Earth has become a huge mine, with a greater quantity and variety of fundamental mineral resources being extracted year after year. Technology, from electric cars to everyday electrical equipment, consume vast amounts of scarce raw materials. On a planet with limited resources, are these minerals being properly assessed? Will there be enough raw materials to meet the demand of a world population on track to reach 10 billion people? What will be the consequences of accelerated resource depredation? Will the planet one day become 'Thanatia', a resource-exhausted Earth? This book allows readers to understand the mineral heritage of the Earth, considering the demand for raw materials in society, comparing it with the availability of resources on Earth and the impact of mining. The basics of physical geonomics are exlpained, allowing readers to analyse the loss of mineral resources on the planet. The impact of renewable energies and technologies, including electric vehicles, are studied. The book concludes with possible solutions to mineral depletion, from increasing recycling rates, ecodesign measures or alternative sources of mineral resources. Providing numerous tables and illustrations, 'The Material Limits of Energy Transition: Thanatia' gives readers a thorough understanding of mineral depletion. Exploring geology, geochemistry, mining, metallurgy, the environment and thermodynamics, this is a truly holistic book.

Earth has become a huge mine, with a greater quantity and variety of fundamental mineral resources being extracted year after year. Technology, from electric cars to everyday electrical equipment, consume vast amounts of scarce raw materials. On a planet with limited resources, are these minerals being properly assessed? Will there be enough raw materials to meet the demand of a world population on track to reach 10 billion people? What will be the consequences of accelerated resource depredation? Will the planet one day become 'Thanatia', a resource-exhausted Earth? This book allows readers to understand the mineral heritage of the Earth, considering the demand for raw materials in society, comparing it with the availability of resources on Earth and the impact of mining. The basics of physical geonomics are exlpained, allowing readers to analyse the loss of mineral resources on the planet. The impact of renewable energies and technologies, including electric vehicles, are studied. The book concludes with possible solutions to mineral depletion, from increasing recycling rates, ecodesign measures or alternative sources of mineral resources. Providing numerous tables and illustrations, 'The Material Limits of Energy Transition: Thanatia' gives readers a thorough understanding of mineral depletion. Exploring geology, geochemistry, mining, metallurgy, the environment and thermodynamics, this is a truly holistic book.

Is Gaia becoming Thanatia, a resource exhausted planet? For how long can our high-tech society be sustained in the light of declining mineral ore grades, heavy dependence on un-recycled critical metals and accelerated material dispersion? These are all root causes of future disruptions that need to be addressed today. This book presents a cradle-to-cradle view of the Earth's abiotic resources through a novel and rigorous approach based on the Second Law of Thermodynamics: heat dissipates and materials deteriorate and disperse. Quality is irreversibly lost. This allows for the assessment of such depletion and can be used to estimate the year where production of the main mineral commodities could reach its zenith. By postulating Thanatia, one acquires a sense of destiny and a concern for a unified global management of the planet's abiotic resource endowment. The book covers the core aspects of geology, geochemistry, mining, metallurgy, economics, the environment, thermodynamics and thermochemistry. It is supported by comprehensive databases related to mineral resources, including detailed compositions of the Earth's layers, thermochemical properties of over 300 substances, historical energy and mineral resource inventories, energy consumption and environmental impacts in the mining and metallurgical sector and world recycling rates of commodities.

Critical minerals play a vital role in the ongoing energy transition, which aims to shift global energy systems towards more sustainable and low-carbon alternatives. These minerals, also known as critical minerals, are essential components in various clean energy technologies such as wind turbines, solar panels, electric vehicles, and energy storage systems. They possess unique properties that enable efficient energy generation, storage, and transmission. For instance, neodymium, a rare earth element, is crucial for the production of high-performance magnets used in wind turbines and electric motors. Lithium, another critical mineral, is a key component in rechargeable batteries powering electric vehicles and energy storage solutions. As the demand for clean energy technologies continues to rise, securing a sustainable and reliable supply of critical minerals becomes increasingly important to support the global energy transition and reduce dependence on fossil fuels. In this book, we investigate various aspects of critical mineral governance in the context of sustainability transition. We give perspectives around the critical metal requirements of sustainability transition in a forward-looking manner. We discuss the answers to the following questions: What role do the critical raw materials play in the transition to a sustainable economy and energy systems transformation? What are the bottlenecks in achieving a sustainable critical material supply? How do the critical minerals enable renewable energy transition and sustainable development? What is their role in the sustainability transition? How is mineral criticality assessed? And how critical are minerals? What are some regional differences in terms of critical mineral availability, processing capacity, and the supply chain? What strategy should be followed in deciding between primary raw materials and secondary raw materials in supplying critical raw materials for the transition to a sustainable economy? What is the (known) critical material budget, and how does it fit with the climate pledges? The authors of the chapters of this book take a multi-perspective approach and provide insights from industrial ecology, environmental engineering, and sustainable management of natural resources. The information provided will help readers to understand critical metal requirements of present and future key technologies and will help societies to develop and implement sustainable supply strategies.

This book is the first to fully explore the short- and long-term impact of the global electric car rollout on the supply of raw materials. The world has gone from zero to almost 1.5 billion fossil fuel cars in circulation today, contributing significantly to the global climate crisis and necessitating a total transition to electric vehicles in the coming decades. This book responds to key questions surrounding the increase of electric car usage, such as will there be sufficient resources available to permanently supply a future world population of ten billion with electric cars? What is the risk that the supply of essential raw materials will be hampered by geopolitical problems, or that mining capacity cannot be quickly scaled up? How does the switch from fossil fuel vehicles to electric cars impact the recycling of scrap cars? It contains detailed information about the material composition of electric and fossil fuel cars in relation to stocks and relative scarcity of corresponding materials in the earth’s crust and estimates the ultimate annual consumption of metals based on predicted population growth. This book is an important tool for decision- makers in national ministries and international bodies, highlighting how to adopt a global long-term raw materials policy to protect the interests of future generations and global fairness. It provides necessary forecasting insight to industry leaders and specialists, policymakers, and researchers.

The Digital Economy Report 2024 turns the attention to the environmental footprint of digitalization. The Report discusses environmental impacts along the life cycle of digital devices and information and communications technology infrastructure with regard to raw material extraction and processing, manufacturing, distribution; use and the end-of-life phase. The direct effects on natural resources, including transition minerals, energy and water, as well as greenhouse gas emissions and waste-related pollution can be said to constitute the “environmental footprint” of the ICT sector. There are also indirect environmental effects from the use of digital technologies and services in different sectors of the economy, and the Report includes a dedicated chapter on e-commerce. The report underlines the need to maximize the positive impact of digitalization while minimizing the negative impacts on environmental sustainability.

This book examines ways of assessing the rational management of nonrenewable resources. Integrating numerous methods, it systematically exposes the strengths of exergy analysis in resources management. Divided into two parts, the first section provides the theoretical background to assessment methods, while the second section provides practical application examples. The topics covered in detail include the theory of exergy cost and thermo-ecological cost, cumulative calculus and life cycle evaluation. This book serves as a valuable resource for researchers looking to investigate a range of advanced thermodynamic assessments of the influence of production processes on the depletion of nonrenewable resources.