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Bridging MOF properties to 3D printing: a framework for electrochemical energy storage architectures with synergistic porosity-ion dynamics

Chenfei Zhou, Huijie Zhou, Xinyu Qin, Shunyu Gu, Mengyao Zhang, Jifan Chen, L. Zhai, Huan Pang

2025Chemical Science5 citationsDOIOpen Access PDF

Abstract

growth and interfacial coating. Breakthrough applications in supercapacitors and batteries demonstrate the transformative potential of this integrated approach. Collectively, this work establishes a design paradigm that bridges porous material chemistry with advanced manufacturing for next-generation electrochemical energy storage architectures.

Topics & Concepts

Materials scienceNanotechnologySupercapacitorEnergy storageFabricationBridging (networking)Electrochemical energy storageBattery (electricity)3D printingElectrochemistryMetal-organic frameworkPorosityComposite numberElectrodeComputer scienceThermalSupercapacitor Materials and FabricationMetal-Organic Frameworks: Synthesis and ApplicationsAdvancements in Battery Materials
Bridging MOF properties to 3D printing: a framework for electrochemical energy storage architectures with synergistic porosity-ion dynamics | Litcius