posted on 2023-08-24, 18:33authored byLeilei Li, Hai Ming, Junli Zhang, Hao Zhang, Yuehua Wen, Yusheng Yang
The poly(2,5-dihydroxy-1,4-benzoquinone-3,6-methylene)
(denoted
as PDBM) capable of reversible coordination/uncoordination with both
mono- and multivalent cations in aqueous electrolytes is desired to
develop safe, sustainable, and cost-effective aqueous rechargeable
batteries (ARBs). However, the comprehensive mechanism between the
electrochemical performance of PDBM and properties of these metal
cations is unclear. Herein, we initially demonstrate the universality
of PDBM to reversibly coordinate/uncoordinate with various cations
(Na+, Mg2+, Ca2+, Zn2+, Al3+, etc.) with high specific capacities
(>200 mA h g–1), high rate capabilities (∼20
C), and long cycling life (5000 cycles). Additionally, an unprecedented
ion-coordination mechanism is presented: the monovalent cations prefer
to occupy the in-plane sites with respect to the benzene rings of
PDBM during the electrochemical reduced process, while the multivalent
cations with the larger charge density tend to occupy the out-of-plane
sites, which can use more active sites in the PDBM molecule and deliver
the higher specific capacities. Meanwhile, the redox potential of
PDBM decreases with the decrease in the binding energy between metal
cations and PDBM molecules. The universality of PDBM to numerous cations
is beneficial to design high-safety, low-cost, and long-lifespan ARBs
for large-scale energy storage systems by modulating the aqueous electrolytes.