comminution of that rock, and ultimately the reduction of their minerals to metals through either pyro- or hydrometallurgical treatment. By reason of this level of energy intensity, mining - and the primary metals industry in general - is a significant contributor to CO2 emissions, both direct and indirect, and thus to climate change globally. Emissions tracking and reporting is now mandatory in most major mining jurisdictions. Achieving reductions in the energy intensity of mining and metals production is therefore a primary area of focus for most producers, majors, mid-tier and juniors alike.
Ironically, mining is also, by reason of the increasingly scarce and increasingly remote occurrence of economic deposits, is an industry highly vulnerable to climate change, where security of power, water and labour supply, even geotechnical stability in some cases, is at risk due to significant changes to climate in these locations, changes including in precipitation levels (and patterns), wind patterns and storm trends, and to changes in seasonal temperatures (i.e. higher highs and lower lows).
At Bara Consulting we have long had an interest in design for reductions in both the physical as well as environmental footprint of mines. In due diligence we have long been assessing for climate risk in general, where recently that has extended to assessment of risk due to localised climate change trends. Even more recently we have begun to look, in addition to our approaches to footprint reduction, at approaches that can increase the resilience of operations to observed and potential future trends in local climate and weather too. This paper seeks to outline these approaches and describe a systematic design approach not only for climate impact reduction, but climate impact resilience as well.