In his article, BODEL emphasizes that the current scalable low -carbon energy solution, which can be used in the UK, is wind, solar, and nuclear technology. However, flexible backup is essential to ensure energy security and grid stability. This can compensate for fluctuations in renewable energy production.
Nuclear power plants are very efficient and generate minimal carbon emissions, but Dr. Border emphasizes that its economic feasibility is completely operated in 24 hours. I am doing it. Maintaining idle status when demand is low is not financially executable.
To deal with this issue, he proposes a dynamic solution to integrate hydrogen production with nuclear energy and meet both electricity and hydrogen demand.
Bridge the energy gap with hydrogen production
Dr. Boder explains that the renewable source of wind and sunlight is intermittent. When the wind is slow or the sun sinks, the amount of power will fall.
In order to maintain stable power supply, an alternative energy source needs to intervene. Traditionally, gas combustion power plants helped this role, but contributed to carbon emissions and compete with the goals of internet zero energy.
In his analysis, Dr. Bodel claims that advanced nuclear technology offers promising solutions. If the demand for grids is low, the power plant can continue to work with an unnecessary ability by bypassing excessive nuclear energy toward hydrogen production.
When the regenerated output fluctuates, nuclear power can return to power and ensure grid stability. This strategic approach enables seamless energy migration and optimizes both renewable and nuclear power.
High -temperature electrolytic: Lock unlocking highly cost -effective hydrogen
Dr. BODEL emphasizes that one of the most efficient ways to generate hydrogen is high -temperature electrolytic and needs significant heat input.
Advanced nuclear reactors provide both hot and electricity and electricity required for this process and become an ideal partner for hydrogen production.
Unlike conventional electrolysis methods, high -temperature electrolytes are more efficient, reducing energy consumption and production costs.
According to Dr. Bodel, by using the reactor to generate both electricity and heat, hydrogen is produced at competitive costs and strengthened economic cases of nuclear energy.
Maximize regenerative possibilities with nuclear technology
Dr. Bodel’s research at the Dalton Nuclear Research Institute indicates how the integration of nuclear technology and hydrogen production provides multiple advantages.
First, it eliminates dependence on fossil fuel -based backup power and greatly reduces greenhouse gas emissions. Second, prevent reductions enabling better use of renewable energy.
By enabling nuclear power plants to switch electricity and hydrogen production based on demand, both energy sources may work at peak efficiency.
This approach minimizes the need for expensive backup infrastructure and energy storage solutions, which will reduce costs for both energy providers and consumers.
Need for government support
To make this vision a reality, Dr. Bodel emphasizes that government support and strategic investment in advanced reactors are very important.
Building a large -scale high -temperature reactor guarantees a reliable and expensive hydrogen supply, and at the same time enhanced British energy security.
Policy proprieters must recognize the wider advantage of nuclear technology as a balanced force that supports not only power generation but also the entire low -carbon ecosystem.
Dr. Bodel advocates to accelerate advanced reactors. This is because it is the key to achieving net zero emissions while maintaining a stable and resilient energy grid.
His research emphasizes the possibility of transforming nuclear technology with hydrogen production and integration.
By utilizing high -temperature reaction devices for both the generation of electricity and hydrogen, the UK can ensure energy security, reduce carbon emissions, and maximize the possibilities of renewable resources.
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