Industry

Industry holds an indispensable relationship with the Sustainable Development Goals (SDGs) formulated by the United Nations, illuminating the fact that sustainable industrial development plays a vital role in achieving these global objectives. Industry, particularly manufacturing, serves as a critical driver for economic growth, employment, and technological advancement. SDG 9, specifically, underlines the importance of industry, innovation, and infrastructure, underscoring the need for resilient infrastructure, inclusive and sustainable industrialization, and fostering innovation. However, the intricate interlinkages between industry and other SDGs must not be overlooked.

For instance, clean and sustainable industrial processes contribute significantly to SDG 13, aiming at climate action, by reducing greenhouse gas emissions, improving energy efficiency, and adopting clean and environmentally sound technologies. Similarly, SDG 12, responsible consumption and production, demands the industries to promote resource and energy efficiency, sustainable infrastructure, and provide access to basic services, green and decent jobs, and a better quality of life for all. It motivates industries to adopt sustainable practices and to integrate sustainability information into their reporting cycle.

The role of industries extends to SDG 8 (Decent work and Economic Growth) as industries stimulate economic activities that lead to job creation and thus, improve living standards. Also, in respect to SDG 5 (Gender Equality), industrial sectors have the potential to provide opportunities for women in the workforce and help bridge the gender wage gap.

Nevertheless, the transformation to a more sustainable industry is not without challenges. The demands of rapid technological changes, the need for significant capital investments in green technologies, and the transition to a circular economy are some of the hurdles industry faces. Further, this transformation requires a multilevel and multi-stakeholder approach, calling for cooperation among governments, private sectors, academia, and civil society to pave the path to achieving SDGs.

Elsevier, Sustainable Materials and Technologies, Volume 16, July 2018
Sensing volatile organic compounds (VOC) is a promising approach in particular for the development of non-invasive, fast and inexpensive tool for the anticipated diagnostic of diseases and monitoring of exposition to toxic molecules. This paper examines for the first time the potential of biobased carbon nanorods (CNR), synthesized by a simple and green method in gram scale via the pyrolysis of castor oil, to build the conducting architecture of quantum resistive vapour sensors (vQRS).
Elsevier, Sustainable Materials and Technologies, Volume 16, July 2018
This paper contributes to the understanding of metal demand development over time by illustrating the impacts of different aspects of technological change using historical data. We provide a direct, quantitative comparison of relative change in global primary production for 30 metals over 21 years (1993–2013), capturing the range and variation of demand development for different metals within this period. The aspects of technological change contributing to this variation are investigated in more depth for nine metals.
Elsevier, Journal of Building Engineering, Volume 18, July 2018
The European Union implemented Ecodesign and Labelling Directives to support the market diffusion of energy efficient products. Accurate signals for consumers on energy efficiency (EE) are essential, as disinformation might lead to sub-optimal market allocations. Considering complex devices such as heat pumps (HPs), a conflict between simplicity of calculation on the one hand and accuracy on the other hand arises.

Successful Food-energy-water (FEW) nexus projects will be more likely to succeed if a transdisciplinary approach is used. Ecological modernization (ecological technology) policies and practices, and sustainable supply chains influence the FEW nexus from a commerce and industry perspective. Taking these perspectives and considering their intertwined linkages is important for advancing research and adoption of FEW nexus efforts. This paper provides an overview of these perspectives and interlinkages.

All-Energy 2018
All-Energy, the UK’s largest renewable energy and low carbon event, is taking place on 2nd & 3rd of May 2018 in Glasgow; it brings together the UK’s largest group of buyers across the value chain, including investors, project developers, end users and policy makers, among others. Showcasing the complete range of renewable and sustainable technologies and with a world-class free-to-attend conference alongside, All-Energy brings together over 7,500 supply chain and business energy end users – including the largest group of renewable energy developers and supply chain partners seen anywhere in the UK.
Elsevier, Sustainable Materials and Technologies, Volume 15, April 2018
As the technologies we use as a society have advanced, so have the materials used in these technologies. Some of these materials are exotic and highly specialized, making them particularly vulnerable to supply disruptions and supply disruptions particularly impactful. Such materials are designated as “critical” materials. Their level of criticality can be identified by accounting for a number of factors related to their supply risk and the extent to which a supply disruption would impact business operations or society at large.
Elsevier, Sustainable Materials and Technologies, Volume 15, April 2018
According to the reports on critical raw materials for the EU, a raw material is considered critical if it has a high economic importance to the EU combined with high supply risk. Supply risk is considered to arise from a combination of several factors, namely a high concentration of production in countries with poor governance, limited material substitutability, and poor end-of-life recycling rates. A number of industry activities, policy initiatives and research projects have recently been initiated in Europe with the aim to secure an adequate supply of raw materials.
Elsevier, Sustainable Materials and Technologies, Volume 15, April 2018
According to the reports on critical raw materials for the EU, a raw material is considered critical if it has a high economic importance to the EU combined with high supply risk. Supply risk is considered to arise from a combination of several factors, namely a high concentration of production in countries with poor governance, limited material substitutability, and poor end-of-life recycling rates. A number of industry activities, policy initiatives and research projects have recently been initiated in Europe with the aim to secure an adequate supply of raw materials.
Over the past decade, raw material price spikes have called attention to the supply security of a variety of critical materials, including rhenium, rare earth elements, and helium. While market forces play an important role in creating and resolving these situations, transitions in technology also create step-changes in demand that increase or decrease the criticality of different materials. With an appropriate understanding of how materials are used in various applications, it is possible to explore the critical materials implications associated with the introduction of new technologies.
Elsevier, Sustainable Materials and Technologies, Volume 15, April 2018
As the technologies we use as a society have advanced, so have the materials used in these technologies. Some of these materials are exotic and highly specialized, making them particularly vulnerable to supply disruptions and supply disruptions particularly impactful. Such materials are designated as “critical” materials. Their level of criticality can be identified by accounting for a number of factors related to their supply risk and the extent to which a supply disruption would impact business operations or society at large.

Pages