| Track 1:Thermal Processes and Energy Systems Engineering |
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Heat transfer and fluid flow in energy systems
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Thermal system design, optimization, and control
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Energy efficiency improvement and thermal management
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Multi-energy systems (e.g., hybrid renewable, combined heat and power)
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Engineering applications of low-carbon energy in industry and buildings
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| Track 2:Electrochemical Energy Conversion and Hydrogen Production |
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Water electrolysis technologies (PEM, AEM, SOEC): system design, stack performance, and thermal/water management
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Electrochemical system durability, degradation mechanisms, and accelerated testing
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Hydrogen production scale-up: from laboratory cells to industrial stacks
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Engineering-oriented electrocatalyst and electrode integration (with a focus on performance under operating conditions, rather than purely material synthesis)
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| Track 3:Fuel Cells and Power Systems |
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Fuel cell materials, stack design, and manufacturing
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System-level performance, control strategies, and diagnostics
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Fuel cell hybrid systems (e.g., battery–fuel cell combinations)
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Applications in transportation (automotive, rail, marine) and stationary power generation
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| Track 4:Advanced Combustion and Low-Carbon Fuels |
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Hydrogen and hydrogen-blend combustion technologies (engines, gas turbines, burners)
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Alternative fuels (ammonia, synthetic fuels, biofuels): combustion mechanisms and emissions
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High-temperature energy systems and materials
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Emission control, pollutant formation, and safety in hydrogen/flexible-fuel combustion
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| Track 5:Energy Storage and Infrastructure |
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Hydrogen storage technologies (compressed, liquid, material-based)
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Energy storage systems integration with renewable sources
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Hydrogen transport, refueling stations, and infrastructure design
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Techno-economic analysis and optimization of hydrogen supply chains
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