About this Research Topic
This Research Topic focuses on the recent advancements in process engineering, reactor design, and catalyst development that are key to accelerating the global energy transition. With an emphasis on innovative research and practical applications, this edition seeks to showcase studies that contribute to more efficient, sustainable, and cost-effective energy systems. It aims to bridge the gap between fundamental chemical engineering principles and their application in addressing the world's pressing energy challenges.
Contributors are invited to present their latest findings, methodologies, and reviews in areas such as renewable energy processes, emission reduction technologies, and advanced materials for energy storage and conversion. By bringing together a diverse group of specialists, this special issue aims to facilitate a multidisciplinary dialogue and expand the frontiers of chemical engineering.
The primary goal of this Research Topic is to address the critical challenges in the chemical engineering field related to the global energy transition. As the world moves towards more sustainable and renewable energy sources, there is a significant need for advancements in chemical processes, reactor designs, and catalyst efficiencies. This transition involves replacing fossil fuels and also encompasses improving the energy efficiency and environmental impact of existing and emerging technologies.
To achieve this, the Research Topic invites research that demonstrates novel approaches and technological innovations in process engineering, reactor configuration, and catalyst formulation.
Contributions may include, but are not limited to, the development of new materials for energy storage and conversion including hydrogen and its chemical carriers, breakthroughs in carbon capture and utilization, strategies for waste-to-energy processes, and enhancements in the scalability and sustainability of bioenergy production.
Recent advances in computational methods, process simulation, and analytical techniques that lead to better process understanding and optimization are particularly welcomed. By consolidating these research efforts, this Research Topic aims to provide a comprehensive platform for disseminating pioneering solutions that could significantly contribute to accelerating the energy transition.
We welcome the submission of Original Research, Review, Mini Review, and Perspective articles on themes including, but not limited to:
• Innovative process engineering;
• Reactor design and optimization;
• Catalyst development;
• Environmental impact reduction;
• Energy storage and conversion;
• Process simulation and optimization.
Submissions should provide significant insights into the challenges and solutions related to the energy transition within the context of chemical engineering. Authors are encouraged to discuss the practical implications of their research, potential applications, and future directions in the field.
Contributors are invited to present their latest findings, methodologies, and reviews in areas such as renewable energy processes, emission reduction technologies, and advanced materials for energy storage and conversion. By bringing together a diverse group of specialists, this special issue aims to facilitate a multidisciplinary dialogue and expand the frontiers of chemical engineering.
The primary goal of this Research Topic is to address the critical challenges in the chemical engineering field related to the global energy transition. As the world moves towards more sustainable and renewable energy sources, there is a significant need for advancements in chemical processes, reactor designs, and catalyst efficiencies. This transition involves replacing fossil fuels and also encompasses improving the energy efficiency and environmental impact of existing and emerging technologies.
To achieve this, the Research Topic invites research that demonstrates novel approaches and technological innovations in process engineering, reactor configuration, and catalyst formulation.
Contributions may include, but are not limited to, the development of new materials for energy storage and conversion including hydrogen and its chemical carriers, breakthroughs in carbon capture and utilization, strategies for waste-to-energy processes, and enhancements in the scalability and sustainability of bioenergy production.
Recent advances in computational methods, process simulation, and analytical techniques that lead to better process understanding and optimization are particularly welcomed. By consolidating these research efforts, this Research Topic aims to provide a comprehensive platform for disseminating pioneering solutions that could significantly contribute to accelerating the energy transition.
We welcome the submission of Original Research, Review, Mini Review, and Perspective articles on themes including, but not limited to:
• Innovative process engineering;
• Reactor design and optimization;
• Catalyst development;
• Environmental impact reduction;
• Energy storage and conversion;
• Process simulation and optimization.
Submissions should provide significant insights into the challenges and solutions related to the energy transition within the context of chemical engineering. Authors are encouraged to discuss the practical implications of their research, potential applications, and future directions in the field.
Keywords: Sustainable energy processes; Advanced reactor design; Catalytic innovation; Energy efficiency optimization; Carbon capture and utilization
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
