Elucidating the Nature of Active Sites and Fundamentals for their Creation in Zn-Containing ZrO<sub>2</sub>–Based Catalysts for Nonoxidative Propane Dehydrogenation

Han, Shanlei; Zhao, Dan; Otroshchenko, Tatiana; Lund, Henrik; Bentrup, Ursula; Kondratenko, Vita A.; Rockstroh, Nils; Bartling, Stephan; Doronkin, Dmitry E.; Grunwaldt, Jan‐Dierk; Rodemerck, Uwe; Linke, David; Gao, Manglai; Jiang, Guiyuan; Kondratenko, Evgenii V.

doi:10.1021/acscatal.0c01580

Cited by 69 publications

(82 citation statements)

References 72 publications

(168 reference statements)

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“…15,16 ). Zn-containing catalysts were also tested but show commercially unattractive performance [17][18][19][20][21][22][23][24][25][26][27] . A general shortcoming of practically all supported catalysts developed until now is their economic inefficiency due to the complex preparation methods often requiring expensive chemicals.…”

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confidence: 99%

In situ formation of ZnOx species for efficient propane dehydrogenation

Zhao

Tian

Doronkin

et al. 2021

Nature

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143

168

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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.

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confidence: 99%

In situ formation of ZnOx species for efficient propane dehydrogenation

Zhao

Tian

Doronkin

et al. 2021

Nature

Self Cite

143

168

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“…6 Metal oxide catalysts, including gallium, cobalt, aluminum and zinc oxide-based catalysts, are currently researched actively for the selective dehydrogenation of propane to propene. 2,[7][8][9][10][11][12][13] The metal sites on the surface of these oxides can exhibit different coordination environments and undergo changes in the oxidation state during the PDH reaction, which affect their catalytic performance. This has driven considerable research efforts to understand the active sites at the atomic level.…”

Section: Introductionmentioning

confidence: 99%

Correlating the Structural Evolution of ZnO/Al₂O₃ to Spinel Zinc Aluminate with its Catalytic Performance in Propane Dehydrogenation

et al. 2021

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Zn-based Al2O3-suported materials have been proposed as inexpensive and environmentally friendly catalysts for the direct dehydrogenation of propane (PDH), however, our understanding of these catalysts' structure and deactivation routes is still limited. Here, we correlate the catalytic activity for PDH of a series of Zn-based Al2O3 catalysts with their structure and structural evolution. To this end, three model catalysts are investigated. (i) ZnO/Al2O3 prepared by atomic layer deposition (ALD) of ZnO onto γ-Al2O3 followed by calcination at 700 °C, which yields a core-shell spinel zinc aluminate/γ-Al2O3 structure. (ii) Zinc aluminate spinel nanoparticles (ZnxAlyO4 NPs) prepared via a hydrothermal method. (iii) A reference core-shell ZnO/SiO2 catalyst prepared by ALD of ZnO on SiO2. The catalysts are characterized in detail by synchrotron X-ray powder diffraction (XRD), Zn K-edge X-ray absorption spectroscopy (XAS), and 27 Al solid state nuclear magnetic resonance (ssNMR). These experiments allowed us to identify tetrahedral Zn sites in close proximity to Al sites of a zinc aluminate spinel phase (ZnIV-O-AlIV/VI linkages) as notably more active and selective in PDH relative to the supported ZnO wurtzite phase (ZnIV-O-ZnIV linkages) in ZnO/SiO2. The best performing catalyst, 50ZnO/Al2O3 gives 77% selectivity to propene (gaseous products based) at 9 mmol C3H6 gcat −1 h −1 space time yield (STY) after 3 min of reaction at 600 °C. On the other hand, the core-shell ZnO/Al2O3 catalyst shows an irreversible loss of activity over repeated PDH and air-regeneration cycles, explained by Zn depletion on the surface due to its diffusion into subsurface layers or the bulk. ZnxAlyO4 NPs gave a comparable initial selectivity and catalytic activity as 50ZnO/Al2O3. With time on stream, ZnxAlyO4 NPs deactivate due to the formation of coke at the catalyst surface, yet the extend of coke deposition is lower than for the ZnO/Al2O3 catalysts, and the activity of ZnxAlyO4 NPs can be regenerated almost fully using calcination in air.

