Domestic Food Waste Derived Porous Carbon for Energy Storage Applications

Packiyalakshmi, Parameswaran; Chandrasekhar, Bongu; Kalaiselvi, N.

doi:10.1002/slct.201900818

Cited by 10 publications

(4 citation statements)

References 57 publications

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“…Some BDC with typical sheet structures, such as peanut shell‐derived carbon, [ 212 ] strawberry‐derived carbon, [ 213 ] oyster‐shell‐derived carbon, [ 214 ] and rice‐derived carbon, [ 215 ] can act as carbon matrix to reasonably design electrode materials for batteries. [ 216 ] According to needs, different parts of the same biomass material with different activation methods have different carbon sheet structures.…”

Section: D Designmentioning

confidence: 99%

Biomass‐Derived Carbon for High‐Performance Batteries: From Structure to Properties

Sun

Shi

Yang

et al. 2022

Adv Funct Materials

131

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Owing to the sustainability, environmental friendliness, and structural diversity of biomass-derived materials, extensive efforts have been devoted to use them as energy storage materials in high-energy rechargeable batteries. A timely and comprehensive review from the structures to mechanisms will significantly widen this research field. Here, it starts with the operation mechanism of batteries, and it aims to summarize the latest advances for biomass-derived carbon to achieve high-energy battery materials, including activation carbon methods and the structural classification of biomass-derived carbon materials from zero dimension, one dimension, two dimension, and three dimension. Each strategy starts with carefully selected examples and then moves to illustrate the underlying transport mechanism of electrons in the structure. In the end, challenges, strategies, and outlooks are pointed out for the future development of biomass-derived carbon materials. Overall, this review will help researchers choose appropriate strategies to design biomass-derived carbon materials, thereby promoting the application of biomass materials in battery design.

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Section: D Designmentioning

confidence: 99%

Biomass‐Derived Carbon for High‐Performance Batteries: From Structure to Properties

Sun

Shi

Yang

et al. 2022

Adv Funct Materials

131

View full text Add to dashboard Cite

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“…Conversely, hard or nongraphitizable carbons are proven to be one of the most suitable materials for SIB anodes, as noted by the abundance of literature on this topic. ,− Although hard carbons can be synthesized using several raw materials, their production from waste or end-of-life materials has recently received considerable attention. Different types of waste including bio, ,− ,− plastics, and rubber tires have been used to synthesize such hard carbons, and high capacities between 200 and 250 mAh g –1 have been achieved when used as active anode materials in SIBs.…”

Section: Introductionmentioning

confidence: 99%

Repurposing Waste Tires as Tunable Frameworks for Use in Sodium-Ion and Lithium–Sulfur Batteries

Djuandhi

Gaikwad

Cowie

et al. 2021

ACS Sustainable Chem. Eng.

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Selectively resourcing electrode components can provide a significant advantage in the uptake of next generation battery systems especially considering the performance of currently incumbent lithium-ion battery technology. This work systematically explores the use of a waste stream to generate electrode components and the influence that treatment and preparation factors have on electrochemical performance. A series of carbonaceous materials derived from waste rubber tires are prepared, involving pyrolysis at 700 and 900 °C as well as physical activation using a feed of CO 2 gas. Results from Raman spectroscopy and X-ray powder diffraction (XRD) show an increase in graphitic character and larger particle size distribution of the carbon with increasing temperatures of pyrolyzation. They also reveal the impact of air and moisture on the evolution of crystalline impurities such as ZnS, CaCO 3 , and Ca(OH) 2 , and consequently their impact on the evolution of the carbon morphology. Galvanostatic cycling of Na-ion and Li−S cells involving the pyrolyzed rubber tires as an electrode component reveal different priorities as to which parameters to improve when designing materials for different cell systems. While higher specific capacities are achieved with more graphitic carbon morphologies in Na half-cells (300 mAh g −1 discharge capacity maintained after 20 cycles at 10 mA g −1 ), less graphitic morphologies were observed to reduce capacity fading experienced in Li−S cells (1003 mAh g −1 discharge capacity maintained after 18 cycles at 167.2 mA g −1 , ∼ 76% of initial value). Ex situ Raman, XRD, and X-ray absorption near-edge structure (XANES) spectroscopies were used to elucidate the mechanisms involved in post electrochemical treatment. This work highlights a pathway to use waste tires to generate valuable electrode components (active material in Na half-cells and S hosts in Li−S cells), and a similar methodology could be applied to other waste streams.

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“…These waste food products inherently feature a 3D carbon skeleton. Consequently, the carbonization process applied to them yields a substantial increase in micro and nanopores, a feature that significantly augments ion diffusion, enhances electrolyte accessibility, amplifies surface area, and ultimately elevates battery performance [ 109 , 110 , 162–166 ]. Carbon nanofibers is another material that displays favourable characteristics towards battery applications.…”

Section: Energy Storage Applications Of Food Waste Derived Porous Car...mentioning

confidence: 99%

Recent advances in food waste-derived nanoporous carbon for energy storage

Davidraj,

Sathish,

Benzigar

et al. 2024

Science and Technology of Advanced Materials

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Affordable and environmentally friendly electrochemically active raw energy storage materials are in high demand to switch to mass-scale renewable energy. One particularly promising avenue is the feasibility of utilizing food waste-derived nanoporous carbon. This material holds significance due to its widespread availability, affordability, ease of processing, and, notably, its cost-free nature. Over the years, various strategies have been developed to convert different food wastes into nanoporous carbon materials with enhanced electrochemical properties. The electrochemical performance of these materials is influenced by both intrinsic factors, such as the composition of elements derived from the original food sources and recipes, and extrinsic factors, including the conditions during pyrolysis and activation. While current efforts are dedicated to optimizing process parameters to achieve superior performance in electrochemical energy storage devices, it is timely to take stock of the current state of research in this emerging field. This review provides a comprehensive overview of recent developments in the fabrication and surface characterisation of porous carbons from different food wastes. A special focus is given on the applications of these food waste derived porous carbons for energy storage applications including batteries and supercapacitors.

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Domestic Food Waste Derived Porous Carbon for Energy Storage Applications

Cited by 10 publications

References 57 publications

Biomass‐Derived Carbon for High‐Performance Batteries: From Structure to Properties

Biomass‐Derived Carbon for High‐Performance Batteries: From Structure to Properties

Repurposing Waste Tires as Tunable Frameworks for Use in Sodium-Ion and Lithium–Sulfur Batteries

Recent advances in food waste-derived nanoporous carbon for energy storage

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