The four trends reshaping the UK’s energy resilience

Shaping the future of energy security

For over 50 years, Shell has used scenarios to explore how the energy system might evolve. The 2025 Energy Security Scenarios are developed using rigorous modelling and expert insight, factoring in shifts in technology, geopolitics and economics.

While they are not forecasts, nor are they expressions of Shell’s strategy or business plan, they are designed to help business leaders and policymakers explore and plan.

In the 2025 Energy Security Scenarios: Energy and Artificial Intelligence report, Shell considers three possible future scenarios:

• Surge: A scenario driven by rapid productivity growth, enabled by new technologies including AI, and economic expansion, where energy demand rises significantly and modular, tech-driven systems play a central role.
• Archipelagos: A fragmented world shaped by heightened geopolitical tensions and national self-reliance, with slower, uneven energy transitions and an emphasis on supply security.
• Horizon: A scenario that models what it would take to reach net-zero emissions by 2050 and limit global warming to 1.5°C by the end of the century compared to pre-industrial levels, requiring global cooperation and policy ambition.

But what does this mean for business leaders in energy-intensive industries in the UK? Here, we present four key energy trends from Shell’s 2025 Energy Security Scenarios report that can help energy procurement specialists and industrials leaders consider possible scenarios and think differently about preparing for a more resilient energy future.

Four energy trends for industrial customers to watch

While the energy system continues to embrace renewables, natural gas, liquefied natural gas (LNG) and biomethane are expected to continue to play an important role in meeting energy demand, especially for energy-intensive industries like industrials. Unlike coal, natural gas can be turned on and off quickly which assists with grid balancing. Such factors help make these lower-carbon alternatives a pragmatic stepping stone on the journey to helping customers to meet their decarbonisation ambitions, offering flexible energy at scale.

In all three Shell scenarios, demand for LNG is likely to grow significantly in the near term, reaching 550 million tonnes per year (mtpa) by the end of the decade. In the Surge scenario, LNG supply could reach 700 mtpa by the 2040s.²

According to The 2025 Energy Security Scenarios report, biofuels use is also expected to grow. Currently, they make up around 4% of the global liquid fuel market, but that share could triple by 2050, especially if advancements in conversion technologies continue – as Shell’s scenarios suggest.  Looking at the UK, the biofuels market is expected to grow by around 11% from 2024 to 2030 – reaching a projected value of more than £3.5 billion.

Over the long term, gas is well-positioned to play a vital and complementary role in the energy mix, supporting the integration of intermittent renewables like wind and solar, while bolstering energy resilience.

According to the IEA, natural gas was the fastest-growing fossil fuel in 2024, with demand rising by 2.7% to reach a new all-time high, up from 0.5% growth in 2023. Its flexibility and reliability make it a valuable asset for maintaining grid stability and ensuring supply continuity throughout the energy transition.

Distributed systems and modular electrification for efficiency gains

As AI and digital technologies mature, they are likely to accelerate the shift away from traditional, centralised energy systems. In the Surge scenario, for example, a modular energy infrastructure begins to displace large-scale, fossil-powered energy systems, unlocking new levels of efficiency, decentralisation and decarbonisation.

Electricity systems are expected to increasingly favour renewable sources backed by grid-scale battery storage, creating more resilient and adaptive energy networks.

All three Shell scenarios also feature a boost in the role of electrification driven by the 2050 goal of achieving net-zero emissions. In Archipelagos, electricity demand grows at more than five percentage points of final energy market share every 10 years while in Surge and Horizon, the increase is 10 percentage points. This is a significant increase from the historical trend of closer to two percentage points per decade.

Meanwhile, the rise of small modular nuclear reactors (SMRs) over the mid-term (2040s) could provide a key energy solution for high-demand users such as datacentres and, in time, marine vessels.

Generating nuclear energy has emerged as a key UK government spending priority in 2025. A consortium led by Rolls-Royce – a British engineering company – has secured state backing worth £2.5 billion to develop the nation’s first small modular nuclear reactors.

