Olivine nanoparticles for Fast Atmospheric CO2 capture at Ambient Conditions

IF 2.7 4区 材料科学 Q3 CHEMISTRY, PHYSICAL
Manuel L. Iozzia, Francesco Goto, Alessandro Podestà, Roberta Vecchi, Alberto Calloni, Cristina Lenardi, Gianlorenzo Bussetti, Marcel Di Vece
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Abstract

To mitigate climate change, CO2 sequestration from the atmosphere is being considered as a method to reduce its greenhouse effect and subsequently lower the Earth's surface temperature. A promising approach is the storage of CO2 in minerals, of which Olivine is a promising candidate due to its Earth abundance and high CO2 absorption capacity, which is of the order of 50 wt.%. A bottleneck for Olivine carbonation is the slow reaction rate at ambient conditions, which previously resulted in supplying CO2 at extreme pressures and temperatures to force carbonation. In this study, nanoscale Olivine particles are fabricated, which due to their high surface‐to‐volume ratio, reach a very high carbonation conversion at a time scale of minutes at ambient conditions. The carbonation is measured by X‐ray photoelectron spectroscopy (XPS), which yielded both the presence of carbonates as well as information on the Olivine oxidation state, in agreement with electron diffraction analysis. This work forms the basis for employing Olivine nanoparticles, as fabricated by the relatively simple method of magnetron sputtering, to capture CO2 from the atmosphere at economic conditions.
用于在环境条件下快速捕获大气中二氧化碳的橄榄石纳米颗粒
为了减缓气候变化,人们正在考虑从大气中封存二氧化碳,以此来减少温室效应,进而降低地球表面温度。一种很有前景的方法是将二氧化碳封存在矿物中,而橄榄石因其在地球上的丰度和高二氧化碳吸收能力(约为 50 wt.%)而成为一种很有前景的候选物质。橄榄石碳化的一个瓶颈是其在环境条件下的反应速度较慢,这导致以前需要在极高的压力和温度下提供二氧化碳来强制碳化。本研究制造了纳米级的橄榄石颗粒,由于其表面体积比高,在环境条件下只需几分钟的时间就能达到非常高的碳化转化率。通过 X 射线光电子能谱(XPS)对碳化过程进行测量,结果与电子衍射分析结果一致,既显示了碳酸盐的存在,也提供了有关橄榄石氧化态的信息。这项工作为采用相对简单的磁控溅射方法制造的橄榄石纳米粒子在经济条件下捕获大气中的二氧化碳奠定了基础。
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来源期刊
Particle & Particle Systems Characterization
Particle & Particle Systems Characterization 工程技术-材料科学:表征与测试
CiteScore
5.50
自引率
0.00%
发文量
114
审稿时长
3.0 months
期刊介绍: Particle & Particle Systems Characterization is an international, peer-reviewed, interdisciplinary journal focusing on all aspects of particle research. The journal joined the Advanced Materials family of journals in 2013. Particle has an impact factor of 4.194 (2018 Journal Impact Factor, Journal Citation Reports (Clarivate Analytics, 2019)). Topics covered include the synthesis, characterization, and application of particles in a variety of systems and devices. Particle covers nanotubes, fullerenes, micelles and alloy clusters, organic and inorganic materials, polymers, quantum dots, 2D materials, proteins, and other molecular biological systems. Particle Systems include those in biomedicine, catalysis, energy-storage materials, environmental science, micro/nano-electromechanical systems, micro/nano-fluidics, molecular electronics, photonics, sensing, and others. Characterization methods include microscopy, spectroscopy, electrochemical, diffraction, magnetic, and scattering techniques.
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