A conducting
redox polymer based on PEDOT with hydroquinone and
pyridine pendant groups is reported and characterized as a proton
trap material. The proton trap functionality, where protons are transferred
from the hydroquinone to the pyridine sites, allows for utilization
of the inherently high redox potential of the hydroquinone pendant
group (3.3 V versus Li0/+) and sustains this reaction by
trapping the protons within the polymer, resulting in proton cycling
in an aprotic electrolyte. By disconnecting the cycling ion of the
anode from the cathode, the choice of anode and electrolyte can be
extensively varied and the proton trap copolymer can be used as cathode
material for all-organic or metal-organic batteries. In this study,
a stable and nonvolatile ionic liquid was introduced as electrolyte
media, leading to enhanced cycling stability of the proton trap compared
to cycling in acetonitrile, which is attributed to the decreased basicity
of the solvent. Various in situ methods allowed for in-depth characterization
of the polymer’s properties based on its electronic transitions
(UV–vis), temperature-dependent conductivity (bipotentiostatic
CV-measurements), and mass change (EQCM) during the redox cycle. Furthermore,
FTIR combined with quantum chemical calculations indicate that hydrogen
bonding interactions are present for all the hydroquinone and quinone
states, explaining the reversible behavior of the copolymer in aprotic
electrolytes, both in three-electrode setup and in battery devices.
These results demonstrate the proton trap concept as an interesting
strategy for high potential organic energy storage materials.
An organic cathode material based on a copolymer of poly(3,4‐ethylenedioxythiophene) containing pyridine and hydroquinone functionalities is described as a proton trap technology. Utilizing the quinone to hydroquinone redox conversion, this technology leads to electrode materials compatible with lithium and sodium cycling chemistries. These materials have high inherent potentials that in combination with lithium give a reversible output voltage of above 3.5 V (vs Li0/+) without relying on lithiation of the material, something that is not showed for quinones previously. Key to success stems from coupling an intrapolymeric proton transfer, realized by an incorporated pyridine proton donor/acceptor functionality, with the hydroquinone redox reactions. Trapping of protons in the cathode material effectively decouples the quinone redox chemistry from the cycling chemistry of the anode, which makes the material insensitive to the nature of the electrolyte cation and hence compatible with several anode materials. Furthermore, the conducting polymer backbone allows assembly without any additives for electronic conductivity. The concept is demonstrated by electrochemical characterization in several electrolytes and finally by employing the proton trap material as the cathode in lithium and sodium batteries. These findings represent a new concept for enabling high potential organic materials for the next generation of energy storage systems.
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