The major pollution event caused by the breach of a dam containing red mud (a by-product of bauxite ore processing for alumina manufacture) at Kolontár in Hungary received widespread international media attention in early October 2010. This is the first event of its type and scale in Europe. While there have been similar events where dams holding mine wastes have failed, which are often acidic or rich in cyanide and ecotoxic metals, there have not previously been documented large scale releases of waste material with the extremely alkaline nature such as that released at Kolontár. Initial environmental monitoring at the site was focussed on the immediate impacts of the hyperalkaline (pH up to 13) water on the receiving streams, which had a major effect on instream organisms for over 50 miles. Beyond this short-term impact and given the lack of precedent for such events, we know relatively little about the longer-term behaviour of the potential contaminants released in the red mud. At other sites affected by hyperalkaline waters from red mud (albeit on a far smaller scale), such contaminants of concern include aluminium, arsenic, molybdenum and vanadium. This study aims to undertake a detailed analysis of the sediments and waters downstream of the spill to assess the nature and form of these, and other trace contaminants. This information is crucial to (a) characterise the spatial extent and severity of the polluted area, (b) assess which specific contaminants are present in the waters and sediments at levels of environmental significance and (c) understand the long-term prospects for mobility and availability of trace elements in the river systems downstream of Kolontár. Detailed sampling of the different phases (e.g. suspended in water, dissolved in water, settled on streambed) of contaminants along the impacted areas of the Marcal, Raba and Mosoni-Duna rivers will be undertaken. The field sampling will be coupled with laboratory tests on the mobility of contaminants in the sludge. Together, these data will help us understand the spatial trends in nature and form of contaminants and how key variables such as pH and the particle size distribution of the released materials are likely to affect their long term mobility in the environment. The work will be undertaken in liaison with scientists in Hungary and the outputs of the work will directly inform long-term management of the pollution spill. Beyond the direct relevance to management of the situation in Hungary, the improved understanding on how trace contaminants from caustic waste materials behave in the environment after such a major event will be useful for informing environmental management at other polluted sites.

The proposed new CCP-WSI+ builds on the impact generated by the Collaborative Computational Project in Wave Structure Interaction (CCP-WSI) and extends it to connect together previously separate communities in computational fluid dynamics (CFD) and computational structural mechanics (CSM). The new CCP-WSI+ collaboration builds on the NWT, will accelerate the development of Fully Coupled Wave Structure Interaction (FCWSI) modelling suitable for dealing with the latest challenges in offshore and coastal engineering. Since being established in 2015, CCP-WSI has provided strategic leadership for the WSI community, and has been successful in generating impact in: Strategy setting, Contributions to knowledge, and Strategic software development and support. The existing CCP-WSI network has identified priorities for WSI code development through industry focus group workshops; it has advanced understanding of the applicability and reliability of WSI through an internationally recognised Blind Test series; and supported collaborative code development. Acceleration of the offshore renewable energy sector and protection of coastal communities are strategic priorities for the UK and involve complex WSI challenges. Designers need computational tools that can deal with complex environmental load conditions and complex structures with confidence in their reliability and appropriate use. Computational tools are essential for design and assessment within these priority areas and there is a need for continued support of their development, appropriate utilisation and implementation to take advantage of recent advances in HPC architecture. Both the CFD and CSM communities have similar challenges in needing computationally efficient code development suitable for simulations of design cases of greater and greater complexity and scale. Many different codes are available commercially and are developed in academia, but there remains considerable uncertainty in the reliability of their use in different applications and of independent qualitative measures of the quality of a simulation. One of the novelties of this CCP is that in addition to considering the interface between fluids and structures from a computational perspective, we propose to bring together the two UK expert communities who are leading developments in those respective fields. The motivation is to develop FCWSI software, which couples the best in class CFD tools with the most recent innovations in computational solid mechanics. Due to the complexity of both fields, this would not be achievable without interdisciplinary collaboration and co-design of FCWSI software. The CCP-WSI+ will bring the CFD and CSM communities together through a series of networking events and industry workshops designed to share good practice and exchange advances across disciplines and to develop the roadmap for the next generation of FCWSI tools. Training and workshops will support the co-creation of code coupling methodologies and libraries to support the range of CFD codes used in an open source environment for community use and to aid parallel implementation. The CCP-WSI+ will carry out a software audit on WSI codes and the data repository and website will be extended and enhanced with database visualisation and archiving to allow for contributions from the expanded community. Code developments will be supported through provision and management of the code repository, user support and training in software engineering and best practice for coupling and parallelisation. By bringing together two communities of researchers who are independently investigating new computational methods for fluids and structures, we believe we will be able to co-design the next generation of FCWSI tools with realism both in the flow physics and the structural response, and in this way, will unlock new complex applications in ocean and coastal engineering