Stoichiometric Layered Potassium Transition Metal Oxide for Rechargeable Potassium BatteriesStoichiometric Layered Potassium Transition Metal Oxide for Rechargeable Potassium Batteries
| Date Published |
08/2018
|
|---|---|
| Publication Type | Journal Article
|
| Authors | |
|---|---|
| DOI |
10.1021/acs.chemmater.8b03228
|
| Abstract |
K-ion batteries are promising alternative energy storage systems for large-scale applications because of the globally abundant K reserves. K-ion batteries benefit from the lower standard redox potential of K/K+ than that of Na/Na+ and even Li/Li+, which can translate into a higher working voltage. Stable KC8 can also be formed via K intercalation into a graphite anode, which contrasts with the thermodynamically unfavorable Na intercalation into graphite, making graphite a readily available anode for K-ion battery technology. However, to construct practical rocking-chair K-ion batteries, an appropriate cathode material that can accommodate reversible K release and storage is still needed. We show that stoichiometric KCrO2 with a layered O3-type structure can function as a cathode for K-ion batteries and demonstrate a practical rocking-chair K-ion battery. In situ X-ray diffraction and electrochemical titration demonstrate that KxCrO2 is stable for a wide K content, allowing for topotactic K extraction and reinsertion. We further explain why stoichiometric KCrO2 is unique in forming the layered structure unlike other stoichiometric K-transition metal oxide compounds, which form nonlayered structures; this fundamental understanding provides insight for the future design of other layered cathodes for K-ion batteries. |
| Journal |
Chemistry of Materials
|
| Volume |
30
|
| Year of Publication |
2018
|
| Issue |
18
|
| Pagination |
6532 - 6539
|
| ISSN Number |
0897-4756
|
| URL | |
| Short Title |
Chem. Mater.
|
| Refereed Designation |
Refereed
|
| Organizations | |
| Research Areas | |
| Download citation | Google Scholar | DOI | BibTeX | Endnote tagged | RIS |