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“…In contrast, the non‐oxidative propane dehydrogenation with noble‐metal catalyst like PtSn x gives the conversion of ≈50 % and the propylene selectivity of ≈90 % at ≈600 °C [8–13] . However, operation with non‐noble‐metal catalyst like VO X /Al 2 O 3 and VO X /ZrO 2 leads to a conversion below ≈25 % and a propene selectivity below ≈90 % even at ≈600 °C, while it suffers from serious coke deposition and conversion drop in dozens of minutes [14–17] . For non‐noble metal catalyst, the lack of catalytic activity gives rise to a limited propane conversion at reduced temperatures while the complicated functional groups at surfaces distract the main reaction to generate by‐products including methane, ethane and coke [18] .…”

Section: Figurementioning

confidence: 99%

“…[8][9][10][11][12][13] However, operation with non-noble-metal catalyst like VO X /Al 2 O 3 and VO X /ZrO 2 leads to a conversion below % 25 % and a propene selectivity below % 90 % even at % 600 8C, while it suffers from serious coke deposition and conversion drop in dozens of minutes. [14][15][16][17] For non-noble metal catalyst, the lack of catalytic activity gives rise to a limited propane conversion at reduced temperatures while the complicated functional groups at surfaces distract the main reaction to generate byproducts including methane, ethane and coke. [18] The high density of weak Lewis acid sites on the surface of catalyst is beneficial for the propane dehydrogenation reaction and could suppress the cracking reaction to avoid carbon deposition.…”

mentioning

confidence: 99%

High‐Density Lewis Acid Sites in Porous Single‐Crystalline Monoliths to Enhance Propane Dehydrogenation at Reduced Temperatures

Lin

Duan

et al. 2021

Angew Chem Int Ed

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The non‐oxidative dehydrogenation of propane to propylene plays an important role in the light‐olefin chemical industry. However, the conversion and selectivity remain a fundamental challenge at low temperatures. Here we create and engineer high‐density Lewis acid sites at well‐defined surfaces in porous single‐crystalline Mo2N and MoN monoliths to enhance the non‐oxidative dehydrogenation of propane to propylene. The top‐layer Mo ions with unsaturated Mo‐N1/6 and Mo‐N1/3 coordination structures provide high‐density Lewis acid sites at the surface, leading to the effective activation of C−H bonds without the overcracking of C−C bonds during the non‐oxidative dehydrogenation of propane. We demonstrate a propane conversion of ≈11 % and a propylene selectivity of ≈95 % with porous single‐crystalline Mo2N and MoN monoliths at 500 °C.

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Elucidating the Nature of Active Sites and Fundamentals for their Creation in Zn-Containing ZrO₂–Based Catalysts for Nonoxidative Propane Dehydrogenation

Cited by 69 publications

References 72 publications

In situ formation of ZnOx species for efficient propane dehydrogenation

In situ formation of ZnOx species for efficient propane dehydrogenation

Correlating the Structural Evolution of ZnO/Al₂O₃ to Spinel Zinc Aluminate with its Catalytic Performance in Propane Dehydrogenation

High‐Density Lewis Acid Sites in Porous Single‐Crystalline Monoliths to Enhance Propane Dehydrogenation at Reduced Temperatures

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Elucidating the Nature of Active Sites and Fundamentals for their Creation in Zn-Containing ZrO2–Based Catalysts for Nonoxidative Propane Dehydrogenation

Cited by 69 publications

References 72 publications

In situ formation of ZnOx species for efficient propane dehydrogenation

In situ formation of ZnOx species for efficient propane dehydrogenation

Correlating the Structural Evolution of ZnO/Al2O3 to Spinel Zinc Aluminate with its Catalytic Performance in Propane Dehydrogenation

High‐Density Lewis Acid Sites in Porous Single‐Crystalline Monoliths to Enhance Propane Dehydrogenation at Reduced Temperatures

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Elucidating the Nature of Active Sites and Fundamentals for their Creation in Zn-Containing ZrO₂–Based Catalysts for Nonoxidative Propane Dehydrogenation

Correlating the Structural Evolution of ZnO/Al₂O₃ to Spinel Zinc Aluminate with its Catalytic Performance in Propane Dehydrogenation