Structural energy storage system using electrospun carbon nanofibers with carbon nanotubes

Lee, Dasom; Jung, Jaemin; Lee, Gyu Hee; Li, Meixian; Lee, Woo Il; Um, Moon‐Kwang; Choi, Sung‐Woong

doi:10.1002/pc.27908

Polymer Composites

2023

DOI: 10.1002/pc.27908

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Structural energy storage system using electrospun carbon nanofibers with carbon nanotubes

Dasom Lee,

Jaemin Jung,

Gyu Hee Lee

et al.

Abstract: In the present study, carbon nanofibers containing multi‐walled carbon nanotubes (MWCNTs) were fabricated and employed as electrodes for structural supercapacitors. Carbon nanofibers were utilized as the electrode material in structural supercapacitors to increase the specific surface area. Electrospun polyacrylonitrile (PAN) nanofibers underwent conversion to carbon nanofibers through stabilization and carbonization processes aided by thermal treatment. The specific surface area of the electrospun carbon nano… Show more

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2024

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Cited by 4 publications

References 49 publications

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Recyclable multiscale composite structural supercapacitor

Kazari,

Farkhondehnia,

Maric

et al. 2024

Polymer Composites

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This study presents a proof‐of‐concept for a fully recyclable and sustainable composite structural supercapacitor. The fabricated device shows promising energy storage capabilities and mechanical strength. Generally, structural supercapacitors capacitance is considerably lower than non‐load‐bearing mono‐functional supercapacitors and are made via thermoset polymer electrolyte. Here, the device is fabricated using an optimized solid electrolyte composition of carbon aerogel modified carbon fibers, fumed silica, lithium salt, and a thermoplastic polymer matrix. The supercapacitor exhibits a high capacitance of 5225 mFg−1 (193 mFcm−2) at 1 mVs−1 scan rate and a large voltage window of 4 V. A simple dissolution/reprecipitation method is used to demonstrate the recycling feasibility, with minimal mechanical degradation (<10%) in the polymer matrix and no chemical structure changes in the electrolyte. This work establishes a promising ecologically‐sound structural energy storage technology with favorable performance compared to prior studies.Highlights A proof‐of‐concept fully recyclable composite structural supercapacitor is made. Thermoplastic‐based robust polymer electrolytes are fabricated. Recycling via dissolution and re‐precipitation of components is demonstrated. Comparison to prior structural supercapacitors shows favorable performance.

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Recyclable multiscale composite structural supercapacitor

Kazari,

Farkhondehnia,

Maric

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

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Porous structural battery composite for coordinated integration of mechanical and electrical functionalities

He,

Zhang,

Zhang

et al. 2024

Polymer Composites

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Structural battery composites (SBCs) represent an emerging multifunctional technology in which materials functionalized with energy storage capabilities are used to build load‐bearing structural components. However, due to the liquid electrolyte contamination in structural battery electrolyte (SBE) and the large volume expansion of active battery materials, the poor interlayer interfacial in multilayer SBCs often causes difficulties in practical use. In this study, a new porous LiFePO4‐graphite SBC is designed and fabricated by independently distributing battery materials and resin matrix on carbon fiber fabric in pattern lattice form to prepare electrodes prepreg. The cured porous composite framework supports the load‐bearing function while limiting the electrochemical reaction in liquid electrolyte within lattices. The electrodes show reversible electric resistance after 3000 bending cycles with radius as small as 10 mm. The mechanical properties enhance significantly with tensile strength of 486.1 MPa and Young's modulus of 9.1 GPa compared to that with a liquid–solid biphasic mixed SBE structure. The SBC also exhibits a favorable capacity of 27.8 mAh/g at 0.1C. This straightforward integration path of mechanical and electrical functionalities is compatible with the manufacturing process of aerospace composite structures, which will provide an efficient and convenient energy supply solution for distributed electronics.Highlights A porous full‐cell structural battery composite (SBC) was designed and fabricated with prepregs. A suspension deposition and volatilization method was developed for robust battery material coating. Electrodes layer exhibited reversible electric resistance after 3000 tensile/bending cycles. The tensile strength and modulus increased significantly compared to the SBC with liquid–solid biphasic mixed structural battery electrolyte. Coordinated integration path was completely compatible with the manufacturing process of aerospace composite structures.

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Cement-based structural supercapacitors design and performance: A review

Feng,

Wei,

et al. 2024

Journal of Energy Storage

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Structural energy storage system using electrospun carbon nanofibers with carbon nanotubes

Cited by 4 publications

References 49 publications

Recyclable multiscale composite structural supercapacitor

Recyclable multiscale composite structural supercapacitor

Porous structural battery composite for coordinated integration of mechanical and electrical functionalities

Cement-based structural supercapacitors design and performance: A review

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