Your search keyword '"Petavratzi, Evi"' showing total 8 results

1. Maps of the physical economy to inform sustainability strategies

Author

Müller, Daniel B., primary, Billy, Romain G., additional, Simoni, Mark U., additional, Petavratzi, Evi, additional, Liu, Gang, additional, Rechberger, Helmut, additional, and Cullen, Jonathan, additional

Published

2024

2. Contributors

Author

Allwood, Julian M., primary, Antrekowitsch, J., additional, Arnout, S., additional, Backes, Chris, additional, Bartie, Neill J., additional, Billy, Romain G., additional, Blanpain, B., additional, Brandner, U., additional, Brenner, Tobias, additional, Brusselaers, Jan, additional, Campbell-Johnston, K., additional, Chen, Xiaozheng, additional, Chintinne, M., additional, Cullen, Jonathan, additional, Dodoo, Ambrose, additional, Doutre, Don, additional, Dubois, Maarten, additional, Dyer, Thomas D., additional, Erik Spiller, D., additional, Evangelista, Ana Catarina Jorge, additional, Eyckmans, Johan, additional, Feil, Alexander, additional, Gerold, Eva, additional, Goorhuis, Maarten, additional, Greiff, Kathrin, additional, Grossmann, Harald, additional, Gustavsson, Leif, additional, Hagelüken, Christian, additional, Hamann, Dorothea, additional, Handke, Toni, additional, Hanke, G., additional, Hawley, Jana M., additional, Heiskanen, Kari, additional, Ignatenko, Olga, additional, Karreman, Sandor, additional, Krampitz, Thomas, additional, Kreschel, Thilo, additional, Kroell, Nils, additional, Kuik, Onno, additional, Kuiper, Pieter, additional, Kvithyld, Anne, additional, Langeveld, Gijs, additional, Lieberwirth, Holger, additional, Liu, Gang, additional, Llamas, Alejandro Abadías, additional, Luidold, Stefan, additional, Meskers, Christina, additional, Müller, Daniel B., additional, Nelson, Priscilla P., additional, Oosterhuis, Frans, additional, Ottiger, Fabian, additional, Peck, David, additional, Petavratzi, Evi, additional, Pontikes, Y., additional, Rechberger, Helmut, additional, Reuter, Markus A., additional, Sathre, Roger, additional, Schlesinger, Mark E., additional, Schluep, Mathias, additional, Shen, Li, additional, Simoni, Mark U., additional, Snellings, R., additional, Soomro, Mahfooz, additional, Sorvari, Jaana, additional, Sprecher, Benjamin, additional, Steinlechner, S., additional, Stevenson, M., additional, Swinbourne, D.R., additional, Tam, Vivian W.Y., additional, Thüm, Sophia, additional, Valdivia, Sonia, additional, van Berkum, Susanne, additional, van Beukering, Pieter, additional, van Schaik, Antoinette, additional, van Zyl, H.C., additional, Vermeulen, W.J.V., additional, Volkova, Olena, additional, Wahlström, Margareta, additional, Wollants, Patrick, additional, Worrell, Ernst, additional, and Zöllner, Mareen, additional

Published

2024

3. Life cycle assessment and water use impacts of lithium production from salar deposits: Challenges and opportunities

Author

Halkes, Rowan T., Hughes, Andrew, Wall, Frances, Petavratzi, Evi, Pell, Robert, Lindsay, Jordan J., Halkes, Rowan T., Hughes, Andrew, Wall, Frances, Petavratzi, Evi, Pell, Robert, and Lindsay, Jordan J.

Abstract

Lithium is a critical raw material for the energy transition and the salar brine deposits of South America host ∼70% of global resources. However, there are concerns regarding water use, and the associated impacts, of lithium production from these deposits. Life Cycle Assessment (LCA) is becoming increasingly prevalent in the analysis of raw materials sustainability, but current methods are regarded as unsatisfactory for assessing water use impacts related to lithium production from salar deposits. This work explores the challenges and opportunities for improvement in this context. We outline how the classification and assessment of water types could be improved and identify Water Availability Assessments, groundwater specific CFs, salar-specific methodologies and multiple mid-point indicators as areas for further investigation. This will aid the development of LCA methodology and enable an improved assessment of the sustainability of lithium production from salar deposits in South America and by extension help decouple decarbonisation efforts from negative impacts.

