This content appears to be a collection of scientific papers and articles related to bioelectrocatalysis, specifically focusing on the development of hybrid bilayer membranes (HBMs) for the production of chemicals, fuels, and materials. The authors are exploring novel approaches to enhance the efficiency and selectivity of HBMs by controlling proton transfer, electron transfer, and molecular recognition. The papers discussed include:
1. Bioelectrocatalytic oxygen reduction using metal complexes embedded in HBMs
2. Controlling proton transfer in HBMs for oxygen reduction
3. Designing alkyl-nitrile for proton transfer enhancement
4. Electrocatalytic CO2 reduction using HBMs
5. Proton-coupled electron transfer in HBMs
6. Materials science and chemistry for energy storage and conversion
7. Supramolecular electrode assemblies for bioelectrochemistry
8. Bioprotonic devices and sensing applications
9. Membrane restructuring by enzymes and lipid domains
10. Atomic force microscopy for studying supported lipid films
The studies aim to improve the performance of HBMs by:
* Engineered proton transfer pathways
* Fine-tuning surface properties
* Incorporating specific enzymes or molecules
* Controlling lipid composition
* Designing novel catalysts and substrates
* Enhancing mass transport
The research highlights the potential of HBMs in various applications, including:
* Production of chemicals, fuels, and materials
* Bioelectrochemical energy conversion and storage
* Bioprotonic devices and sensing
* Biotechnological applications
Overall, the papers demonstrate the possibility of developing advanced HBMs with tailored properties for specific applications, highlighting the importance of understanding membrane structure, dynamics, and function in bioelectrocatalysis.