具有磁刺激功能的聚砜和碳基填料纳米结构复合材料用于高效捕获二氧化碳

IF 6.7 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Science: Advanced Materials and Devices Pub Date : 2024-03-04 DOI:10.1016/j.jsamd.2024.100701
Muhammad Nisar , Leonardo Moreira Dos Santos , Julian Geshev , Muhammad I. Qadir , Sherdil Khan , Guilhermino J.M. Fechine , Giovanna Machado , Sandra Einloft
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引用次数: 0

摘要

减缓人为二氧化碳排放造成的全球变暖是当今的热门研究课题。用于捕获一氧化碳的液体溶剂吸附剂成本高且难以处理,是其工业应用的主要障碍。地球上丰富的固体吸附剂是二氧化碳分离的有利候选材料,可为二氧化碳解吸提供低能耗。本文通过简单的溶液混合法制备了聚砜(PSF)纳米复合材料。使用碳基填料,即碳纳米管(CNT)和活性炭(CA)(5-20 wt.%)作为填料,其中活性炭含有纳米铁颗粒。对它们的形态、热性能、一氧化碳捕获能力和磁性能进行了全面研究。透射电子显微镜(TEM)显示,聚合物基体中的填料分布均匀,铁纳米粒子的尺寸为 47-54 nm。热分析表明,与原始聚合物相比,添加 5 wt.% 的纳米粒子可使初始()和最大()降解温度提高约 4 °C。根据差示扫描量热仪(DSC)的估算,原始 PSF 和生产的纳米复合材料的玻璃化转变温度()显示出相同的值。随着填料量的增加,水接触角值逐渐减小,这表明 PSF 纳米复合材料具有亲水性。所获得的 PSF 纳米复合材料在 45 °C 时的二氧化碳捕集能力约为 40-61 mgCO/g,高于原始 PSF。与之前开发的系统相比,这一卓越成就树立了新的基准。填料的引入将二磁性聚合物基体转变为铁磁体,呈现出约 480 Oe 的矫顽力,增强了材料在微电子领域的应用潜力。
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Nanoarchitectured composite of polysulfone and carbon-based fillers bearing magnetically stimulable function for efficient CO2 capture

Mitigating the global warming caused by CO2 emissions from anthropogenic sources is a hot research topic in the current era. The high cost and difficulty in handling liquid solvent absorbents for CO2 capture are the main barriers to their industrial application. Earth-abundant solid sorbents are favorable candidates for CO2 separation, offering a low energy penalty for CO2 desorption. Here, Polysulfone (PSF) nanocomposites were prepared by simple solution blending. The carbon-based fillers, namely carbon nanotubes (CNT), and activated carbon (CA) in the range of 5–20 wt%, containing iron nanoparticles, were used as fillers. Their morphological, thermal, CO2 capture capacity and magnetic properties were comprehensively studied. Transmission electron microscopy (TEM) evidenced uniform filler distribution in the polymer matrix with sizes of 47–54 nm. Thermal analysis revealed an approximately 4 °C improvement in both the initial (Tonset) and maximum (Tmax) degradation temperatures by adding 5 wt% of nanoparticles compared to the pristine polymer. The glass transition temperature (Tg) of the pristine PSF and produced nanocomposites showed identical values as estimated by differential scanning calorimetry (DSC). The increase in filler amount gradually decreased the water contact angle values, indicating a hydrophilic classification of the PSF nanocomposites. The obtained PSF nanocomposites exhibited an efficient CO2 capture capacity of about 40–61 mgCO2/g at 45 °C, higher than pristine PSF. This remarkable achievement sets a new benchmark compared to previously developed systems. The introduction of the filler transforms the diamagnetic polymer matrix into a ferromagnet, presenting a coercivity of about 480 Oe, enhancing the material's potential for applications in microelectronics.

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来源期刊
Journal of Science: Advanced Materials and Devices
Journal of Science: Advanced Materials and Devices Materials Science-Electronic, Optical and Magnetic Materials
CiteScore
11.90
自引率
2.50%
发文量
88
审稿时长
47 days
期刊介绍: In 1985, the Journal of Science was founded as a platform for publishing national and international research papers across various disciplines, including natural sciences, technology, social sciences, and humanities. Over the years, the journal has experienced remarkable growth in terms of quality, size, and scope. Today, it encompasses a diverse range of publications dedicated to academic research. Considering the rapid expansion of materials science, we are pleased to introduce the Journal of Science: Advanced Materials and Devices. This new addition to our journal series offers researchers an exciting opportunity to publish their work on all aspects of materials science and technology within the esteemed Journal of Science. With this development, we aim to revolutionize the way research in materials science is expressed and organized, further strengthening our commitment to promoting outstanding research across various scientific and technological fields.
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