Propane Dehydrogenation on Ga₂O₃-Based Catalysts: Contrasting Performance with Coordination Environment and Acidity of Surface Sites

Abstract: α-Ga2O3, β-Ga2O3, and γ-Ga2O3 as well as the silica-supported catalysts γ-Ga2O3/SiO2, β-Ga2O3/SiO2, and Ga­(NO3)3-derived Ga/SiO2 were prepared, characterized, and evaluated for propane dehydrogenation (PDH) at 550 °C. The coordination environment and acidity of surface sites in stand-alone and SiO2-supported Ga2O3 catalysts were studied using FTIR, 15N dynamic nuclear polarization surface-enhanced NMR spectroscopy (15N DNP SENS), and DFT modeling of the adsorbed pyridine probe molecule. The spectroscopic data… Show more

“…However, this system undergoes rapid deactivation likely due to the reduction of Ga 2 O 3 . [6][7][8][9][10][11][12] While Ga 2 O 3 -based materials readily deactivate and cannot be used on industrial scales for PDH, the corresponding Gazeotype catalysts are used to convert propane into aromatics in the commercial Cyclar© process; this process is proposed to also involve propane dehydrogenation as a key step on isolated Ga sites before the further conversion of propene to aromatics on acid sites. [13 -16] These unique catalytic properties have led to the synthesis of isolated Ga sites at the surface of non-reducible bulk materials such as silica to generate stable propane dehydrogenation catalysts.…”

“…Ga 2 O 3 is one metal oxide that has received significant interest due to its promising initial activity and selectivity in alkane dehydrogenation. However, this system undergoes rapid deactivation likely due to the reduction of Ga 2 O 3 [6–12] . While Ga 2 O 3 ‐based materials readily deactivate and cannot be used on industrial scales for PDH, the corresponding Ga‐zeotype catalysts are used to convert propane into aromatics in the commercial Cyclar © process; this process is proposed to also involve propane dehydrogenation as a key step on isolated Ga sites before the further conversion of propene to aromatics on acid sites [13–16] .…”

A Molecular Analogue of the C−H Activation Intermediate of the Silica‐Supported Ga(III) Single‐Site Propane Dehydrogenation Catalyst: Structure and XANES Signature

“…However, this system undergoes rapid deactivation likely due to the reduction of Ga 2 O 3 . [6][7][8][9][10][11][12] While Ga 2 O 3 -based materials readily deactivate and cannot be used on industrial scales for PDH, the corresponding Gazeotype catalysts are used to convert propane into aromatics in the commercial Cyclar© process; this process is proposed to also involve propane dehydrogenation as a key step on isolated Ga sites before the further conversion of propene to aromatics on acid sites. [13 -16] These unique catalytic properties have led to the synthesis of isolated Ga sites at the surface of non-reducible bulk materials such as silica to generate stable propane dehydrogenation catalysts.…”

“…Ga 2 O 3 is one metal oxide that has received significant interest due to its promising initial activity and selectivity in alkane dehydrogenation. However, this system undergoes rapid deactivation likely due to the reduction of Ga 2 O 3 [6–12] . While Ga 2 O 3 ‐based materials readily deactivate and cannot be used on industrial scales for PDH, the corresponding Ga‐zeotype catalysts are used to convert propane into aromatics in the commercial Cyclar © process; this process is proposed to also involve propane dehydrogenation as a key step on isolated Ga sites before the further conversion of propene to aromatics on acid sites [13–16] .…”

A Molecular Analogue of the C−H Activation Intermediate of the Silica‐Supported Ga(III) Single‐Site Propane Dehydrogenation Catalyst: Structure and XANES Signature

“…(B) A possible coordination geometry for a Ga IV -O-Ga VI surface linkage with the attribution of Lewis acidity strength according to the 15 N chemical shift of bound pyridine probe molecule. 12 SP stands for square pyramidal.…”

“…13 PDH and cracking reactions proceed on different sites in Ga 2 O 3 catalysts since the rate of propene formation and propene selectivity decrease with time on stream (TOS) but the selectivity to cracking products and their rate of formation is stable with TOS. 12 One strategy to control the distribution of bulk Ga IV and Ga VI sites, and thereby presumably also inuence the coordination environment of surface Ga sites, is to exploit (Ga,Al) 2 O 3 spineltype solid solutions as alkane dehydrogenation catalysts. 6,9,14 In these materials, the bulk Ga IV : Ga VI ratio can be varied since Al atoms preferentially occupy octahedral positions in the defect spinel-type structure of Ga 2 O 3 , 15 increasing thereby the relative fraction of Ga IV sites (i.e., the proposed active sites).…”

“…9 The reduced deactivation and increased activity might be related to the higher relative fraction of weak LAS in (Ga,Al) 2 O 3 (as assessed by NH 3 -TPD) and linked to a higher relative density of undercoordinated Ga sites, such as putative Ga III sites discussed above. 9,12 Note that the alkane dehydrogenation activity of various phases of Al 2 O 3 (a-, d-, g-, q-) is generally low and requires a pre-treatment with CO or H 2 at high temperature (600 C) to become considerable. 16,17 Due to their limited activity, Al 2 O 3 catalysts are typically tested in PDH at substantially higher temperatures (600-630 C) relative to Ga 2 O 3 catalysts (550 C).…”

Uncovering selective and active Ga surface sites in gallia–alumina mixed-oxide propane dehydrogenation catalysts by dynamic nuclear polarization surface enhanced NMR spectroscopy

Impact of Heteroatom Speciation on the Activity and Stability of Carbon‐Based Catalysts for Propane Dehydrogenation