Aqueous
zinc-organic batteries, featuring safe aqueous electrolytes
and cost-effective materials, demonstrate broad application prospects.
However, small-molecule organic cathodes encounter critical challenges,
including poor electronic conductivity and severe dissolution issues.
Herein, a small-molecule quinone guest (sodium anthraquinone-2-sulfonaterationate,
SAS) is incorporated with a conductive host (reduced graphene oxide,
rGO) through noncovalent bonding to obtain a free-standing SAS@rGO
electrode. Theoretical calculations and experimental characterizations
indicate host–guest interactions prevent the dissolution of
active material and facilitate electron transport. Furthermore, various
in/ex situ characterizations reveal that SAS@rGO remains stable during
cycling, maintaining a high capacity retention of 90.4% after 300
cycles even at 0.5 C. Moreover, 1,4-butyrolactone is adopted as cosolvent
to break the hydrogen bonding network, ensuring rapid ion transport
kinetics at low temperatures. Combining the principles of host–guest
and solvation chemistry synergistically, the Zn//SAS@rGO battery achieves
exceptional cycling stability for over 3000 cycles at 1 A g–1 and −40 °C.