Sage Journals: Discover world-class research

Abstract

In this study, the application mode and evaluation methods of green and sustainable remediation (GSR) were investigated in a soil remediation project. On-site equipment, materials, and energy usage were recorded, and environmental footprints were calculated using qualitative and semiquantitative methods. Replacement of equipment with appropriate power, reduction of redundant drive routes, increase of the reuse ratio of on-site and off-site materials, and optimization of remediation among other improvements should be implemented. Conventionally, the total air pollutant emission, water consumption, energy use, and greenhouse gas (GHG) emission were 1,682 kg, 3,093 t, 249.5 MWh, and 320 t CO₂e, respectively. Furthermore, on basis of 10 best management practices (BMPs) selected, the all-life cycle of the project was optimized using the GSR concept by eliminating inappropriate practices; redundant drive route was reduced by 19.8% using ArcGIS and TravellerAPP, while the reuse ratio and remediation method were theoretically optimized. Environmental footprint and accident risk of remediation were sharply reduced based on a combination of BMPs and quantitative evaluation. Air pollutant emission, hazardous gas, water, and energy consumption were reduced by 46.2%, 50.8%, 28.3%, and 40.5%, respectively, and GHG emission decreased by 147.4 t. Finally, confronting barriers and recommendations for GSR administration particularly in developing countries were summarized. This study theoretically and practically applied the GSR concept to an actual project in China. Association of on-site data with remediation activities and its optimization can provide technical and administrative support for GSR development and engineering practices.

Get full access to this article

View all access options for this article.

References

Al-Shahrani

, Xiao

, Llewellyn

S.A.

, Barri

, Jiang

, Shi

, Martinie

, and Green

M.L.

(2007). Desulfurization of diesel via the H 2 O 2 oxidation of aromatic sulfides to sulfones using a tungstate catalyst. Appl. Catal. B, 73, 311.

ASTM. (2013). E2893-13E1. Standard Guide for Greener Cleanups. West Conshohocken, PA: ASTM International.

Chen

(2007). Rapid urbanization in China: A real challenge to soil protection and food security. Catena, 69, 1.

Dellens

A.D.

(2007). Green Remediation and the Use of Renewable Energy Sources for Remediation Projects. Washington, DC: US Environmental Protection Agency, Office of Solid Waste and Emergency.

Delucchi

(2003). A Lifecycle Emissions Model (LEM): Lifecycle Emissions from Transportation Fuels, Motor Vehicles, Transportation Modes, Electricity Use, Heating and Cooking Fuels, and Materials. Davis, CA: Institute of transportation Studies.

Ellis

D.E.

, and Hadley

P.W.

(2009). Sustainable remediation white paper: Integrating sustainable principles, practices, and metrics into remediation projects. Remediat. J. 19, 5.

EPA. (2008). Incorporating Sustainable Environmental Practices into Remediation of Contaminated Sites. EPA 542-R-08-002.

Haller

(2017). Soil Remediation and Sustainable Development: Creating Appropriate Solutions for Marginalized Regions. Sweden: Mid Sweden University.

, Miao

, and Feng

(2010). Rock burst process of limestone and its acoustic emission characteristics under true-triaxial unloading conditions. Int. J. Rock Mechan. Min. Sci. 47, 286.

10.

Hinchee

R.E.

, and Smith

L.A.

(1992). In Situ Thermal Technologies for Site Remediation. Boca Raton, FL: CRC Press.

11.

Hondo

(2005). Life cycle GHG emission analysis of power generation systems: Japanese case. Energy, 30, 2042.

12.

Hou

(2016). Divergence in stakeholder perception of sustainable remediation. Sustain. Sci. 11, 215.

13.

Hou

, and Al-Tabbaa

(2014). Sustainability: A new imperative in contaminated land remediation. Environ. Sci. Policy. 39, 25.

14.

Hou

, Ding

, Li

, Wu

, Hu

, Guo

, Wang

, Ma

, O'Connor

, and Wang

(2017). A Sustainability Assessment Framework for Agricultural Land Remediation in China. Land Degrad. Dev. 29, 1005.

