The global energy landscape is undergoing a significant transformation, with an increasing focus on sustainability and a drive to transition away from fossil fuels. As we stand at the precipice of this energy transition, the choices we make today will shape the future of our planet. The opportunities for powering our world are expanding rapidly, with renewable energy sources such as solar and wind leading the way. Additionally, alternative sources like hydrogen and nuclear fission are showing great promise in the pursuit of a cleaner, more sustainable energy landscape.
This article explores the possibilities and challenges associated with the energy transition, taking a closer look at the innovations that are driving change and the obstacles that must be overcome.
The Current Energy Landscape
Adapted from International Energy Agency, Key World Energy Statistics 2021
According to statistics released by the International Energy Agency, 80.9% of global energy came from fossil fuels, 9.4% from biofuels and waste, 5.0% from nuclear energy, 2.5% from hydro energy, and the remaining 2.2% from other sources in 2019.
Today’s energy landscape is largely characterised by its over-reliance on fossil fuels which have detrimental impacts on the environment. Alternative sources of cleaner energy such as solar, wind and hydrogen are being increasingly adopted. Yet, the extent of technological advancement needed to effectively facilitate the energy transition is still nowhere in sight.
The combustion of fossil fuels such as coal, oil and natural gas causes large amounts of greenhouse gases to be released into the atmosphere, trapping heat and causing global temperatures to rise. This leads to climate change, resulting in rising sea levels, unpredictable precipitation problems and extreme weather events.
The combustion of fossil fuels also releases a variety of pollutants into the atmosphere including sulphur dioxide and nitrogen oxides. These gases contribute to smog and can cause respiratory problems. They can also react with rain water to form acid rain, which can corrode buildings, destroy marine life and damage ecosystems.
The Russia-Ukraine war has worsened the global energy crisis. Due to supply-chain disruptions from one of the world’s major oil suppliers, Russia, this has in turn driven up energy prices. This increases the number of households unable to afford energy - especially those in developing countries.
Furthermore, due to political tensions, Russia has cut gas flows to the EU by 80% between May and October 2022. This has caused a significant shortage in the EU’s energy mix. This highlights the over-reliance on major fuel-exporting countries, making the diversification towards alternative or domestic sources of energy a pressing need.
The main reason why sustainable energy sources still remain relatively more expensive today, is the sheer cost of infrastructure required to build solar farms and wind farms. When produced on a large-scale, these costs can add up quickly. This makes sustainable energy sources more expensive than traditional ones.
As a result it poses a significant barrier to the large-scale adoption of sustainable energy sources, as many countries and businesses tend to prioritise cost savings at the expense of the environment.
Hydrogen Fuel is produced by chemically reacting hydrogen gas with oxygen to create water. This process releases energy that can be harnessed to power fuel cells and generate electricity directly.
Advantages:
It produces no harmful emissions when burned. In fact, the only byproduct of hydrogen fuel is water vapour, making it an extremely clean source of energy.
Hydrogen fuel can be produced from a variety of sources, including water, natural gas, and biomass, making it a versatile and sustainable fuel option.
Gaps:
Difficulty in storage and transport; requires specialised equipment and infrastructure to handle safely.
The production of hydrogen fuel can be energy-intensive, which can limit its overall sustainability.
Nuclear fission is a process in which the nucleus of an atom is split into two or more smaller nuclei, releasing a large amount of energy in the form of heat and radiation. This process is the basis of nuclear power plants, which use the heat generated by nuclear fission to produce steam, which in turn drives turbines to generate electricity.
Advantages:
Clean source of energy that does not generate greenhouse gases such as carbon dioxide.
It also reduces our dependency on fossil fuels, which are a finite resource that exacerbate climate change.
Gaps:
Nuclear energy produces radioactive waste, which must be carefully stored and disposed of.
Safety concerns associated with nuclear power plants, particularly in the event of a nuclear accident, which can release dangerous levels of radiation.
Geothermal energy is a renewable source of energy. It comes from the heat that is naturally generated within the Earth's core. This heat energy can be harnessed and used for various purposes such as generating electricity, heating buildings, and providing hot water.
Geothermal energy is typically harnessed by drilling deep wells into the ground to access the hot water and steam that is naturally present in the Earth's crust. The hot water or steam is then used to power turbines and generate electricity, or it can be directly used for heating or cooling buildings.
Advantages:
Geothermal energy is a clean and sustainable source of energy that has a much smaller environmental footprint than fossil fuels.
Gaps:
It is not widely available in all areas and can be expensive to develop in some locations.
Energy storage is the capture of energy produced at one time for use at a later time. The aim is to reduce imbalances between energy demand and energy production. Recently, there have been innovative solutions on battery recycling, driving a more sustainable energy landscape.
For example, NEU Battery Materials, a startup from the HyperScale accelerator programme created a way to recycle lithium batteries using a clean and sustainable electrochemical and produce battery grade materials. This solution addresses the sustainable redox targeting battery recycling issue.
A microgrid is a small-scale electrical grid that can operate independently or in conjunction with the main power grid. It typically includes distributed energy resources such as solar panels, wind turbines, battery storage, and backup generators, which can generate and store electricity locally.
Microgrids are designed to provide reliable and resilient power to specific communities, facilities, or regions. They are often used in areas that are prone to power outages or that are far from the main power grid, such as remote communities, military bases, or hospitals.
There are several challenges in the large-scale adoption of alternative energy. The alternative energy must be cheap, abundant, clean, safe, easy to transport, and sustainable. To build energy resilience and reduce the geopolitical risk of energy insecurity, each country should self-sustain and bring the supply chain to their own backyards.
Today, our predominant energy system is centred around natural gas. In the future, however, multiple systems of energy storage and distribution are foreseen. This includes electricity imports, hydrogen networks, combustion technology and infrastructure, etc.
With the proliferation of alternative energy such as solar, thermal and nuclear, there is an increasing need to design an integrated system that is robust, resilient and reliable - perhaps one that is co-reliant.
Accelerator programmes drive innovation and expedite the transition of the current energy landscape into a more sustainable one. Startups benefit from active guidance from industry professionals, access to resources, connections with investors, collaborations, and a structured framework for innovation.
With potential funding, startups with innovative solutions tackling real-world problems are empowered to conduct further research and development, and upscale their ideas to revolutionise the energy landscape.
One of the initiatives driving innovation within the energy space is the PETRONAS FutureTech 3.0. The programme focuses on 5 verticals - Future of Energy and Mobility, Sustainability, Future of Industry and Work, Future of Chemicals and Material, and Frontier Technology.
More information can be found here: https://petronasft.thestartupx.com.
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