Likewise, large solar projects could be adopted at a national or regional level, with governments favouring locally sourced modular technologies to reduce their exposure to volatile global markets.

At the same time, industrial customers are seeking reliable, clean power solutions that strengthen their long-term resilience. These customers are looking for greater transparency in how renewable energy is sourced and certified – not only to meet decarbonisation targets, but also to reduce exposure to volatile global markets. Combined with the UK government’s investment in homegrown clean power, this trend is accelerating the development and delivery of integrated energy solutions that support sustainability, energy security, and economic growth.

Regardless of the scenario, the move towards modularity will be driven by AI – whether that is in the form of enhanced manufacturing processes or the optimisation of interlinked, decentralised energy systems spread across different regions and geographies.

AI and digitalisation to control energy costs

Shell’s analysis suggests that by 2050, global energy demand could be 25% higher than in 2024, while CO₂ emissions are expected to peak within a decade. Then there are new technologies like AI, which may drive further demand – but are also expected to play a key role in cutting emissions.

The adoption of AI and smart automation emerges in all three Shell scenarios as a potential lever for industrial leaders looking to reduce energy costs and improve operational efficiency. AI is expected to optimise manufacturing lines, forecast energy demand with greater precision and automate load shifting – improving overall system flexibility, increasing efficiencies and reducing waste.

In the Surge scenario, these capabilities go a step further. AI doesn’t just optimise processes – it restructures how power is dispatched across industrial systems, making sure energy-intensive facilities are run as cost-effectively and efficiently as possible. Meanwhile, in the Horizon scenario, where carbon pricing and emissions targets are more stringent, efficiency becomes especially valuable. This, in turn, prompts some industrial players to consider retrofitting operations and investing in low-energy systems to stay competitive and compliant.

This change has already started. For example, Horizon Europe, a European Commission funding programme for research and innovation in support of the UN’s Sustainable Development Goals, created an investment framework worth €95 billion, which is already advancing digital innovation in energy.

In the UK, companies finding ways to use cutting-edge AI to reduce emissions have received support from government programmes, including a fund worth £1.7 million announced in mid-2024. These AI companies are working on innovative projects ranging from weather forecasting (for solar power generation) to software that improves energy efficiency.

Battery storage and on-site renewables for resilience and cost savings

The energy system could be at a turning point for renewables. Across all three scenarios, renewable energy plays a pivotal role, with the accelerated production of renewable energy modules making on-site generation more accessible and cost-effective for businesses.

Investing in on-site renewables, especially when paired with battery storage, may give businesses more autonomy over their energy supply. This not only could help support greater resilience to fluctuations in supply and pricing – a valuable benefit in the more geopolitically complex Archipelagos scenario – but can also help businesses to align with evolving regulatory expectations and net-zero goals.

Under the Shell Horizon scenario, continued investment in solutions such as hydrogen and battery storage may be on the rise not just for compliance with future regulation, but for maintaining competitiveness in a carbon-focused global economy.

The UK government has committed nearly a billion pounds (from 2023 to 2028) for its Green Industries Growth Accelerator. It’s also announced a reform of the country’s electricity grid, hoping to boost energy security, increase capacity and drive exports.

Unlocking a more sustainable energy future

Across all three of The 2025 Energy Security Scenarios, one theme is clear: the energy landscape of tomorrow is likely to look different from the one we know today. Whether dominated by the rapid integration of AI, geopolitical fragmentation or regulatory reform, these futures each represent a set of opportunities and challenges for business leaders across sectors in Europe and the world.

Exploring what the Surge, Archipelagos and Horizon scenarios could mean for UK businesses in the industrials sector may be a helpful way to consider options and build the future energy system.

Business leaders in the UK might not be searching for life on distant moons, but they are exploring the systems that will power life on Earth for decades to come. Just as the European Space Agency has done with its Jupiter Icy Moons Explorer (Juice) mission, decision makers across the region may benefit from recognising the value of long-term thinking in shaping an energy scenario in which they continue to succeed.