15.

Hou

, Guthrie

, and Rigby

(2016). Assessing the trend in sustainable remediation: A questionnaire survey of remediation professionals in various countries. J. Environ. Manage. 184, 18.

16.

Hou

, and Li

(2017). Complexities surrounding China's soil action plan. Land Degrad. Dev. 28, 2315.

17.

ITRC (Interstate Technology & Regulatory Council). (2011). Green and Sustainable Remediation: State of the Science and Practice, GSR-1. Washington, DC: Interstate Technology & Regulatory Council, Green and Sustainable Remediation Team. Available at: www.itrcweb.org (accessed September 14, 2017).

18.

Karadimas

N.V.

, Doukas

, Kolokathi

, and Defteraiou

(2008). Routing optimization heuristics algorithms for urban solid waste transportation management. WSEAS Trans. Comput. 7, 2022.

19.

Kibblewhite

, Chambers

, and Goulding

(2016). How good is the evidence to support investment in soil protection?. Soil Use Manage. 32, 172.

20.

Leigh

J.P.

, and Hoskin

A.F.

(2000). Remediation of contaminated sediments: A comparative analysis of risks to residents vs. remedial workers. Soil Sediment Contam., 9, 291.

21.

Leštan

, Luo

C.-L.

, and Li

X.-D.

(2008). The use of chelating agents in the remediation of metal-contaminated soils: A review. Environ. Pollut. 153, 3.

22.

Y.-G.

, and Jiang

G.-M.

(2004). Ecological restoration of mining wasteland in both China and abroad: An over review. Acta Ecol. Sin. 1, 95.

23.

Mengyao

(2010). The problems and countermeasures in environmental management of contaminated sites in China. Chin. Agric. Sci. Bull. 26, 338 (in Chinese).

24.

Page

C.A.

, Diamond

M.L.

, Campbell

, and McKenna

(1999). Life-cycle framework for assessment of site remediation options: Case study. Environ. Toxicol. Chem. 18, 801.

25.

Petruzzi

N.M.

(2011). A case study on the evaluation and implementation of green and sustainable remediation principles and practices during a RCRA corrective action cleanup. Ground Water Monit. Remediat. 31, 63.

26.

Sarra

, and Nakahigashi

(2012). Kigyo no shakai-teki sekinin: Challenges for corporate social responsibility in Japan. UBCL Rev. 45, 779.

27.

Sheldon

R.A.

(2014). Green and sustainable manufacture of chemicals from biomass: State of the art. Green Chem. 16, 950.

28.

Song

, Hou

, Zhang

, O'Connor

, Li

, Gu

, Li

, and Liu

(2018). Environmental and socio-economic sustainability appraisal of contaminated land remediation strategies: A case study at a mega-site in China. Sci. Total Environ. 610, 391.

29.

U.S. EPA. (2013). Methodology & Spreadsheets for Environmental Footprint Analysis (SEFA). EPA.

30.

Yan

, Liu

, Peng

, Mahmood

, Chen

, Wang

, Li

, and Chen

(2016). Spatial distribution and risk assessment of heavy metals in the farmland along mineral product transportation routes in Zhejiang, China. Soil Use Manage. 32, 338.

31.

Yasutaka

, Zhang

, Murayama

, Hama

, Tsukada

, and Furukawa

(2016). Development of a green remediation tool in Japan. Sci. Total Environ. 563, 813.

32.

Zhao

F.-J.

, Ma

, Zhu

Y.-G.

, Tang

, and McGrath

S.P.

(2014) Soil contamination in China: Current status and mitigation strategies. Environ. Sci. Technol. 49, 750.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.08 MB

0.09 MB

0.06 MB

0.03 MB

Implementation of a Green and Sustainable Concept to Evaluate Footprint and Optimize Contaminated Site Remediation in China: A Case Study

Abstract

Abstract

Get full access to this article

References

Supplementary Material