Peering into buried interfaces with X-rays and electrons to unveil MgCO3 formation during CO2 capture in molten salt-promoted MgO

A. H. Bork, M. Rekhtina, E. Willinger, Pedro Castro-Fernández, J. Drnec, P. Abdala, C. Müller
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引用次数: 19

Abstract

Significance The grand challenge of reducing CO2 emissions requires the development of cost-effective CO2 sorbents. Based on the theoretically obtainable weight-normalized CO2 uptake, MgO-based materials promoted with molten salts are attractive sorbents when compared to amines or metal organic frameworks. However, there is very little understanding of the processes that occur at the atomic-to-micro scale during CO2 capture conditions, hampering the advancement of such sorbents. Combining X-ray and electron-based characterization techniques, we observe that MgCO3 crystals form via nucleation and growth at the interface between MgO and the molten salt and are oriented with respect to the MgO(100) surface. Hence, more-effective MgO-based sorbents will require maximizing the interfacial area and the number of nucleation sites at the interface. The addition of molten alkali metal salts drastically accelerates the kinetics of CO2 capture by MgO through the formation of MgCO3. However, the growth mechanism, the nature of MgCO3 formation, and the exact role of the molten alkali metal salts on the CO2 capture process remain elusive, holding back the development of more-effective MgO-based CO2 sorbents. Here, we unveil the growth mechanism of MgCO3 under practically relevant conditions using a well-defined, yet representative, model system that is a MgO(100) single crystal coated with NaNO3. The model system is interrogated by in situ X-ray reflectometry coupled with grazing incidence X-ray diffraction, scanning electron microscopy, and high-resolution transmission electron microscopy. When bare MgO(100) is exposed to a flow of CO2, a noncrystalline surface carbonate layer of ca. 7-Å thickness forms. In contrast, when MgO(100) is coated with NaNO3, MgCO3 crystals nucleate and grow. These crystals have a preferential orientation with respect to the MgO(100) substrate, and form at the interface between MgO(100) and the molten NaNO3. MgCO3 grows epitaxially with respect to MgO(100), and the lattice mismatch between MgCO3 and MgO is relaxed through lattice misfit dislocations. Pyramid-shaped pits on the surface of MgO, in proximity to and below the MgCO3 crystals, point to the etching of surface MgO, providing dissolved [Mg2+…O2–] ionic pairs for MgCO3 growth. Our studies highlight the importance of combining X-rays and electron microscopy techniques to provide atomic to micrometer scale insight into the changes occurring at complex interfaces under reactive conditions.
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用x射线和电子观察埋藏的界面,揭示熔融盐促进的MgO中CO2捕获过程中MgCO3的形成
减少二氧化碳排放的巨大挑战要求开发具有成本效益的二氧化碳吸附剂。基于理论上可获得的重量归一化CO2吸收量,与胺或金属有机框架相比,用熔盐促进的mgo基材料是有吸引力的吸附剂。然而,在二氧化碳捕获过程中,人们对原子到微观尺度上发生的过程知之甚少,这阻碍了这种吸附剂的发展。结合x射线和电子表征技术,我们观察到MgCO3晶体在MgO和熔盐界面处通过成核和生长形成,并且相对于MgO(100)表面取向。因此,更有效的mgo基吸附剂需要最大化界面面积和界面成核位点的数量。熔融碱金属盐的加入极大地加速了MgO通过形成MgCO3捕获CO2的动力学。然而,生长机制、MgCO3形成的性质以及熔融碱金属盐在CO2捕集过程中的确切作用仍然是未知的,这阻碍了更有效的mgo基CO2吸附剂的开发。在这里,我们揭示了MgCO3在实际相关条件下的生长机制,使用了一个定义明确但具有代表性的模型系统,即包裹有NaNO3的MgO(100)单晶。模型系统通过原位x射线反射仪、掠射x射线衍射、扫描电子显微镜和高分辨率透射电子显微镜进行检测。当裸露的MgO(100)暴露于CO2流动时,形成约7-Å厚度的非晶体表面碳酸盐层。相比之下,当MgO(100)被NaNO3包裹时,MgCO3晶体形成并生长。这些晶体相对于MgO(100)衬底具有优先取向,并形成于MgO(100)和熔融NaNO3之间的界面。MgCO3相对于MgO呈外延生长(100),并且MgCO3和MgO之间的晶格失配通过晶格失配位错得到缓解。MgO表面的金字塔形凹坑位于MgCO3晶体附近和下方,表明表面MgO被蚀刻,为MgCO3生长提供了溶解的[Mg2+…O2 -]离子对。我们的研究强调了结合x射线和电子显微镜技术的重要性,以提供原子到微米尺度的洞察在反应条件下复杂界面发生的变化。
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