Fabrication of Graphitized Carbon Fibers from Fusible Lignin and Their Application in Supercapacitors

Zhou, Linfei; You, Xiangyu; Wang, Lingjie; Qi, Shijie; Wang, Ruichen; Uraki, Yasumitsu; Zhang, Hui Jie

doi:10.3390/polym15081947

Cited by 4 publications

(4 citation statements)

References 77 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Furthermore, the orientation of the crease of the singular rips observed on the microfiber edges indicates a pressure force stemming from the microfiber at the carbonaceous interface. As the presence of transition metal catalysts such as Al 3+ was previously reported to lower the temperature of graphitization, these local overpressures could plausibly be due to events related to surface graphitization . The migration of volatile carbon oxide through the coating during annealing could have led to the appearance of crystalline aluminum oxide-based outgrowths, as was previously reported on protocols of fabrication of fiber-templated ceramic thin tubes …”

Section: Resultsmentioning

confidence: 59%

“…As the presence of transition metal catalysts such as Al 3+ was previously reported to lower the temperature of graphitization, these local overpressures could plausibly be due to events related to surface graphitization. 61 The migration of volatile carbon oxide through the coating during annealing could have led to the appearance of crystalline aluminum oxide-based outgrowths, as was previously reported on protocols of fabrication of fiber-templated ceramic thin tubes. 62 To further discuss the cracked coatings, the thermal procedure was repeated in an inert atmosphere, in order to preserve the underneath carbon microfiber, showcased in Figure 5.…”

Section: Thermal Cycle Of Carbon Microfibers Coated With Aluminum Hyd...mentioning

confidence: 73%

See 1 more Smart Citation

Amorphous Alumina Thin Films Deposited on Carbon Microfibers As Interface Layer for Thermal Oxidation Barriers

des Ligneris,

Samélor,

Vergnes

et al. 2023

ACS Appl. Eng. Mater.

View full text Add to dashboard Cite

Carbon microfibers make a promising candidate as textile reinforcement for high temperature composites provided that their limitation of thermal oxidation over 670 K in air is overcome. As such, this study explored the potential of atomic layer deposition (ALD) for the deposition of a substrate-nanolaminate interface layer for the design of a refractory oxygen barrier coating applied to individual carbon microfibers within a woven fabric. To this end, amorphous aluminum hydroxide was deposited at 350 K in a flow-type thermal ALD reactor operating at a pressure of 1.8 Torr, yielding a growth per cycle (GPC) of 1.0 Å/cycle. The conformal aspect of the amorphous films was found to be well preserved below a thickness of 45 ± 5 nm, above which reorganization of the substrate surface by junction of the previously deposited layers resulted in a uniform deposition. Furthermore, a minimal thickness of 20 ± 2 nm was required to obtain self-standing films following the thermal oxidation of the carbon microfibers. Indeed, thermal treatment at 1380 K of the coated woven fabric induced multiple occurrences of neat cracks in the aluminum oxide films, attributed to the increased rigidity and mismatch between the respective thermal expansion coefficients. The dense network of nanograins of aluminum oxide was further characterized by using 4D-STEM, revealing multiple phases and orientations.

show abstract

Section: Resultsmentioning

confidence: 59%

Section: Thermal Cycle Of Carbon Microfibers Coated With Aluminum Hyd...mentioning

confidence: 73%

Amorphous Alumina Thin Films Deposited on Carbon Microfibers As Interface Layer for Thermal Oxidation Barriers

des Ligneris,

Samélor,

Vergnes

et al. 2023

ACS Appl. Eng. Mater.

