Your search keyword '"Eckelt, Reinhard"' showing total 7 results

1. In situ formation of ZnO.sub.x species for efficient propane dehydrogenation

Author

Zhao, Dan, Tian, Xinxin, Doronkin, Dmitry E., Han, Shanlei, Kondratenko, Vita A., Grunwaldt, Jan-Dierk, Perechodjuk, Anna, Vuong, Thanh Huyen, Rabeah, Jabor, Eckelt, Reinhard, Rodemerck, Uwe, Linke, David, Jiang, Guiyuan, Jiao, Haijun, and Kondratenko, Evgenii V.

Subjects

Chemical properties, Methods, Propane -- Chemical properties, Dehydrogenation -- Methods, Zinc oxide -- Chemical properties

Abstract

Author(s): Dan Zhao [sup.1] [sup.2] , Xinxin Tian [sup.2] [sup.3] , Dmitry E. Doronkin [sup.4] , Shanlei Han [sup.1] [sup.2] , Vita A. Kondratenko [sup.2] , Jan-Dierk Grunwaldt [sup.4] , [...], Propane dehydrogenation (PDH) to propene is an important alternative to oil-based cracking processes, to produce this industrially important platform chemical.sup.1,2. The commercial PDH technologies utilizing Cr-containing (refs. .sup.3,4) or Pt-containing (refs. .sup.5-8) catalysts suffer from the toxicity of Cr(vi) compounds or the need to use ecologically harmful chlorine for catalyst regeneration.sup.9. Here, we introduce a method for preparation of environmentally compatible supported catalysts based on commercial ZnO. This metal oxide and a support (zeolite or common metal oxide) are used as a physical mixture or in the form of two layers with ZnO as the upstream layer. Supported ZnO.sub.x species are in situ formed through a reaction of support OH groups with Zn atoms generated from ZnO upon reductive treatment above 550 °C. Using different complementary characterization methods, we identify the decisive role of defective OH groups for the formation of active ZnO.sub.x species. For benchmarking purposes, the developed ZnO-silicalite-1 and an analogue of commercial K-CrO.sub.x/Al.sub.2O.sub.3 were tested in the same setup under industrially relevant conditions at close propane conversion over about 400 h on propane stream. The developed catalyst reveals about three times higher propene productivity at similar propene selectivity. Propene is obtained through propane dehydrogenation using catalysts that are toxic, expensive or demanding to regenerate with ecologically harmful compounds, but the ZnO-based alternative reported here is cheap, clean and scalable.

Published

2021

2. Author Correction: In situ formation of ZnOx species for efficient propane dehydrogenation

Author

Zhao, Dan, primary, Tian, Xinxin, additional, Doronkin, Dmitry E., additional, Han, Shanlei, additional, Kondratenko, Vita A., additional, Grunwaldt, Jan-Dierk, additional, Perechodjuk, Anna, additional, Vuong, Thanh Huyen, additional, Rabeah, Jabor, additional, Eckelt, Reinhard, additional, Rodemerck, Uwe, additional, Linke, David, additional, Jiang, Guiyuan, additional, Jiao, Haijun, additional, and Kondratenko, Evgenii V., additional

Published

2022

3. In situ formation of ZnOx species for efficient propane dehydrogenation.

Author

Zhao, Dan, Tian, Xinxin, Doronkin, Dmitry E., Han, Shanlei, Kondratenko, Vita A., Grunwaldt, Jan-Dierk, Perechodjuk, Anna, Vuong, Thanh Huyen, Rabeah, Jabor, Eckelt, Reinhard, Rodemerck, Uwe, Linke, David, Jiang, Guiyuan, Jiao, Haijun, and Kondratenko, Evgenii V.

