All Outputs (8)

Resource Recovery from Wastes: Towards a Circular Economy (2019)
Book
Macaskie, L. E., Sapsford, D. J., & Mayes, W. M. (Eds.). (2020). Resource Recovery from Wastes: Towards a Circular Economy. London: Royal Society of Chemistry. https://doi.org/10.1039/9781788016353

The concept of a circular economy has been gaining increasing attention in recent years. Many of the sources of chemicals we have become reliant on are dwindling and the accumulation of waste products poses a serious environmental problem. By recover... Read More about Resource Recovery from Wastes: Towards a Circular Economy.

A New Perspective on a Global Circular Economy (2019)
Book Chapter
Velenturf, A. P. M., Purnell, P., Macaskie, L. E., Mayes, W. M., & Sapsford, D. J. (2020). A New Perspective on a Global Circular Economy. In Resource recovery from wastes : towards a circular economy (3-22). Royal Society of Chemistry. https://doi.org/10.1039/9781788016353-00001

© The Royal Society of Chemistry 2020. Natural resource exploitation is accelerating in the face of resource decline, while at the same time people are generating ever growing quantities of wastes. Population and income growth drive up the demand for... Read More about A New Perspective on a Global Circular Economy.

Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues (2019)
Book Chapter
Gomes, H. I., Rogerson, M., Courtney, R., & Mayes, W. M. (2020). Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues. In Resource recovery from wastes: towards a circular economy (168-191). Cambridge: Royal Society of Chemistry. https://doi.org/10.1039/9781788016353-00168

With an estimated annual production of two billion tonnes globally, alkaline industrial wastes can be considered both major global waste streams, and materials that offer significant options for potential resource recovery. Alkaline wastes are usuall... Read More about Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues.

Governing Resource Flows in a Circular Economy: Rerouting Materials in an Established Policy Landscape (2019)
Book Chapter
Deutz, P., Baxter, H., & Gibbs, D. (2019). Governing Resource Flows in a Circular Economy: Rerouting Materials in an Established Policy Landscape. In L. E. Macaskie, D. J. Sapsford, & W. M. Mayes (Eds.), Resource Recovery from Wastes: Towards a Circular Economy (375-394). London: Royal Society of Chemistry. https://doi.org/10.1039/9781788016353-00375

The development of a Circular Economy, whereby resources are kept in circulation for the extraction of maximum value, has captured extensive policy and academic attention. The circularisation of material flows is likely to prove a task for a generati... Read More about Governing Resource Flows in a Circular Economy: Rerouting Materials in an Established Policy Landscape.

What Causes Carbonates to Form “Shrubby” Morphologies? An Anthropocene Limestone Case Study (2019)
Journal Article
Bastianini, L., Rogerson, M., Mercedes-Martín, R., Prior, T. J., Cesar, E. A., & Mayes, W. M. (2019). What Causes Carbonates to Form “Shrubby” Morphologies? An Anthropocene Limestone Case Study. Frontiers in Earth Science, 7, Article 236. https://doi.org/10.3389/feart.2019.00236

The South Atlantic Aptian “Pre-Salt” shrubby carbonate successions offshore Brazil and Angola are of major interest due to their potential hydrocarbon accumulations. Although the general sedimentology of these deposits is widely recognized to be with... Read More about What Causes Carbonates to Form “Shrubby” Morphologies? An Anthropocene Limestone Case Study.

Atmospheric carbon capture performance of legacy iron and steel waste (2019)
Journal Article
Pullin, H., Bray, A. W., Burke, I. T., Muir, D. D., Sapsford, D. J., Mayes, W. M., & Renforth, P. (2019). Atmospheric carbon capture performance of legacy iron and steel waste. Environmental Science and Technology, 53(16), 9502-9511. https://doi.org/10.1021/acs.est.9b01265

Legacy iron (Fe) and steel wastes have been identified as a significant source of silicate minerals, which can undergo carbonation reactions and thus sequester carbon dioxide (CO2). In reactor experiments, i.e., at elevated temperatures, pressures, o... Read More about Atmospheric carbon capture performance of legacy iron and steel waste.

Constructed wetlands for steel slag leachate management: Partitioning of arsenic, chromium, and vanadium in waters, sediments, and plants (2019)
Journal Article
Gomes, H., Mayes, W. M., Whitby, P., & Rogerson, M. (2019). Constructed wetlands for steel slag leachate management: Partitioning of arsenic, chromium, and vanadium in waters, sediments, and plants. Journal of environmental management, 243, 30-38. https://doi.org/10.1016/j.jenvman.2019.04.127

© 2019 The Authors Constructed wetlands can treat highly alkaline leachate resulting from the weathering of steel slag before reuse (e.g. as aggregate)or during disposal in repositories and legacy sites. This study aimed to assess how metal(loid)s s... Read More about Constructed wetlands for steel slag leachate management: Partitioning of arsenic, chromium, and vanadium in waters, sediments, and plants.

Optimization Routes for the Bioleaching of MSWI Fly and Bottom Ashes Using Microorganisms Collected from a Natural System (2019)
Journal Article
Funari, V., Gomes, H. I., Cappelletti, M., Fedi, S., Dinelli, E., Rogerson, M., …Rovere, M. (2019). Optimization Routes for the Bioleaching of MSWI Fly and Bottom Ashes Using Microorganisms Collected from a Natural System. Waste and biomass valorization, 10(12), 3833-3842. https://doi.org/10.1007/s12649-019-00688-9

This paper presents a route for the treatment of MSWI fly (FA) and bottom ashes (BA) using microorganisms to critically assess whether bioleaching is within reach of effective industrial application. The leaching of metals from BA and FA was investig... Read More about Optimization Routes for the Bioleaching of MSWI Fly and Bottom Ashes Using Microorganisms Collected from a Natural System.