Carbon Neutralization 

About: Carbon Neutralization is an academic journal. The journal publishes majorly in the area(s): Chemistry & Engineering. It has an ISSN identifier of 2769-3325. Over the lifetime, 62 publications have been published receiving 130 citations. The journal is also known as: Carbon Neutralization.

Anion exchange membrane water electrolysis for sustainable large‐scale hydrogen production

Abstract: The development of sustainable energy technology has received considerable attention to meet the increasing energy demands and realize carbon neutrality. Hydrogen is a promising alternative energy source to replace fossil fuels and mitigate environmental issues. However, most hydrogen is produced by reforming fossil fuels, called gray hydrogen, and the production of gray hydrogen emits a large amount of carbon dioxide. As a sustainable approach, water electrolysis technology has been developed to produce high-purity hydrogen, called green hydrogen. Among various technologies, water electrolysis equipped with an anion exchange membrane has been regarded as an attractive pathway for large-scale H2 production at a low cost. The status of anion exchange membrane water electrolyzers is approaching toward megawatt-scale H2 production by companies, which has the potential to become competitive technology for existing water electrolyzers (alkaline electrolyzer, proton exchange membrane electrolyser). This review article represents recent advances in the development of major components (membrane, catalyst, membrane electrode assembly) of anion exchange water electrolyzers. By recognizing the current water electrolysis performance and solving the remaining challenges, anion exchange membrane electrolysis can be a leading technology for green hydrogen production.

Structural degradation mechanisms and modulation technologies of layered oxide cathodes for sodium‐ion batteries

Abstract: Renewable energies, such as solar and wind, have been explored and widely applied for alleviating problems associated with the depletion of fossil fuel resources and environmental pollution. The intermittent and fluctuating features of these renewable energies require development of efficient energy storage and conversion systems. Sodium-ion batteries (SIBs) are considered one of the most promising candidates for large-scale energy storage due to the low cost and earth abundance of sodium resources. A major challenge for the practical application of SIBs is the development of appropriate cathodes with high energy densities and cycling stabilities. Layered oxide cathodes have received significant attention because of their relatively simple synthetic routes and high capacities stemming from their layered structures. However, they often suffer from moisture sensitivity and structural degradation upon repeated Na+ insertion/extraction, leading to severe performance fading. This review summarizes and discusses the degradation mechanisms of these layered oxide cathodes and modulation strategies for addressing the stability issues. Understanding the mechanisms behind structural instability would provide better insight for improving SIBs' cathode materials, which has critical implications for the designs and applications of SIBs as renewable energy systems.

Application of cellulose‐based hydrogel electrolytes in flexible batteries

Abstract: Flexible energy storage devices have the advantages of portability and safety, and have great potential for developing electronic materials in the future. In flexible batteries, the electrolyte presents an essential role in the electrochemical performance and safety of the batteries. Hydrogel electrolyte materials are considered to be one of the ideal electrolyte materials due to their environmental friendliness, high safety, maneuverability, and innocuity. However, ordinary hydrogels often suffer some defects, such as insufficient ductility and poor water retention. Currently, many researchers report cellulose materials as reinforcing agents to improve the performance of hydrogels. In this paper, we review the recent application of cellulose in hydrogel-based materials for energy storage technology and summarize the functions and properties of cellulose. In addition, we analyze the shortcomings of cellulose used in hydrogels and briefly describe the prospects of cellulose materials, hoping to contribute to the research in this field.

Theoretical calculation guided materials design and capture mechanism for Zn–Se batteries via heteroatom‐doped carbon

Abstract: Zinc–selenium (Zn–Se) batteries have generated great research interest because they could potentially meet the requirements of a high-capacity, high energy density storage device. Unfortunately, efforts to control the shuttle effect of polyselenides have yielded limited success. Nanostructured carbon hosts with nonpolar surfaces have insufficient ability to restrict polyselenides within the cathode. Herein, first-principles calculations are used to successfully study the merits of heteroatom-doped graphene as an efficient sorbent with an excellent ability to inhibit the shuttle effect of polyselenides. The calculation results show that using B as a dopant could distinctly enhance interaction between hosts and polyselenides, which occur significant charge transfer with polyselenides and reduce the diffusion energy barrier of Zn ions. Then, we synthesized carbon/Se and boron-doped carbon material/Se composite cathodes proving that B-doped carbon could restrict the shuttle effect of polyselenides, which increases the electrochemical performance of Zn–Se batteries. Therefore, the theoretical study identifies a delightful restricted material that could potentially restrict the shuttle effect in Zn–Se batteries and provides a foundation and strategy for the fabrication of long-life, high-power-density Zn–Se batteries.