Abstract

Propane dehydrogenation (PDH) to propene is an important alternative to oil-based cracking processes, to produce this industrially important platform chemical1,2. The commercial PDH technologies utilizing Cr-containing (refs. 3,4) or Pt-containing (refs. 5–8) catalysts suffer from the toxicity of Cr(vi) compounds or the need to use ecologically harmful chlorine for catalyst regeneration9. Here, we introduce a method for preparation of environmentally compatible supported catalysts based on commercial ZnO. This metal oxide and a support (zeolite or common metal oxide) are used as a physical mixture or in the form of two layers with ZnO as the upstream layer. Supported ZnOx species are in situ formed through a reaction of support OH groups with Zn atoms generated from ZnO upon reductive treatment above 550 °C. Using different complementary characterization methods, we identify the decisive role of defective OH groups for the formation of active ZnOx species. For benchmarking purposes, the developed ZnO–silicalite-1 and an analogue of commercial K–CrOx/Al2O3 were tested in the same setup under industrially relevant conditions at close propane conversion over about 400 h on propane stream. The developed catalyst reveals about three times higher propene productivity at similar propene selectivity.Propene is obtained through propane dehydrogenation using catalysts that are toxic, expensive or demanding to regenerate with ecologically harmful compounds, but the ZnO-based alternative reported here is cheap, clean and scalable. [ABSTRACT FROM AUTHOR]

Published

2021

4. In situ formation of ZnOxspecies for efficient propane dehydrogenation

Author

Zhao, Dan, Tian, Xinxin, Doronkin, Dmitry E., Han, Shanlei, Kondratenko, Vita A., Grunwaldt, Jan-Dierk, Perechodjuk, Anna, Vuong, Thanh Huyen, Rabeah, Jabor, Eckelt, Reinhard, Rodemerck, Uwe, Linke, David, Jiang, Guiyuan, Jiao, Haijun, and Kondratenko, Evgenii V.

Abstract

Propane dehydrogenation (PDH) to propene is an important alternative to oil-based cracking processes, to produce this industrially important platform chemical1,2. The commercial PDH technologies utilizing Cr-containing (refs. 3,4) or Pt-containing (refs. 5–8) catalysts suffer from the toxicity of Cr(vi) compounds or the need to use ecologically harmful chlorine for catalyst regeneration9. Here, we introduce a method for preparation of environmentally compatible supported catalysts based on commercial ZnO. This metal oxide and a support (zeolite or common metal oxide) are used as a physical mixture or in the form of two layers with ZnO as the upstream layer. Supported ZnOxspecies are in situ formed through a reaction of support OH groups with Zn atoms generated from ZnO upon reductive treatment above 550 °C. Using different complementary characterization methods, we identify the decisive role of defective OH groups for the formation of active ZnOxspecies. For benchmarking purposes, the developed ZnO–silicalite-1 and an analogue of commercial K–CrOx/Al2O3were tested in the same setup under industrially relevant conditions at close propane conversion over about 400 h on propane stream. The developed catalyst reveals about three times higher propene productivity at similar propene selectivity.

Published

2021

5. Author Correction: In situ formation of ZnOx species for efficient propane dehydrogenation.

Author

Zhao, Dan, Tian, Xinxin, Doronkin, Dmitry E., Han, Shanlei, Kondratenko, Vita A., Grunwaldt, Jan-Dierk, Perechodjuk, Anna, Vuong, Thanh Huyen, Rabeah, Jabor, Eckelt, Reinhard, Rodemerck, Uwe, Linke, David, Jiang, Guiyuan, Jiao, Haijun, and Kondratenko, Evgenii V.

Published

2022

6. Author Correction: In situ formation of ZnOxspecies for efficient propane dehydrogenation

Author

Zhao, Dan, Tian, Xinxin, Doronkin, Dmitry E., Han, Shanlei, Kondratenko, Vita A., Grunwaldt, Jan-Dierk, Perechodjuk, Anna, Vuong, Thanh Huyen, Rabeah, Jabor, Eckelt, Reinhard, Rodemerck, Uwe, Linke, David, Jiang, Guiyuan, Jiao, Haijun, and Kondratenko, Evgenii V.

Published

2022

7. Author Correction: In situ formation of ZnO x species for efficient propane dehydrogenation.

Author

Zhao D, Tian X, Doronkin DE, Han S, Kondratenko VA, Grunwaldt JD, Perechodjuk A, Vuong TH, Rabeah J, Eckelt R, Rodemerck U, Linke D, Jiang G, Jiao H, and Kondratenko EV

Published

2022