Silicone for Lithium-Ion Battery Anode Derived from Geothermal Waste Silica through Magnesiothermic Reduction and Double Stages in Acid Leaching

Silviana, Silviana; Ma'ruf, Amar; Dalanta, Febio

doi:10.4028/p-2y9z6c

Cited by 2 publications

(1 citation statement)

References 45 publications

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“…In the context of Li-ion batteries, SNPs are used to improve battery material performance and lifetime. SNPs are used as the raw material to synthesize anode composite mixture, because they offer a large surface area for lithium-ion storage, increasing the battery's overall energy density [58]. SNP can be further synthesized to silicon before being used as a material that combined with graphite for anode composites in Li-ion batteries.…”

Section: Applications Of Snps In Bio-energy Areamentioning

confidence: 99%

Advances in modified silica nanoparticles utilization for various applications: Now and future

Silviana,

Dalanta

2024

E3S Web Conf.

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The review article explores the multifaceted applications of silica nanoparticles (SNPs) across diverse industries, emphasizing their catalytic role in transformative advancements. Green nanotechnology principles are crucial for sustainable SNP synthesis, with a focus on utilizing natural extracts and bio-agents. Standardization and enhanced collaboration between industry and academia are pivotal for realizing the broader potential of SNPs. In the biomedical realm, SNPs exhibit exceptional capabilities in drug delivery and diagnostics, promising significant medical advancements. Safe integration necessitates collaborative efforts in safety assessments, long-term studies, and standardized testing. The exploration of SNP-based advanced coatings hints at industry-specific applications, with a recommendation for continued research into new capabilities and compatibility. SNPs in Li-ion batteries show promise for energy storage, urging further investigation into scalability and long-term performance. Agriculture benefits from SNP applications in precision farming, emphasizing the need for environmentally conscious formulations. In nanocomposite materials, SNPs enhance mechanical properties, advocating collaborative research for standardization and optimization. The adaptability of SNP-based smart coatings in aerospace and automotive industries requires exploration of new functionalities and seamless integration. In conclusion, SNPs hold promising prospects in healthcare, energy storage, and agriculture, emphasizing the necessity of collaborative efforts, sustained research, and a commitment to responsible and innovative SNP integration for a technologically advanced and environmentally conscious future.

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Section: Applications Of Snps In Bio-energy Areamentioning

confidence: 99%

Advances in modified silica nanoparticles utilization for various applications: Now and future

Silviana,

Dalanta

2024

E3S Web Conf.

Self Cite

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Use of Modified Silica as Selective Adsorbent on Exhaust and Dissolved Gases

Silviana,

Silvester,

Rochman

et al. 2024

KEM

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Emissions are substances that enter the air, whether or not they have the potential as pollutants. Emission gases can have adverse effects on the health of living beings, especially humans, and can contribute to an increase in the Earth's temperature. Therefore, separation efforts are needed to minimize the negative impacts caused by them. Adsorption method was categorized as absorption, cryogenic distillation, and membrane. Although there were shortcomings in adsorbing emission gases through the method, it remained a promising approach. Adsorption was recognized for its economic viability, technological effectiveness, thermally stability, corrosion resistance, high load capacity, and tunable surface properties. However, adsorption materials were categorized as porous carbon, zeolites, metal-organic frameworks (MOFs), porous polymers, and porous silica. A significant limitation of the method was its susceptibility to decreased capacity in the presence of water vapor. The analysis results showed that porous silica became a superior adsorption material due to its high porosity, which facilitated rapid gas diffusion. To enhance selectivity and adjust pore size, material modifications, particularly silica, became necessary. This showed that surface modification for silicasupported the improvements in selectivity and pore size.

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Silicone for Lithium-Ion Battery Anode Derived from Geothermal Waste Silica through Magnesiothermic Reduction and Double Stages in Acid Leaching

Cited by 2 publications

References 45 publications

Advances in modified silica nanoparticles utilization for various applications: Now and future

Advances in modified silica nanoparticles utilization for various applications: Now and future

Use of Modified Silica as Selective Adsorbent on Exhaust and Dissolved Gases

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