Water splitting and artificial photosynthesis aim to convert renewable energy into chemical energy by producing hydrogen or carbon-based fuels. Water splitting uses electrical or solar energy to separate water into hydrogen and oxygen, with hydrogen serving as a clean energy carrier. Artificial photosynthesis mimics natural processes by using sunlight, catalysts, and semiconductors to drive chemical reactions. These technologies enable long-term energy storage and support decarbonization of power, transport, and industry. Research focuses on improving catalyst efficiency, durability, and scalability. Water splitting and artificial photosynthesis play a key role in green hydrogen production and carbon-neutral fuel pathways, supporting the transition to sustainable and low-carbon energy systems.
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