Redox-coupled alkali-metal ion transport mechanism in binder-free films of Prussian blue nanoparticles

Prussian blue (PB), an archetypal classic porous coordination polymer, has been rediscovered as a potential electrode material for ion secondary batteries due to its accommodations for alkali-metal ions. Many researchers have investigated the charge/discharge capacities of PB and its analogue (PBA)...

Full description

Saved in:
Bibliographic Details
Published inJournal of materials chemistry. A, Materials for energy and sustainability Vol. 7; no. 9; pp. 4777 - 4787
Main Authors Ishizaki, Manabu, Ando, Hideo, Yamada, Noboru, Tsumoto, Kai, Ono, Kenta, Sutoh, Hikaru, Nakamura, Takashi, Nakao, Yoshihide, Kurihara, Masato
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 2019
Subjects
Alkali metals
Batteries
Binders
Chemical reduction
Computer applications
Coordination polymers
Electrochemistry
Electrochromism
Electrode materials
Electrodes
Ion transport
Ions
Lithium
Low temperature
Metal ions
Nanoparticles
Organic chemistry
Pigments
Pores
Potassium
Quantum chemistry
Redox reactions
Selectivity
Solvation
Storage batteries
Online AccessGet full text

Cover

More Information
Summary:Prussian blue (PB), an archetypal classic porous coordination polymer, has been rediscovered as a potential electrode material for ion secondary batteries due to its accommodations for alkali-metal ions. Many researchers have investigated the charge/discharge capacities of PB and its analogue (PBA) cells with binders. Binders, however, often obscure the underlying redox-coupled ion transport mechanism and the intrinsic transport pathways in PB and PBAs. Using binder-free PB film electrodes prepared by our low-temperature annealing method, we monitored the redox process accompanied by ion transport through simultaneous electrochemical and electrochromic measurements. We clarify that large pores of the defect lattice PB facilitate the efficient transport of bare and solvated Li + /K + , whereas small pores of the perfect lattice PB only allow bare Li + to be transported up to inner lattice layers. This highlights the importance of pore/ion size selectivity and the (de)solvation effect. Quantum chemical calculations of a perfect lattice model revealed the size-dependent transport pathways of bare Li + and K + , which microscopically corroborate the experimentally observed selectivity. In addition, spin density difference maps demonstrate that the Li + transport can be facilitated not only by the electrochemical reduction of all Fe III centres but also by Li + -induced local redox reactions of the lattice framework. Our combined experimental and theoretical studies provide a fundamental understanding of the concealed structure–property relationship in PB films, thereby contributing to a more systematic design of high-performance PB/PBA electrodes.
ISSN:2050-7488
2050-7496
DOI:10.1039/C8TA11776D