Published

2024

4. Understanding the spatial variation in lithium concentration of high Andean Salars using diagnostic factors

Author

Al-Jawad, Jafar, Ford, Jonathan, Petavratzi, Evi, Hughes, Andrew, Al-Jawad, Jafar, Ford, Jonathan, Petavratzi, Evi, and Hughes, Andrew

Abstract

Salars (basins of internal drainage) in the “Lithium Triangle” countries (Argentina, Bolivia, Chile) hold >50 % of the global lithium resources within lithium-rich brines. Given the imperative for lithium production to enable the energy transition and that salars by their very nature are highly variable, so a framework to both characterise their differences as well as identifying their similarities would be beneficial to understanding their provenance and potential for exploitation. In this study, data for 29 salars based on environmental factors: rainfall, evaporation as well as their physical characteristic: pan size and basin size have been used to characterise them along with those describing their setting land-use/cover and geological outcrop. These parameters have been normalised by creating a ratio of the lithium concentration divided by the factor for each salar. Cross-correlation has been used to develop relationships between these normalised factors, combined with principal component analysis to identify clustering and to further characterise groupings of behaviours. Two such relationships emerge out of this process: regional and local. Regional covers factors such as elevation, precipitation, and evaporation; local includes size of watershed, salar nucleus, land cover and geological outcrop in the watershed. However, Salar de Atacama is identified as an outlier and so the transferability of the understanding of its provenance and operation must be treated with caution. Other salars could be added to the framework as more information becomes available. The methodology presented here could help exploration by characterising salars into categories as their smaller size may not necessarily mean lower lithium mass. Further, such a framework can inform policy decisions and instruments by recognising the complexity of salars combined with the need to understand the environmental impacts of brine extraction.

Published

2024

5. Mapping the flows and stocks of permanent magnets rare earth elements for powering a circular economy in the UK

Author

Hsu, Wan-Ting, Petavratzi, Evi, Zils, Markus, Einarsson, Stefán, Morasae, Esmaeil Khedmati, Lysaght, Oliver, Hopkinson, Peter, Hsu, Wan-Ting, Petavratzi, Evi, Zils, Markus, Einarsson, Stefán, Morasae, Esmaeil Khedmati, Lysaght, Oliver, and Hopkinson, Peter

Abstract

A transition towards renewable energy and transport electrification requires a high demand for rare earth elements (REE). China's dominance in REE makes the supply chains vulnerable for REE-consuming countries. The UK is one of the only three major refining plants outside of China, and it has, therefore, an active role in the global REE supply chain. In addition, the UK recycling capacity of REE permanent magnets is in development. Understanding REE flows and stocks is required both for scaling up upstream refining capacity and for the recycling projects that are currently in commercial development. This study developed a material flow model of REE in NdFeB magnets used in electric vehicles and wind turbines, taking the UK (2017–2021) as a case. Results show that the UK is a net importer (1238 t of REE in REE compounds, 7787 t of REE in NdFeB magnets) and has a highly fragmented value chain. A significant amount of the REE remains in stocks, whilst most end-of-life REE-containing components were not recovered. Substantial data challenges cause a lack of traceability across the global REE supply chain. This needs to be addressed in order to enhance knowledge of how these REE are utilised. The proposed model and policy interventions can be applied to other countries to improve traceability and circularity.

Published

2024

6. Greater circularity leads to lower criticality, and other links between criticality and the circular economy

Author

Tercero Espinoza, Luis, Schrijvers, Dieuwertje, Chen, Wei-Qiang, Dewulf, Jo, Eggert, Roderick, Goddin, James, Habib, Komal, Hagelüken, Christian, Hurd, Alan J., Kleijn, René, Ku, Anthony Y., Lee, Min-Ha, Nansai, Keisuke, Nuss, Philip, Peck, David, Petavratzi, Evi, Sonnemann, Guido, van der Voet, Ester, Wäger, Patrick A., Young, Steven B., Hool, Alessandra, Tercero Espinoza, Luis, Schrijvers, Dieuwertje, Chen, Wei-Qiang, Dewulf, Jo, Eggert, Roderick, Goddin, James, Habib, Komal, Hagelüken, Christian, Hurd, Alan J., Kleijn, René, Ku, Anthony Y., Lee, Min-Ha, Nansai, Keisuke, Nuss, Philip, Peck, David, Petavratzi, Evi, Sonnemann, Guido, van der Voet, Ester, Wäger, Patrick A., Young, Steven B., and Hool, Alessandra

