;오참뜻;김국진;이철효;성기준;
  • 부경대학교 생태공학과;(주)오이코스;(주)오이코스;(주)오이코스;부경대학교 생태공학과;
Abstract
Various methods are used to remediate soil contaminated with heavy metals or petroleum. In recent years, harsh physical and chemical remediation methods are being used to increase remediation efficiency, however, such processes could affect soil properties and degrade the ecological functions of the soil. Effects of soil washing, thermal desorption, and land farming, which are the most frequently used remediation methods, on the physicochemical properties of remediated soil were investigated in this study. For soils smaller than 2 mm, the soil texture were changed from sandy clay loam to sandy loam because of the decrease in the clay content after soil washing, and from loamy sand to sandy loam because of the decrease in the sand content and increase in silt content during thermal desorption, however, the soil texture remained unchanged after land farming process. The water-holding capacity, organic matter content, and total nitrogen concentration of the tested soil decreased after soil washing. A change in soil color and an increase in the available phosphate concentration were observed after thermal desorption. Exchangeable cations, total nitrogen, and available phosphate concentration were found to decrease after land farming; these components were probably used by microorganisms during as well as after the land farming process because microbial processes remain active even after land farming. A study of these changes can provide information useful for the reuse of remediated soil. However, it is insufficient to assess only soil physicochemical properties from the viewpoint of the reuse of remediated soil. Potential risks and ecological functions of remediated soil should also be considered to realize sustainable soil use.

Keywords: Remediated soil;Soil washing;Thermal desorption;Land farming;Sustainable soil use;

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This Article

  • 2012; 17(4): 36-43

    Published on Aug 31, 2012

  • 10.7857/JSGE.2012.17.4.036
  • Received on May 18, 2012
  • Revised on Aug 26, 2012
  • Accepted on Aug 26, 2012