Roll-to-Roll Nanomanufacturing of Hybrid Nanostructures for Energy Storage Device Design

Journal Reference

ACS Appl. Mater. Interfaces, 2015, 7 (26), pp 14201–14210.

Landon Oakes^1,2, Trevor Hanken², Rachel Carter², William Yates², and Cary L. Pint^1,2

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1. Interdisciplinary Materials Science and Engineering,Vanderbilt University, Nashville, Tennessee 37212,United States
2. Mechanical Engineering,Vanderbilt University, Nashville, Tennessee 37212, United States

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Abstract

A key limitation to the practical incorporation of nanostructured materials into emerging applications is the challenge of achieving low-cost, high throughput, and highly replicable scalable nanomanufacturing techniques to produce functional materials. Here, we report a benchtop roll-to-roll technique that builds upon the use of binary solutions of nanomaterials and liquid electrophoretic assembly to rapidly construct hybrid materials for battery design applications. We demonstrate surfactant-free hybrid mixtures of carbon nanotubes, silicon nanoparticles, MoS₂ nanosheets, carbon nanohorns, and graphene nanoplatelets. Roll-to-roll electrophoretic assembly from these solutions enables the controlled fabrication of homogeneous coatings of these nanostructures that maintain chemical and physical properties defined by the synergistic combination of nanomaterials utilized without adverse effects of surfactants or impurities that typically limit liquid nanomanufacturing routes. To demonstrate the utility of this nanomanufacturing approach, we employed roll-to-roll electrophoretic processing to fabricate both positive and negative electrodes for lithium ion batteries in less than 30 s. The optimized full-cell battery, containing active materials of prelithiated silicon nanoparticles and MoS₂ nanosheets, was assessed to exhibit energy densities of 167 Wh/kgcell^–1 and power densities of 9.6 kW/kgcell^–1.

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