Abstract

Society requires a stable and secure supply of raw materials. Raw materials supply stability and security are, amongst others, addressed by the concept of raw materials criticality, which focuses on the vulnerability of an economic unit (most commonly a country or region, but also the world, specific sectors, companies or products) to supply restrictions of certain mineral raw materials (cf. Schrijvers et al., 2020). The idea of keeping materials in the economic cycle for longer is specified in the Circular Economy (CE) concept, which encompasses efforts that reduce waste and improve material efficiency (Ellen McArthur Foundation, 2013; European Commission, 2018). So far, CE beyond recycling has not played a prominent role in the criticality debate. At the same time, critical raw materials (CRM) have only been a minor topic in the discussion on CE (recent exceptions include European Commission, 2018, and Gaustad et al., 2018). If properly aligned, criticality assessments might help in defining priority materials for the CE, and circularity strategies could substantially mitigate supply risks. In this paper, we explore the potential benefits, as well as caveats, of adopting a CE approach to CRM, based on our own experiences and our discussions organized by the IRTC (International Round Table on Materials Criticality) project.

Published

2020

7. Mapping the global flow of tungsten to identify key material efficiency and supply security opportunities

Author

Leal-Ayala, David R., Allwood, Julian M., Petavratzi, Evi, Brown, Teresa J., Gunn, Gus, Leal-Ayala, David R., Allwood, Julian M., Petavratzi, Evi, Brown, Teresa J., and Gunn, Gus

Abstract

Tungsten is an economically important metal with diverse applications ranging from wear resistant cutting tools to its use in specialized steels and alloys. Concerns about its supply security have been raised by various studies in literature, mostly due to trade disputes arising from supply concentration and exports restrictions in China and its lack of viable substitutes. Although tungsten material flows have been analysed for specific regions, a global mass flow analysis of tungsten is still missing in literature and its global supply chain remains opaque for industry outsiders. The objective of this paper is to create a map of global tungsten flows to highlight and discuss key material efficiency (i.e., using less of a material to make a product or supply a service, or reducing the material entering production but ending up in waste) and supply security opportunities along tungsten’s supply chain that could be incorporated into the planning and prioritization of future supply security strategies. The results indicate the existence of various intervention alternatives that could help to broaden the supply base and improve the overall material efficiency of the system. In particular, future policy and research and development (R&D) efforts to improve tungsten’s material efficiency should focus on minimizing tungsten losses as fine particles during beneficiation and extraction (current global losses estimated at 10–40%), as well as on evaluating alternatives to improve recycling collection systems and technologies, which could lead to 17–45% more tungsten discards being recycled into new products.

Published

2015

8. Understanding the spatial variation in lithium concentration of high Andean Salars using diagnostic factors.

Author

Al-Jawad J, Ford J, Petavratzi E, and Hughes A

Abstract

Salars (basins of internal drainage) in the "Lithium Triangle" countries (Argentina, Bolivia, Chile) hold >50 % of the global lithium resources within lithium-rich brines. Given the imperative for lithium production to enable the energy transition and that salars by their very nature are highly variable, so a framework to both characterise their differences as well as identifying their similarities would be beneficial to understanding their provenance and potential for exploitation. In this study, data for 29 salars based on environmental factors: rainfall, evaporation as well as their physical characteristic: pan size and basin size have been used to characterise them along with those describing their setting land-use/cover and geological outcrop. These parameters have been normalised by creating a ratio of the lithium concentration divided by the factor for each salar. Cross-correlation has been used to develop relationships between these normalised factors, combined with principal component analysis to identify clustering and to further characterise groupings of behaviours. Two such relationships emerge out of this process: regional and local. Regional covers factors such as elevation, precipitation, and evaporation; local includes size of watershed, salar nucleus, land cover and geological outcrop in the watershed. However, Salar de Atacama is identified as an outlier and so the transferability of the understanding of its provenance and operation must be treated with caution. Other salars could be added to the framework as more information becomes available. The methodology presented here could help exploration by characterising salars into categories as their smaller size may not necessarily mean lower lithium mass. Further, such a framework can inform policy decisions and instruments by recognising the complexity of salars combined with the need to understand the environmental impacts of brine extraction., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 British Geological Survey (C) UKRI 2023. Published by Elsevier B.V. All rights reserved.)

Published

2024