The NHP-WEC project aims to advance data-driven monitoring and control in connection to both device technology and sea state predictions for WEC arrays. The research proposed is simultaneously generic while also significantly contributing to the development of an existing concept device that has shown potential, namely the multi-axis TALOS that has been developed and tank tested at Lancaster University (LU). TALOS is a novel multi-axis point absorber-style built as a 1/100th scale representation, with a solid outer hull containing all the moving parts (like a submarine or a PS Frog style WEC device). The internal PTO system is made up of an inertial mass with hydraulic cylinders that attach it to the hull. The mass makes up a significant proportion of the device, hence it moves around as the hull is pushed by various wave motions. The motion of the ball moves hydraulic cylinders causing them to pump hydraulic fluid through a circuit. The flow of this hydraulic fluid is used to turn a hydraulic motor, which is coupled to an electrical generator, to generate electricity i.e. an inertial mass PTO approach. Key strengths include: The arrangement of the rams allows for the mass ball to move in multiple directions, allowing energy to be captured from multiple degrees of freedom. The flow of hydraulic fluid will change as the ball's motion changes, so an internal hydraulic smoothing circuit is utilised to regulate the output. The latest design has proven to be successful in wave tank testing and the PTO system yields a smooth output in response to time-varying inputs from waves. An analytical model has also been developed to combine data from the hull model and hydraulic rig, yielding a predicted power output of up to 3.2 kW. However, TALOS is at a very early stage of development and requires further research to advance its Technology Readiness Level (TRL). The design, development, deployment and operation of WECs, such as TALOS and their potential commercial use requires a holistic understanding of the marine environment, including on-line monitoring to enhance control combined with prediction. Potential WEC deployment sites and energy resource from single devices and arrays must be determined. Operational conditions, including wave characteristics must be quantified to estimate dynamic loads on WEC, constraining manufacturing and their real-time operation. In this context, SmartWave, developed by the UoH, with the ORE Catapult and Orsted, is a tool capable of deriving high resolution sea state conditions from satellite images using machine learning. Key strengths: SmartWave is based on a novel forecasting methodology, capable of resolving sea state within offshore windfarms for sector O&M logistics. It integrates recent advances in all-weather satellite monitoring to map and study the temporal and spatial distribution of sea surface wave characteristics. However, existing limitations must be addressed to advance the TRL of WEC capabilities and hence fully exploit this new technology. For example, it has been developed to characterize significant wave height, whilst further research is essential in order to extract other sea state parameters, including wave height, direction and frequency. Nonetheless, since it is capable of global reach remotely, without the use of in situ sensors, SmartWave is uniquely placed to identify the selection of appropriate deployment sites depending on the device size and specification, for optimal production of electricity. The NHP-WEC project brings together key aspects of WEC technology and the global deployment potential of SmartWave, allowing integration of novel methodologies across optimisation, control, condition monitoring and resource forecasting. These advances will together drive evidenced reductions in costs and hence provide confidence on the benefits of wave energy technology to developers and investors.

The need for the UK to shift to NetZero was highlighted at COP26 in Glasgow, and there is a clear need for UK energy security. UK policy to achieving these is based on massive expansion of off-shore wind. In 2022 Crown Estate Scotland "ScotWind" auctioned 9,000 km2 of sea space in the northern North Sea, with potential to provide almost 25 GW of offshore wind. Further developments are planned elsewhere, for example, the 300 MW Gwynt Glas Offshore Wind Farm in the Celtic Sea. These developments mark a shift in off-shore wind generation, away from shallow, well mixed coastal waters to deeper, seasonally stratified shelf seas This shift offers both challenges and opportunities which this proposal will explore. Large areas of the NW European shelf undergo seasonal thermal stratification. This annual development of a thermocline, separating warm surface water from cold deep water, is fundamental to biological productivity. Spring stratification drives a bloom of growth of the microscopic phytoplankton that are the base of marine food chains. During summer the surface layer is denuded of nutrients and primary production continues in a layer inside the thermocline, where weak turbulent mixing supplies nutrients from the deeper water and mixes oxygen and organic material downward. Tidal flows generate turbulence; the strength of turbulence controls the timing of the spring bloom, mixing at the thermocline, and the timing of remixing of the water in autumn/winter. Determining the interplay between mixing and stratification is fundamental to understanding how shelf sea biological production is supported. Arrays of large, floating wind turbines are now being deployed over large areas of seasonally-stratifying seas. These structures will inject extra turbulence into the water, as tidal flows move through and past them. This extra turbulence will alter the balance between mixing and stratification: spring stratification and the bloom could occur later, biological growth inside the thermocline could be increased, and more oxygen could be supplied into the deep water. There could be significant benefits of this extra mixing, but we need to understand the whole suite of effects caused by this mixing to aid large-scale roll-out of deep-water renewable energy. eSWEETS will conduct observations at an existing floating wind farm in the NW North Sea to determine how the extra mixing generated by tides passing through the farm affect the physics, biology and chemistry of the water. We will measure the mixing of nutrients, organic material and oxygen within the farm, and track the down-stream impacts of the mixing as the water moves away from the wind farm and the phytoplankton respond to the new supply of nutrients. We will use autonomous gliders to observe the up-stream and down-stream contrasts in stratification and biology all the way through the stratified part of the year. We will use our observations to formulate the extra mixing in a computer model of the NW European shelf, so that we can then use the model to predict how planned renewable energy developments over the next decades might affect our shelf seas and how those effects might help counter some of the changes we expect in a warming climate. Stratification is so fundamental to how our seas support biological production that we will develop a new, cost-effective way of monitoring it. We will work with the renewables industry and modellers at the UK Met Office on a technique that allows temperature measurements to be made along the power cables that lie on the seabed between wind farms and the coast. Our vision is that large-scale roll-out of windfarms will lead to the ability to measure stratification across the entire shelf. This monitoring will help the industry (knowledge of operating conditions), government regulators (environment responses to climate change) and to operational scientists at the UK Met Office (constraining models for better predictions).

