cradle-to-grave

By Elsa Dominish, Nick Florin, and Rachael Wakefield-Rann - Earthworks, April 27, 2021

This research investigates the current status and future potential of strategies to reduce demand for new mining, particularly for lithium-ion battery metals for electric vehicles. This study is focused on four metals which are important to lithium-ion batteries: cobalt, lithium, nickel and copper.

In order to meet the goals of the Paris Climate agreement and prevent the worst effects of catastrophic climate change, it will be essential for economies to swiftly transition to renewable energy and transport systems. At present, the technologies required to produce, store and utilize renewable energy require a significant amount of materials that are found predominantly in environmentally sensitive and often economically marginalized regions of the world. As demand for these materials increase, the pressures on these regions are likely to be amplified. For renewable energy to be socially and ecologically sustainable, industry and government should develop and support responsible management strategies that reduce the adverse impacts along the material and technology supply chains.

There are a range of strategies to minimize the need for new mining for lithium-ion batteries for electric vehicles, including extending product life through improved design and refurbishment for reuse, and recovering metals through recycling at end of life. For example, we found that recycling has the potential to reduce primary demand compared to total demand in 2040, by approximately 25% for lithium, 35% for cobalt and nickel and 55% for copper, based on projected demand. This creates an opportunity to significantly reduce the demand for new mining. However, in the context of growing demand for electric vehicles, it will also be important that other demand reduction strategies with lower overall material and energy costs are pursued in tandem with recycling, including policy to dis-incentivize private car ownership and make forms of active and public transport more accessible. While the potential for these strategies to reduce demand is currently not well understood; this report provides insights into the relative merits, viability, and implications of these demand reduction strategies, and offers recommendations for key areas of policy action.

Read the text (Link).

By Andy Whitmore - War on Want, March 2021

There is an urgent need to deal with the potential widespread destruction and human rights abuses that could be unleashed by the extraction of transition minerals: the materials needed at high volumes for the production of renewable energy technologies. Although it is crucial to tackle the climate crisis, and rapidly transition away from fossil fuels, this transition cannot be achieved by expanding our reliance on other materials. The voices arguing for ‘digging our way out of the climate crisis’, particularly those that make up the global mining industry, are powerful but self-serving and must be rejected. We need carefully planned, lowcarbon and non-resource-intensive solutions for people and planet.

Academics, communities and organisations have labelled this new mining frontier, ‘green extractivism’: the idea that human rights and ecosystems can be sacrificed to mining in the name of “solving” climate change, while at the same time mining companies profit from an unjust, arbitrary and volatile transition. There are multiple environmental, social, governance and human rights concerns associated with this expansion, and threats to communities on the frontlines of conflicts arising from mining for transition minerals are set to increase in the future. However, these threats are happening now. From the deserts of Argentina to the forests of West Papua, impacted communities are resisting the rise of ‘green extractivism’ everywhere it is occurring. They embody the many ways we need to transform our energy-intense societies to ones based on democratic and fair access to the essential elements for a dignified life. We must act in solidarity with impacted communities across the globe.

This report includes in-depth studies written by frontline organisations in Indonesia and Philippines directly resisting nickel mining in both countries respectively. These exclusive case studies highlight the threats, potential impacts and worrying trends associated with nickel mining and illustrate, in detail, the landscape for mining expansion in the region.

Read the text (PDF).

By Sara Huier - International Development Studies and Global Studies, Roskilde University, April 2019

The study argues that the Circular Economy (CE) model often privileges the Global North economies’ standpoint, revealing a significant inadequacy. Therefore, the present research investigates the extent of the disparities in closed-loop strategies between developed and developing countries. The objective of the analysis is to understand whether these contingencies are relevant and whether they are the display of global economy dynamics that reinforce mechanisms of inequality, conflicting with the Sustainable Development rationale.

It is found that the analysis corroborates the existence of imbalanced drivers, opportunities, barriers and drawbacks between the Global North and the Global South, although potential benefits for the South are entailed. However, it also emerges the existence of critical transnational dynamics which may prevent the achievement of CE objectives globally. The existence of these overlooked and unaddressed global forces is identified as the actual problem of the CE model. Indeed, the narrow focus of the CE on production processes and local, national and regional dynamics diverts the attention from the Global Value Chains. Thus, it is recommended to analyse the global CE structure by applying the Global Value Chain framework, in order to investigate if it is possible to overcome the exposed CE’s limits.

Read the Report (PDF).

By Nick Meynen - EJOLT, October 15, 2014

Disclaimer: The views expressed here are not the official position of the IWW (or even the IWW’s EUC) and do not necessarily represent the views of anyone but the author’s.

While violent conflicts over rare metals used in our phones and laptops continue and e-waste keeps piling up, engineers break their heads over new ways to ensure that products die quicker.

It takes 244 kg of fossil fuel, 21,8 kg of chemicals and 1.5 tons of water to manufacture one computer and monitor. Carsten Wachholz, product policy officer from the European Environmental Bureau: “To offset the energy consumed to manufacture a laptop, it must be used for more than 20 years, even with a 20-30% efficiency improvement rate over that time”. The opposite is happening: computers made in 2010 have a 10% shorter lifespan than those made in 2000[1]. The same goes up for cell phones, iPods and so on. Unsurprisingly, the amount of e-waste created in the world keeps rising exponentially, to over 50 million tons of e-waste, annually.

The idea of planned obsolescence started with light bulbs, nylon socks and cars but it has now moved to all electronic devices, textbooks, washing machines, microwaves, software and almost every product that can possibly break or become ‘old-fashioned’. Engineers are asked to make sure that things go to the dump faster so you need to buy a new one quicker. This makes lots of money for the companies, but it has some nasty side-effects: increasing material and energy consumption on a planet with shrinking stocks and increasing waste. These are major drivers behind environmental injustices, which we have carefully mapped over the last three years of research. So let’s take a closer look at this source of so many evils and on how to stop it.