Valorization of peanut wastes into a catalyst in production of biodiesel

Kim, Minyoung; Lee, Dongjun; Jung, Sungyup; Chang, Scott X.; Lin, Kun‐Yi Andrew; Bhatnagar, Amit; Kwon, Eilhann E.; Tsang, Yiu Fai

doi:10.1002/er.7248

Cited by 8 publications

(3 citation statements)

References 58 publications

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“…Using groundnut shells as a biomass feedstock could potentially be economically beneficial for groundnut farmers, while also reducing the amount of waste produced by the food processing industry. Various useful compounds can be extracted from groundnut shell powder, including biochar [32], cellulose nanofibers [33], biofuels such as bioethanol or biodiesel [34][35][36][37][38], carbon nanoparticles [39,40], and silica nanoparticles [41]. Some of these extracts, including biochar, carbon nanoparticles, silica nanoparticles, and peanut shell powder/fibers, can be used as filler material for developing polymer composites.…”

Section: Rankmentioning

confidence: 99%

From Waste to Strength: Unveiling the Mechanical Properties of Peanut-Shell-Based Polymer Composites

Mandala¹,

Hegde

Kodali

et al. 2023

J. Compos. Sci.

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Peanut-shell-based polymer composites have gained significant attention as sustainable and cost-effective materials with potential applications as food packaging films, ceiling tiles, insulation panels, supercapacitors, and electrodes in various industries like the packaging industry, construction, furniture, and electronics. This review article presents a systematic roadmap of the mechanical properties of peanut-shell-based polymer composites, analyzing the influence of factors such as filler content, surface modification techniques, interfacial adhesion, and processing methods. Through an extensive literature review, we highlight the mechanical properties of peanut-shell-based polymer composites. Furthermore, challenges and ongoing research efforts in this field are discussed. This comprehensive review provides valuable insights for researchers, industry professionals, and policymakers, promoting the development and utilization of peanut-shell-based polymer composites for various applications.

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Section: Rankmentioning

confidence: 99%

From Waste to Strength: Unveiling the Mechanical Properties of Peanut-Shell-Based Polymer Composites

Mandala¹,

Hegde

Kodali

et al. 2023

J. Compos. Sci.

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“…that focus on removing biodegradable organic contaminants and pathogens, biochar-based technologies are capable of removing multiple contaminants simultaneously, including many contaminants that are typically resistant to chemical and biological degradation in conventional treatment processes. [12][13][14] Moreover, biochar-modified soils tend to have higher moisture content in both fine-textured and coarse-textured soils because the biochar particles form larger pores in fine-textured soils are improving water flow and water availability in the soil; while biochar in coarse-textured soils clogs the largest pores in the soil, preventing water flow and improving water retention. 15 Global warming and the impact of human activities on ecosystems destabilize the balance between inputs and outputs and lead to the loss of soil organic carbon, which in turn exacerbates climate change.…”

Section: Introductionmentioning

confidence: 99%

Thermokinetics of production of biochar from crop residues: an overview

et al. 2022

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“…This is an advantage for bioplastic products because it mitigates the problems of climate change and global warming. 7 Additional to bioplastics, valorization of organic biomass can led us to obtain sustainable and valuable materials, such as crosslinking agents, chemicals and fuels, 8 for example, raw materials for bio-hydrogen production, 9 solar cells, 10 wastewater treatment 11 and solar-steam-assisted desalination, 12 to name a few. In fact, biomass also has great potential in the functional materials field of high performance.…”

Section: Introductionmentioning

confidence: 99%

Valorization of sawdust biomass for biopolymer extraction via green method: Comparison with conventional process

Cárdenas‐Zapata

Palma‐Ramírez

Flores‐Vela

et al. 2022

Intl J of Energy Research

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Summary The valorization of sawdust (SW) biomass by‐product, to extract cellulose through alkali and bleaching processes, including side‐streams to recover hemicellulose and lignin, is performed with the intention of evaluating differences with a proposed green method (GM). The study is developed with the intention of having a process at laboratory scale without leading to the complicated nanoscale processing. This study contemplates a process with scalable characteristics for the future, which contributes to wood processing waste around the world. Particularly, agroindustrial wastes from Durango (SWT1) and Hidalgo (SWT2), local communities of Mexico, were studied. SWT1 and SWT2 samples were processed with ethanol, sodium hydroxide followed by bleaching with sodium chlorite/acetic acid to remove, extractives (E), hemicellulose (H) and lignin (L), respectively. Selected‐SWT2 was processed through a proposed GM using hydrogen peroxide/sodium hydroxide. On the basis of results including Fourier transform infrared spectroscopy, thermogravimetric/differential analysis (TGA/DTG), X‐ray diffraction (XRD), dynamic light scattering, high heating value, scanning electron microscopy techniques and chemical composition, GM was capable of producing a biomass rich in α‐cellulose (58.0%: SWT2‐C), whereas processed SWT1 and SWT2 through conventional method led to a more percentage of H, β‐ and γ‐C mixtures than α‐polymorphous; 41.0% and 51.0%, respectively. This new method could impact of an important manner to the development of biodegradable thermoplastics. The approximation, from deconvolution of TGA/DTA, led to determine adequately the composition of hemicellulose (SWT1‐C: 51.0%, SWT2‐C: 36.0–0.00%), lignin (SWT1‐C: 17.0%, SWT2‐C: 20.0%) and cellulose (SWT1‐C: 32.0%, SWT2‐C: 44.0%). XRD analysis also indicated that samples contain the following percentage of polymorphous cellulose compounds: SWT1‐C (Type II: 71.3%), SWT2‐C (Type I α: 44.6% and II: 41.4%) and SWT2‐C‐GM (Type II: 38.8%), which confirms that the combination of the type of biomass and the applied pretreatment plays a fundamental role for final applications; in this case, it can be appropriate for elastomers and thermoplastic uses. As a final point, the cellulose composition and thermal stability of both sources is comparable with the commonly used raw material for commercial products.

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Valorization of peanut wastes into a catalyst in production of biodiesel

Cited by 8 publications

References 58 publications

From Waste to Strength: Unveiling the Mechanical Properties of Peanut-Shell-Based Polymer Composites

From Waste to Strength: Unveiling the Mechanical Properties of Peanut-Shell-Based Polymer Composites

Thermokinetics of production of biochar from crop residues: an overview

Valorization of sawdust biomass for biopolymer extraction via green method: Comparison with conventional process

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