Natural flows shape our environment. Virtually every part of the planet can be put in the context, or at the interface, of transdisciplinary processes shaped by fluid dynamics, from: mantle convection, driving tectonic plate movement and geohazards; energy sources driving ocean currents and mixing, controlling marine life; the dispersal of water, nutrients and pollutants through terrestrial systems, critical to life on land; to the risks from extreme weather, in a changing climate. Although, numerical models exist that capture many aspects of these flows, they are fundamentally limited by the complexity, and critically, the range of scales present in the natural environment. Thus, lack of understanding of the natural world often stems from lack of empirical data of environmental flows. Empirical data are key to motivate new understanding of fluid dynamics and thus the natural environment. Data are often derived from controlled experiments, studying fundamental processes. Yet, to deliver impact, these processes need to be placed in real-world context. Three-dimensional, and temporal, data are key to understand complex flows inherent to nature. Yet whilst common in numerical models, such data are rare in current empirical research. Our capability to quantify the dynamics of environmental flows is in many respects more limited than numerical models. Only now has recent advances in technology placed the ability to address long-standing limitations of empirical data of environmental flows within our grasp. The Future of Advanced Metrology for Environmental fluid dynamics (FAME) project makes a world-leading contribution to research capability, by: 1) advancing globally unique capacity to collect complete empirical datasets of environmental flows; 2) scaling experimental fluid dynamics to the real-world. Synergistic integration of a suite of novel equipment, based on novel volumetric flow measurement, addresses these goals and supports step-change advances across natural environmental science. Leading experts at Hull, extensively supported by academia and industry, will integrate the suite of new equipment, including: Advanced optical flow measurement equipment that can disentangle the dynamics of the different fluid, particulate and chemical components that comprise natural flows; Submersible optical measurement equipment that translates capability to resolve flows, previously only available in laboratory conditions, to real-world scales; and Acoustic imaging of naturally cloudy environmental flows, where optical techniques cannot be used. Through integration of this suite of equipment, FAME affords globally unique capability to resolve flows across a range of environments and scales, providing new data needed for research into key societal challenges. By enabling access to both equipment, and critically the unique datasets that will be generated, FAME will motivate the next generation of community research into the natural environment.

The UK is leading the development and installation of offshore renewable energy technologies. With over 13GW of installed offshore wind capacity and another 3GW under construction, two operational and one awarded floating offshore demonstration projects as well as Contracts for Difference awards for four tidal energy projects, offshore renewable energy will provide the backbone of the Net Zero energy system, giving energy security, green growth and jobs in the UK. The revised UK targets that underpin the Energy Security Strategy seek to grow offshore wind capacity to 50 GW, with up to 5 GW floating offshore wind by 2030. Further acceleration is envisaged beyond 2030 with targets of around 150 GW anticipated for 2050. To achieve these levels of deployment, ORE developments need to move beyond current sites to more challenging locations in deeper water, further from shore, while the increasing pace of deployment introduces major challenges in consenting, manufacture and installation. These are ambitious targets that will require strategic innovation and research to achieve the necessary technology acceleration while ensuring environmental sustainability and societal acceptance. The role of the Supergen ORE Hub 2023 builds on the academic and scientific networks, traction with industry and policymakers and the reputation for research leadership established in the Supergen ORE Hub 2018. The new hub will utilise existing and planned research outcomes to accelerate the technology development, collaboration and industry uptake for commercial ORE developments. The Supergen ORE Hub strategy will focus on delivering impact and knowledge transfer, underpinned by excellent research, for the benefit of the wider sector, providing research and development for the economic and social benefit of the UK. Four mechanisms for leverage are envisaged to accelerate the ORE expansion: Streamlining ORE projects, by accelerating planning, consenting and build out timescales; upscaling the ORE workforce, increasing the scale and efficiency of ORE devices and system; enhanced competitiveness, maximising ORE local content and ORE economic viability in the energy portfolio; whilst ensuring sustainability, yielding positive environmental and social benefits from ORE. The research programme is built around five strategic workstreams, i) ORE expansion - policy and scenarios , ii) Data for ORE design and decision-making, iii) ORE modelling, iv) ORE design methods and v) Future ORE systems and concepts, which will be delivered through a combination of core research to tackle sector wide challenges in a holistic and synergistic manner, strategic projects to address emerging sector challenges and flexible funding to deliver targeted projects addressing focussed opportunities. Supergen Representative Systems will be established as a vehicle for academic and industry community engagement to provide comparative reference cases for assessing applicability of modelling tools and approaches, emerging technology and data processing techniques. The Supergen ORE Hub outputs, research findings and sector progress will be communicated through directed networking, engagement and dissemination activities for the range of academic, industry and policy and governmental stakeholders, as well as the wider public. Industry leverage will be achieved through new co-funding mechanisms, including industry-funded flexible funding calls, direct investment into research activities and the industry-funded secondment of researchers, with >53% industry plus >23% HEI leverage on the EPSRC investment at proposal stage. The Hub will continue and expand its role in developing and sustaining the pipeline of talent flowing into research and industry by integrating its ECR programme with Early Career Industrialists and by enhancing its programme of EDI activities to help deliver greater diversity within the sector and to promote ORE as a rewarding and accessible career for all.