Interface-Engineered Nickel Foam Electrodes with Polydopamine and Ultraphene for High-Performance Nickel Iron Metal–Organic Framework Hybrid Energy Storage

Journal article

Authors/Editors

CHUTIMA KONGVARHODOM

Strategic Research Themes

Innovative Materials, Manufacturing and Construction (Strategic Research Themes)

Publication Details

Author list: Kuo, T.-R.; Chuang, B.-Y.; Kongvarhodom, C.; Yougbaré, S.; Saukani, M.; Chen, H.-M.; Lin, L.-Y.

Publisher: American Chemical Society

Publication year: 2025

Volume number: 8

Issue number: 24

Start page: 18146

End page: 18157

Number of pages: 12

ISSN: 25740962

eISSN: 2574-0962

URL: https://www.scopus.com/inward/record.uri?eid=2-s2.0-105025203000&doi=10.1021%2Facsaem.5c03022&partnerID=40&md5=aca6dbc1f0f9c0ab47025d10f416bdfd

Languages: English-Great Britain (EN-GB)

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Abstract

Nickel foam (NF) has been widely employed as a conductive scaffold for electrochemical energy storage, owing to its high electrical conductivity, mechanical robustness, and three-dimensional porous architecture that facilitates rapid charge transport and electrolyte penetration. However, the intrinsically inert surface of NF limits active material adhesion and uniform growth. In this work, a hierarchical interfacial engineering strategy is proposed on modifying NF by sequentially coating with polydopamine (PDA), anchoring Ultraphene nanosheets, and subsequently growing nickel iron metal–organic frameworks (NiFeMOF) for the application on high-performance electrodes of battery-supercapacitor hybrids (BSHs). Optimizing the PDA polymerization time offers uniform surface coverage and abundant functional groups, while introducing Ultraphene layers provides improved conductivity and ion accessibility. Building upon this engineered interlayer, the NiFeMOF-coated modified NF (U-PDA-NF) delivers a significantly higher specific capacitance of 1911 mF/cm2 at 6 mA/cm2 than that of NiFeMOF/NF, attributed to enhanced nucleation, reduced resistance, and favorable surface-controlled kinetics. The assembled BSH achieves a maximum energy density of 26.9 mWh/cm2 at 325 mW/cm2, and excellent cycling stability with a capacitance retention of 93.2% and Coulombic efficiency of 96.9% after 10,000 cycles. This study demonstrates effectiveness of PDA/Ultraphene interlayers in unlocking full potentials of NF substrates for advanced hybrid energy storage applications. This work introduces a versatile and scalable surface modification route that can be extended to various metal foam substrates and active materials, providing a general strategy for improving interfacial compatibility and electrochemical efficiency. The demonstrated interlayer design highlights a direction for constructing high-performance hybrid energy storage systems that bridge the gap between supercapacitors and batteries. © 2025 The Authors. Published by American Chemical Society

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