In this work, the Li-ion insertion mechanism in organic electrode materials is investigated through the lens of atomic-scale models based on first-principles theory. Starting with a structural analysis, the interplay of density functional theory with evolutionary and potential-mapping algorithms is used to resolve the crystal structure of the different (de)lithiated phases. These methods elucidate different lithiation reaction pathways and help to explore the formation of metastable phases and predict one- or multi-electron reactions, which are still poorly understood for organic intercalation electrodes. The cathode material dilithium 2,5-oxyterephthalate (operating at 2.6 V vs. Li/Li+) is investigated in depth as a case study, owing to it...
AbstractRechargeable lithium batteries have achieved a rapid advancement and commercialization in th...
Organic electrode materials offer obvious opportunities to promote cost-effective and environmentall...
Rechargeable Li batteries consist of an anode, electrolyte, and cathode. The cathode is typically an...
In this work, the Li-ion insertion mechanism in organic electrode materials is investigated through ...
Organic electroactive materials are promising candidates to be used as lithium insertion electrodes ...
The superlithiation of organic anodes is a promising approach for developing the next generation of ...
The intense increase in energy consumption around the world has prompted a great deal of research on...
Renewable energy sources are generally abundant but intermittent, with peak production and peak dema...
This work is pioneering to introduce molecular electrostatic potential (MESP) to investigate the int...
Several forms of organic materials have arisen as promising candidates for future active electrode m...
This research analyzes the possibility of using lithiated benzenedipropiolate, an organic material, ...
In this communication, we use first-principles based multi-level computational methods to predict th...
AbstractRechargeable lithium batteries have achieved a rapid advancement and commercialization in th...
Organic electrode materials offer obvious opportunities to promote cost-effective and environmentall...
Rechargeable Li batteries consist of an anode, electrolyte, and cathode. The cathode is typically an...
In this work, the Li-ion insertion mechanism in organic electrode materials is investigated through ...
Organic electroactive materials are promising candidates to be used as lithium insertion electrodes ...
The superlithiation of organic anodes is a promising approach for developing the next generation of ...
The intense increase in energy consumption around the world has prompted a great deal of research on...
Renewable energy sources are generally abundant but intermittent, with peak production and peak dema...
This work is pioneering to introduce molecular electrostatic potential (MESP) to investigate the int...
Several forms of organic materials have arisen as promising candidates for future active electrode m...
This research analyzes the possibility of using lithiated benzenedipropiolate, an organic material, ...
In this communication, we use first-principles based multi-level computational methods to predict th...
AbstractRechargeable lithium batteries have achieved a rapid advancement and commercialization in th...
Organic electrode materials offer obvious opportunities to promote cost-effective and environmentall...
Rechargeable Li batteries consist of an anode, electrolyte, and cathode. The cathode is typically an...