Peter Amann, Bernhard Klötzer, David Degerman, Norbert Köpfle, Thomas Götsch, Patrick Lömker, Christoph Rameshan, Kevin Ploner, Djuro Bikaljevic, Hsin-Yi Wang, Markus Soldemo, Mikhail Shipilin, Christopher M. Goodwin, Jörgen Gladh, Joakim Halldin Stenlid, Mia Börner, Christoph Schlueter, Anders Nilsson
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引用次数: 35
摘要
在二氧化碳/一氧化碳(CO2/CO)氢化过程中,锌-铜(Zn)催化剂中锌(Zn)的活性化学态是氧化锌(ZnO)纳米颗粒、金属锌还是锌-铜表面合金一直存在争议。我们使用 X 射线光电子能谱在 180 至 500 毫巴的温度下探测 Zn/ZnO/Cu(211)上 CO2/CO 加氢过程中 Zn 和反应中间产物的性质。通过调节掠入射角,可以实现表面或体液灵敏度。二氧化碳的氢化反应更倾向于采用团簇或纳米颗粒形式的氧化锌,而在纯二氧化碳中,表面的锌铜合金变得更加突出。研究结果揭示了 CO 在形成 Zn-Cu 表面合金中的特殊作用,这种合金是促进 CO2 甲醇高效合成的活性相。
The state of zinc in methanol synthesis over a Zn/ZnO/Cu(211) model catalyst
The active chemical state of zinc (Zn) in a zinc-copper (Zn-Cu) catalyst during carbon dioxide/carbon monoxide (CO2/CO) hydrogenation has been debated to be Zn oxide (ZnO) nanoparticles, metallic Zn, or a Zn-Cu surface alloy. We used x-ray photoelectron spectroscopy at 180 to 500 millibar to probe the nature of Zn and reaction intermediates during CO2/CO hydrogenation over Zn/ZnO/Cu(211), where the temperature is sufficiently high for the reaction to rapidly turn over, thus creating an almost adsorbate-free surface. Tuning of the grazing incidence angle makes it possible to achieve either surface or bulk sensitivity. Hydrogenation of CO2 gives preference to ZnO in the form of clusters or nanoparticles, whereas in pure CO a surface Zn-Cu alloy becomes more prominent. The results reveal a specific role of CO in the formation of the Zn-Cu surface alloy as an active phase that facilitates efficient CO2 methanol synthesis.
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