View full text Add to dashboard Cite

show abstract

“…The sustainable footprint of lignin provides the basis for the synthesis of biomaterials that convert the uncontrolled use of chemical resources to the production of electricity [78]. The spectrum of direct applications of lignin includes the engineering industry [79], biomedicine and biotechnology [80], medicine [81], biopesticides and biofertilizers [82], wastewater treatment [83], biofuels [84], adsorbents [85], carbon fibers [86], adhesives [87], dispersants [88], anti-UV filters [89], and the pharmaceuticals industry [90].…”

Section: Ligninmentioning

confidence: 99%

Polymeric Materials Obtained by Extrusion and Injection Molding from Lignocellulosic Agroindustrial Biomass

Pacheco,

Evangelista-Osorio,

Muchaypiña-Flores

et al. 2023

Polymers

View full text Add to dashboard Cite

This review presents the advances in polymeric materials achieved by extrusion and injection molding from lignocellulosic agroindustrial biomass. Biomass, which is derived from agricultural and industrial waste, is a renewable and abundant feedstock that contains mainly cellulose, hemicellulose, and lignin. To improve the properties and functions of polymeric materials, cellulose is subjected to a variety of modifications. The most common modifications are surface modification, grafting, chemical procedures, and molecule chemical grafting. Injection molding and extrusion technologies are crucial in shaping and manufacturing polymer composites, with precise control over the process and material selection. Furthermore, injection molding involves four phases: plasticization, injection, cooling, and ejection, with a focus on energy efficiency. Fundamental aspects of an injection molding machine, such as the motor, hopper, heating units, nozzle, and clamping unit, are discussed. Extrusion technology, commonly used as a preliminary step to injection molding, presents challenges regarding fiber reinforcement and stress accumulation, while lignin-based polymeric materials are challenging due to their hydrophobicity. The diverse applications of these biodegradable materials include automotive industries, construction, food packaging, and various consumer goods. Polymeric materials are positioned to offer even bigger contributions to sustainable and eco-friendly solutions in the future, as research and development continues.

show abstract

“…In nature, electrode materials determine the charge storage mechanism and the electrochemical performance of supercapacitors. Various carbon-based materials, including carbon nanotubes [9], graphene [10], activated carbon [11] and carbon fiber [12] are usually employed as electrode materials in EDLCs, which benefit from their unique properties, such as abundant availability, cost-effectiveness, excellent stability, environmental friendliness and good electrical conductivity [13].…”

Section: Introductionmentioning

confidence: 99%

P-Doped Modified Porous Carbon Derived from ZIF-8 for Enhanced Capacitive Performance

Guo,

Li,

et al. 2023

Energies

View full text Add to dashboard Cite

Porous carbon materials derived from ZIF-8 have attracted extensive research attention on account of their large surface area, tunable mesoporosity and abundant nitrogen content. However, directly carbonized ZIF-8 usually suffers from a low electronic conductivity, poor wettability and relatively low mesoporosity, which severely restricts their capacitive performance. Herein, P-doped modified carbon materials derived from ZIF-8 (ZPCs) were synthesized by using nontoxic phytic acid as a phosphorus source, followed by carbonization at high temperature. Benefiting from its relatively high specific surface area of 911.7 m2 g−1 and higher ratio of mesopores, as well as N, O and P doping, ZPC-1000 delivers the largest specific capacity, up to 219.4 F g−1 at 1 A g−1, among the prepared samples and an outstanding cycle span, retaining 100% capacity after 2000 cycles at 5 A g−1. In this work, we highlight the strategy of constructing a synergistic effect between high mesoporosity and heteroatom doping, which can greatly boost the capacitive performance of carbon materials.

show abstract

Fabrication of Graphitized Carbon Fibers from Fusible Lignin and Their Application in Supercapacitors

Cited by 4 publications

References 77 publications

Amorphous Alumina Thin Films Deposited on Carbon Microfibers As Interface Layer for Thermal Oxidation Barriers

Amorphous Alumina Thin Films Deposited on Carbon Microfibers As Interface Layer for Thermal Oxidation Barriers

Polymeric Materials Obtained by Extrusion and Injection Molding from Lignocellulosic Agroindustrial Biomass

P-Doped Modified Porous Carbon Derived from ZIF-8 for Enhanced Capacitive Performance

Contact Info

Product

Resources

About