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引用次数: 0
摘要
该研究调查了燃烧辅助合成正硅酸锂(Li4SiO4)粉末的方法,该方法具有捕获二氧化碳的潜在应用价值。研究使用工业级碳酸锂和金属硅粉末作为起始材料。在 500 至 900 °C 的温度范围内和不同的保温时间内对合成条件进行了探索。使用 FactSage 8.2 软件进行的热力学建模表明,以金属硅作为硅源,在 700 ℃ 或更高温度下生产 Li4SiO4 是可行的,实验证实了这一点。合成粉末的表征包括 X 射线衍射、比表面积测定、粒度分布分析、扫描电子显微镜和二氧化碳吸收测试。尽管 Li4SiO4 的含量最低,仅为 83.7%,但在 700 °C 和 45 分钟保温时间下合成的样品显示出最佳的二氧化碳吸收性能(12.80 wt%),同时具有最低的结晶粒度值(126.58 nm)、最高的比表面积值(4.975 m2/g)和最低的平均粒度值(10.85 µm),这对此类固体吸附剂的二氧化碳吸收性能非常有效。研究得出结论,虽然在实现最佳二氧化碳捕集性能方面仍存在挑战,但它为在碳捕集应用中使用正硅酸锂奠定了基础。 图文摘要
Thermodynamic Investigations for Combustion-Assisted Synthesis of Lithium Orthosilicate Powders
The study investigates the combustion-assisted synthesis of lithium orthosilicate (Li4SiO4) powders for potential CO2 capture applications. Technical-grade lithium carbonate and metallic silicon powders were used as starting materials. Synthesis conditions were explored across temperatures ranging from 500 to 900 °C and different holding durations. Thermodynamic modeling using FactSage 8.2 software suggested that Li4SiO4 production is feasible at temperatures of 700 °C and higher with metallic silicon as the silicon source, which was confirmed experimentally. Characterization of the synthesized powders involved X-ray diffraction, specific surface area determination, particle size distribution analysis, scanning electron microscopy, and CO2 uptake tests. Despite having the lowest Li4SiO4 content as 83.7%, the sample synthesized at 700 °C with 45 min of holding time showed the best CO2 uptake performance as 12.80 wt% while having the lowest crystallite size value (126.58 nm), the highest specific surface area value (4.975 m2/g) and the lowest average particle size value (10.85 µm) which are highly effective on the CO2 uptake performance of such solid sorbents. The study concludes that while challenges remain in achieving optimal CO2 capture performance, it lays a foundation for utilizing lithium orthosilicate in carbon capture applications.
期刊介绍:
Journal of Sustainable Metallurgy is dedicated to presenting metallurgical processes and related research aimed at improving the sustainability of metal-producing industries, with a particular emphasis on materials recovery, reuse, and recycling. Its editorial scope encompasses new techniques, as well as optimization of existing processes, including utilization, treatment, and management of metallurgically generated residues. Articles on non-technical barriers and drivers that can affect sustainability will also be considered.
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