Amidst escalating global energy demands and pressing environmental concerns, unlocking the potential of non-petroleum-based carbon sources, including coal, natural gas, and biomass, is imperative. Catalyzing C1 molecules‒methane, carbon monoxide, methanol, and carbon dioxide‒derived from these non-petroleum carbon sources into high-value green chemicals and synfuels, holds significant promise for reshaping our approach to sustainable energy and environmental management. However, the traditional conversion of C1 molecules has long been plagued by challenges such as low efficiency, poor selectivity, and limited control over reaction pathways. These issues have become obstacles hindering the progress of sustainable energy and environmental development. The urgency to address these challenges is further heightened by the climate crisis, compelling a paradigm shift in our energy utilization practices.
The efficient activation of C-O and C-H bonds, along with the controllable C-C coupling in C1 chemistry, plays a pivotal role in producing high-value green chemicals and synfuels. Existing methods often struggle to precisely control catalytic activity and product selectivity, resulting in energy losses and undesired by-products. Moreover, elucidating the complex multi-phase and multi-scale reaction mechanisms, the activation mechanisms of C1 molecules, and the regulatory rules in catalytic processes remain a persistent challenge. To address the urgent need for efficient and clean energy utilization amid the climate crisis, we are pleased to introduce a focused research topic, "C1 Chemistry for Sustainable Energy and Environment," in Frontiers in Catalysis. This topic provides researchers with an opportunity to share their perspectives and latest research advancements in the field of C1 chemistry, especially in the pursuit of carbon neutrality and a sustainable future. Delving into the intricacies of catalytic processes, unlocking new mechanisms for efficient activation of C-O and C-H bonds, achieving controllable C-C coupling, and designing innovative catalysts, will significantly contribute to overcoming existing obstacles and drive the development of more sustainable and environmentally friendly energy solutions.
This research topic aims to inspire researchers across diverse fields to explore groundbreaking advancements. We encourage submissions covering, but not limited to, the following areas:
1. Sustainable conversion of C1 molecules through photonic, electronic, and thermal methods into chemicals and synfuels
2. Innovative catalyst design and novel reaction pathways
3. Novel reactor design for improving catalytic efficiency
4. Advanced characterization techniques for resolving catalyst structures and monitoring reaction intermediates
5. Integration with carbon neutrality goals
Authors are invited to submit comprehensive reviews and original research articles. Accepted submissions include Original Research, Reviews, Perspective, Mini Review, and Research Articles. This Research Topic is expected to have a broad impact, appealing to diverse readership in chemistry, material science, environment, and engineering. Your contributions are pivotal in advancing our understanding of catalytic processes for sustainable energy and environmental solutions.
Keywords:
C1 Molecules, Energy, Catalysis, Sustainable Energy
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.
Amidst escalating global energy demands and pressing environmental concerns, unlocking the potential of non-petroleum-based carbon sources, including coal, natural gas, and biomass, is imperative. Catalyzing C1 molecules‒methane, carbon monoxide, methanol, and carbon dioxide‒derived from these non-petroleum carbon sources into high-value green chemicals and synfuels, holds significant promise for reshaping our approach to sustainable energy and environmental management. However, the traditional conversion of C1 molecules has long been plagued by challenges such as low efficiency, poor selectivity, and limited control over reaction pathways. These issues have become obstacles hindering the progress of sustainable energy and environmental development. The urgency to address these challenges is further heightened by the climate crisis, compelling a paradigm shift in our energy utilization practices.
The efficient activation of C-O and C-H bonds, along with the controllable C-C coupling in C1 chemistry, plays a pivotal role in producing high-value green chemicals and synfuels. Existing methods often struggle to precisely control catalytic activity and product selectivity, resulting in energy losses and undesired by-products. Moreover, elucidating the complex multi-phase and multi-scale reaction mechanisms, the activation mechanisms of C1 molecules, and the regulatory rules in catalytic processes remain a persistent challenge. To address the urgent need for efficient and clean energy utilization amid the climate crisis, we are pleased to introduce a focused research topic, "C1 Chemistry for Sustainable Energy and Environment," in Frontiers in Catalysis. This topic provides researchers with an opportunity to share their perspectives and latest research advancements in the field of C1 chemistry, especially in the pursuit of carbon neutrality and a sustainable future. Delving into the intricacies of catalytic processes, unlocking new mechanisms for efficient activation of C-O and C-H bonds, achieving controllable C-C coupling, and designing innovative catalysts, will significantly contribute to overcoming existing obstacles and drive the development of more sustainable and environmentally friendly energy solutions.
This research topic aims to inspire researchers across diverse fields to explore groundbreaking advancements. We encourage submissions covering, but not limited to, the following areas:
1. Sustainable conversion of C1 molecules through photonic, electronic, and thermal methods into chemicals and synfuels
2. Innovative catalyst design and novel reaction pathways
3. Novel reactor design for improving catalytic efficiency
4. Advanced characterization techniques for resolving catalyst structures and monitoring reaction intermediates
5. Integration with carbon neutrality goals
Authors are invited to submit comprehensive reviews and original research articles. Accepted submissions include Original Research, Reviews, Perspective, Mini Review, and Research Articles. This Research Topic is expected to have a broad impact, appealing to diverse readership in chemistry, material science, environment, and engineering. Your contributions are pivotal in advancing our understanding of catalytic processes for sustainable energy and environmental solutions.
Keywords:
C1 Molecules, Energy, Catalysis, Sustainable Energy
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.