Eco-design practices towards sustainable supply chain management: interpretive structural modelling (ISM) approach

Due to increasing emphasis on sustainable practices, many organisations have attempted to leverage their supply chain performance towards balancing triple bottom line dimensions (economic, environmental and social perspectives). This paper, therefore, determines the priorities of sustainable supply chain management focusing on eco-design. Interpretive structural modelling (ISM) and Matriced’ Impacts Croise’s Multiplication Appliquée a UN Classement (MIMAC) are used to identify the hierarchical structure of the relationships among eco-design dimensions, and to analyse characteristics power of each dimension on supporting eco-design practices. The relationships and characteristics power of each dimension are used to determine indicators that are effective in enhancement of eco-design practice, evaluated through sustainable supply chain performance. Results indicate that product deployment is an important approach for improving eco-design practice towards sustainable supply chain management. This emphasises the purpose and impact of eco-design on sequential supply chain activities at deployment phase. Further research is required to make an overall assessment of eco-design practices across range of manufacturing industries, given the current research is based on inputs from a limited number of experts of selected organisations.     

Kinetics of biochemically driven metal precipitation in synthetic landfill leachate

This study investigates the effectiveness of using metal sulphide and carbonate precipitation mechanisms combined with a landfill‐derived mixed bacterial population. The study was conducted under controlled substrate conditions in anaerobic batch reactors. High chemical oxygen demand (COD):sulphate ratios, butyrate, propionate, and acetate were used anaerobically by bacteria for growth with associated sulphate reduction as well as sulphide and carbonate generation. Propionate and butyrate degradation occurred during sulphate reduction by sulphate‐reducing bacteria while acetate degradation was associated with methanogenesis by methanogenic bacteria. Using low COD, sulphate ratios showed limited acetate utilization, but sulphate reduction still occurred. Precipitation of Cd, Cu, Zn, Ni, and Fe sulphides occurred quickly and was completed in 15 to 30 days, while Ca, Mn, and Mg carbonates formed after 40 to 50 days and some soluble metal remained even after 120 days. The rate of metal precipitation was in the order of Cd>Cu>Zn>Ni>Fe>Mn>Mg>Ca. Bacterially mediated metal precipitation occurred slower than that recognized for chemical precipitation. These findings suggest that contaminant transport models based on chemical equilibrium metal behaviors may over‐predict metal removal by bio‐precipitation. © 2002 Wiley Periodicals, Inc.     

An investigation into long-distance health impacts of the 1996 eruption of Mt Ruapehu,New Zealand

During the June 1996 eruption of Mt Ruapehu, New Zealand, traces of fine particulate volcanic ash were observed in or near the cities of Hamilton and Auckland, 166–282 km from the volcano. Although no health impacts in these cities were attributed to the eruption, hospital records at both cities for the following month show the highest rates of respiratory mortality for the 1990s. Alternative explanations for this increase in respiratory mortality were investigated, including urban air pollution, adverse weather conditions and influenza. Comparable records from Wellington city, assumed to be outside the zone of ash dispersal, were used as a ‘control’. Our results suggest that at Hamilton, where non-volcanic factors can largely be eliminated as making a significant contribution, diffuse volcanic ashfall may have been an important factor in respiratory mortality during the weeks following the eruption. At Auckland, further away from the volcano but with a much larger population than Hamilton, a case for a weaker volcanic contribution can be made, but is more equivocal because of coincidentally high urban air pollution and cold, stable weather.These findings support the concept that diffuse fine volcanic ash poses a risk to respiratory health at greater distances from an eruption than is currently perceived. This is because the finest ‘respirable’ fraction of erupted material with potentially hazardous physico-chemical properties is likely to be ejected highest into the atmosphere and dispersed the greatest distance. If significant amounts reach large cities, then large numbers of individuals may be at risk, especially those already suffering poor respiratory health. This work has important implications for environmental health and hazard management in New Zealand and in other regions that may be susceptible to a similar volcanic threat.