Boosting Potassium Storage Capacity Based on Stress‐Induced Size‐Dependent Solid‐Solution Behavior

A prerequisite for successful development of a K‐ion battery anode based on solid‐solution behavior is to improve its potassium storage capacity. Increasing the solid‐solution domain by decreasing the particle size offers a promising strategy for enhancing the potassium storage capabilities of inser...

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Bibliographic Details
Published in:Advanced energy materials 2018-11, Vol.8 (32), p.n/a
Main Authors: Xu, Shu‐Mao, Ding, Ying‐Chun, Liu, Xin, Zhang, Qiang, Wang, Kai‐Xue, Chen, Jie‐Sheng
Format: Article
Language:English
Subjects:
Anodes
Batteries
coherency strain
Dislocations
Electrode materials
improved capacities
Insertion
Intercalation
Intercalation compounds
Nanowires
Phase separation
Potassium
potassium‐ion batteries
size‐dependent
solid‐solution
Storage capacity
Strain
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Summary:A prerequisite for successful development of a K‐ion battery anode based on solid‐solution behavior is to improve its potassium storage capacity. Increasing the solid‐solution domain by decreasing the particle size offers a promising strategy for enhancing the potassium storage capabilities of insertion anode materials. Extended solid‐solution composition range in nanostructured particles is mainly due to the existence of a coherency strain that suppresses phase separation upon intercalation. Here, the intercalation stress effect in size‐dependent solid‐solution behavior is explored by insertion of K+ into K2Ti6O13 nanowires with different diameters. K2Ti6O13 nanowires with small average diameter of ≈5.5 nm deliver a large initial reversible depotassiated capacity of ≈120 mAh g−1 (deinsertion of ≈2.5 K+) at 0.2 C. The remarkably high reversible depotassiated capacity is mainly ascribed to the decrease of the incoherent interface upon potassiation. The direct observation of enrichment of intragranular particles in potassiated K2Ti6O13 nanowires with average diameter of ≈38 nm provides evidence of strain‐accommodating misfits or dislocations in solid‐solution intercalation compounds. This work offers a promising route to utilize coherency strain energy for K‐ion batteries with improved specific capacity and alleviated irreversible capacity loss. Reducing the size of insertion materials with enhanced solid‐solution domains offers a promising strategy to increase the potassium storage capabilities in K‐ion batteries. Maintaining a coherence interface within an individual particle upon (de)insertion of cations is favorable for the storage and utilization of coherency strain energy for solid‐solution intercalation compounds with improved rate and cyclic battery performance.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.201802175