Ferrocenyl-dithiolane integrated Cu(I) Coordination Polymers: Framework Engineering for Synergistic Redox Activity towards Supercapattery Applications

Abstract

This work presents the rational design of ferrocene-integrated Cu(I) coordination polymers (CPs) that harness the synergistic redox activity of Fe(II) and Cu(I) centers for high-performance energy storage. Two new CPs, Fc-Cu1 and Fc-Cu2, were obtained by self-assembly of CuI with (2-methyl-1,3-dithiolan-2-yl)ferrocene and 1,1′-bis(2-methyl-1,3-dithiolan-2-yl)ferrocene, respectively. Both CPs consist of a similar [{Cu₂(μ₄-I)(μ₂-I)}]_n array where ferrocene ligands coordinate via sulfur atoms, leading to a one-dimensional polymeric structure for Fc-Cu1 and a layered 2D architecture for Fc-Cu2. The 2D architecture of Fc-Cu2 improves electrical conductivity, charge transport, and ion diffusion compared to its 1D counterpart, resulting in a higher diffusion-controlled charge storage capacity of 450 C·g^-1 at 1 A·g^-1. A symmetric supercapattery device assembled using Fc-Cu2 electrodes delivers a maximum energy density of 29 Wh·kg-1 at a power density of 9.9 kW·kg^-1 and retains 85% of its initial capacity over 10,000 cycles, demonstrating excellent cycling stability. This study underscores the significance of combining multiple redox-active centers with controlled framework dimensionality in the development of next-generation CP/MOF-based energy storage systems.