Catalytic recycling of medical plastic wastes over La0.6Ca0.4Co1–Fe O3− pre-catalysts for co-production of H2 and high-value added carbon nanomaterials

Yu, Xiaohu; Chen, Guoxing; Widenmeyer, Marc; Kinski, Isabel; Liu, Xingmin; Kunz, Ulrike; Schüpfer, Dominique; Molina‐Luna, Leopoldo; Tu, Xin; Homm, Gert; Weidenkaff, Anke

doi:10.1016/j.apcatb.2023.122838

Cited by 12 publications

(3 citation statements)

References 70 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Yu et al employed a calixarene La 0.6 Ca 0.4 Co 1− x FexO 3− δ precatalyst to effectively deconstruct medical waste plastic materials into carbon nanotubes and hydrogen at 850 °C. 67 Remarkably, even after 10 consecutive high-temperature cycles, the catalyst maintained the highest yields of carbon nanotubes (245 mg g cat −1 ) and hydrogen (24.92 mmol g cat −1 ) for waste plastic treatment. Through varying the reaction temperature and pre-catalyst composition, they identified the Fe/Co ratio in the precatalyst as a key factor in enhancing reactivity and product selectivity.…”

Section: Catalytic Technology For Waste Plastics Resource Recoverymentioning

confidence: 93%

Advancements in catalysis for plastic resource utilization

Chen,

Bai,

Peng

et al. 2023

Environ. Sci.: Adv.

View full text Add to dashboard Cite

show abstract

Section: Catalytic Technology For Waste Plastics Resource Recoverymentioning

confidence: 93%

Advancements in catalysis for plastic resource utilization

Chen,

Bai,

Peng

et al. 2023

Environ. Sci.: Adv.

View full text Add to dashboard Cite

show abstract

“…Several microorganisms can be used, including hydrolytic, acidogenic, and acetogenic bacteria, to form VACs, metabolites, CO 2, CH 4 [64] alcohols [77], and H 2 [76]. The use of residues for H 2 synthesis is still being optimized for use on an industrial scale, which brings other possibilities for study and evaluation regarding the topic [147,148].…”

Section: Biofuelsmentioning

confidence: 99%

Valorization of Fermented Food Wastes and Byproducts: Bioactive and Valuable Compounds, Bioproduct Synthesis, and Applications

Faria,

Carvalho,

Conte-Junior

2023

Fermentation

View full text Add to dashboard Cite

Significant amounts of fermented food waste are generated worldwide, promoting an abundance of residual biomass that can be used as raw material to extract bioactive peptides, fermentable sugars, polyphenols, and valuable compounds for synthesizing bioproducts. Therefore, generating these high-value-added products reduces the environmental impact caused by waste disposal and increases the industrial economic value of the final products. This review presents opportunities for synthesizing bioproducts and recovering bioactive compounds (employing wastes and byproducts from fermented sources) with several biological properties to support their consumption as dietary supplements that can benefit human health. Herein, the types of fermented food waste and byproducts (i.e., vegetables, bread wastes, dairy products, brewing, and winery sources), pre-treatment processes, the methods of obtaining products, the potential health benefits observed for the bioactive compounds recovered, and other technological applications of bioproducts are discussed. Therefore, there is currently a tendency to use these wastes to boost bioeconomic policies and support a circular bioeconomy approach that is focused on biorefinery concepts, biotechnology, and bioprocesses.

show abstract

“…In the long-term, changing the energy grid in this direction will result in higher shares of renewable energy in the power mix. In recent years, increased interest has been shown in the application of plasma for hydrogen production [13,14], the catalytic synthesis of ammonia [15][16][17][18], the methanation of CO 2 to synthetic natural gas [19,20], the conversion of CO 2 to alcohols [21], and the production of nanomaterials [22], to name but a few applications. Since plasma is typically characterized by its fast startup [23][24][25][26], plasma-based technologies are of particular interest with respect to their increased use in the demand-side management of power systems.…”

Section: Introductionmentioning

confidence: 99%

Pioneering the Future: A Trailblazing Review of the Fusion of Computational Fluid Dynamics and Machine Learning Revolutionizing Plasma Catalysis and Non-Thermal Plasma Reactor Design

Arshad,

Ahmad,

Mularski

et al. 2024

Catalysts

View full text Add to dashboard Cite

The advancement of plasma technology is intricately linked with the utilization of computational fluid dynamics (CFD) models, which play a pivotal role in the design and optimization of industrial-scale plasma reactors. This comprehensive compilation encapsulates the evolving landscape of plasma reactor design, encompassing fluid dynamics, chemical kinetics, heat transfer, and radiation energy. By employing diverse tools such as FLUENT, Python, MATLAB, and Abaqus, CFD techniques unravel the complexities of turbulence, multiphase flow, and species transport. The spectrum of plasma behavior equations, including ion and electron densities, electric fields, and recombination reactions, is presented in a holistic manner. The modeling of non-thermal plasma reactors, underpinned by precise mathematical formulations and computational strategies, is further empowered by the integration of machine learning algorithms for predictive modeling and optimization. From biomass gasification to intricate chemical reactions, this work underscores the versatile potential of plasma hybrid modeling in reshaping various industrial processes. Within the sphere of plasma catalysis, modeling and simulation methodologies have paved the way for transformative progress. Encompassing reactor configurations, kinetic pathways, hydrogen production, waste valorization, and beyond, this compilation offers a panoramic view of the multifaceted dimensions of plasma catalysis. Microkinetic modeling and catalyst design emerge as focal points for optimizing CO2 conversion, while the intricate interplay between plasma and catalysts illuminates insights into ammonia synthesis, methane reforming, and hydrocarbon conversion. Leveraging neural networks and advanced modeling techniques enables predictive prowess in the optimization of plasma-catalytic processes. The integration of plasma and catalysts for diverse applications, from waste valorization to syngas production and direct CO2/CH4 conversion, exemplifies the wide-reaching potential of plasma catalysis in sustainable practices. Ultimately, this anthology underscores the transformative influence of modeling and simulation in shaping the forefront of plasma-catalytic processes, fostering innovation and sustainable applications.

show abstract

Catalytic recycling of medical plastic wastes over La0.6Ca0.4Co1–Fe O3− pre-catalysts for co-production of H2 and high-value added carbon nanomaterials

Cited by 12 publications

References 70 publications

Advancements in catalysis for plastic resource utilization

Advancements in catalysis for plastic resource utilization

Valorization of Fermented Food Wastes and Byproducts: Bioactive and Valuable Compounds, Bioproduct Synthesis, and Applications

Pioneering the Future: A Trailblazing Review of the Fusion of Computational Fluid Dynamics and Machine Learning Revolutionizing Plasma Catalysis and Non-Thermal Plasma Reactor Design

Contact Info

Product

Resources

About