Structural sensitivity of heterogeneous catalysts for sustainable chemical synthesis of gluconic acid from glucose

Yan, Wenjuan; Zhang, Dongpei; Sun, Yongjun; Zhou, Ziqi; Du, Yin; Du, Yiyao; Li, Yushan; Liu, Mengyuan; Zhang, Yuming; Shen, Jian; Jin, Xin

doi:10.1016/s1872-2067(20)63590-2

Cited by 26 publications

(15 citation statements)

References 105 publications

(179 reference statements)

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“…Catalytic application of the size-dependent SMSI. It is known that in many reactions the catalytic performance of supported gold catalysts is size dependent [26][27][28]52,53 . The usually uneven particle size distribution may give rise to different products thus lowering the selectivity.…”

Section: Resultsmentioning

confidence: 99%

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

et al. 2020

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The strong metal-support interaction (SMSI) has long been studied in heterogonous catalysis on account of its importance in stabilizing active metals and tuning catalytic performance. As a dynamic process taking place at the metal-support interface, the SMSI is closely related to the metal surface properties which are usually affected by the size of metal nanoparticles (NPs). In this work we report the discovery of a size effect on classical SMSI in Au/TiO2 catalyst where larger Au particles are more prone to be encapsulated than smaller ones. A thermodynamic equilibrium model was established to describe this phenomenon. According to this finding, the catalytic performance of Au/TiO2 catalyst with uneven size distribution can be improved by selectively encapsulating the large Au NPs in a hydrogenation reaction. This work not only brings in-depth understanding of the SMSI phenomenon and its formation mechanism, but also provides an alternative approach to refine catalyst performance.

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Section: Resultsmentioning

confidence: 99%

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

et al. 2020

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“…3c), which are consistent with the signals of the Au 0 and Au + species, respectively. 35 As shown in Table 1, compared with Au/C-CeO 2 and Au/O-CeO 2 , the Au/R-CeO 2 catalyst exhibits the largest percentage of Au + species (19.5%), indicating that R-CeO 2 has the strongest interaction with Au. The strong interaction between Au and R-CeO 2 leads to the electron transfer from Au 0 to Ce 4+ on the (110) plane, forming more Ce 3+ (as well as oxygen vacancies) and Au + in the Au/R-CeO 2 catalyst.…”

Section: Resultsmentioning

confidence: 93%

Effect of CeO₂ morphology on the catalytic properties of Au/CeO₂ for base-free glucose oxidation

Yao

et al. 2022

Catal. Sci. Technol.

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“…PtH À and H + generate H 2 which desorbs from Pt. Several studies [8,10,11,24,33] have posited that the mechanism of the oxidation (oxidative dehydrogenation) of D-glucose involves the liquid-phase oxidation of an aldehyde group, namely the terminal aldehyde group of glucose after ring opening. In other words, the traditional method of glucose conversion is not based on hemiacetal chemistry.…”

Section: Resultsmentioning

confidence: 99%

“…The catalytic oxidation of glucose to gluconic acid and its salts (GNA), which are important chemical substances that exhibit good biodegradability and biocompatibility, is performed using H 2 O 2 or O 2 as an oxidizing agent (Scheme 1a). [8] In comparison, the catalytic dehydrogenation of glucose to GNA and H 2 , two high-value-added products, is performed under milder conditions and achieves better atom economy. [9,10] In the acceptorless dehydrogenation reaction (Scheme 1b) developed by Mata et al [10,11] Iridium (III) complexes were used as catalysts to convert glucose into GNA and H 2 .…”

Section: Introductionmentioning

confidence: 99%

Low‐energy Hemiacetal Dehydrogenation Pathway: Co‐production of Gluconic Acid and Green Hydrogen via Glucose Dehydrogenation

Liu

Niu

et al. 2022

Chemistry An Asian Journal

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Exploring low‐energy reaction pathway of catalytic biomass conversion can lead to wider application and the achievement of sustainability objectives. Since glucose dehydrogenation to gluconic acid and H2 is a cost‐effective alternative to glucose oxidation, this study aims to elucidate its mechanism. The detection of lactone as an intermediate indicates that cyclic glucose reacts directly via its hemiacetal group–ring opening is not involved; that is, cyclic glucose is dehydrogenated to lactone, which is further hydrolyzed to gluconic acid. The source of hydrogen is confirmed to be from glucose and water by Isotope tracing analysis. Density function theory calculations demonstrate that Hemiacetal Dehydrogenation Pathway (this work) is less energy intensive than Ring‐opening Oxidation Pathway (previous works). This study provides a new dehydrogenation strategy to produce gluconic acid and H2 from biomass under mild conditions.

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Structural sensitivity of heterogeneous catalysts for sustainable chemical synthesis of gluconic acid from glucose

Cited by 26 publications

References 105 publications

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

Effect of CeO₂ morphology on the catalytic properties of Au/CeO₂ for base-free glucose oxidation

Low‐energy Hemiacetal Dehydrogenation Pathway: Co‐production of Gluconic Acid and Green Hydrogen via Glucose Dehydrogenation

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Structural sensitivity of heterogeneous catalysts for sustainable chemical synthesis of gluconic acid from glucose

Cited by 26 publications

References 105 publications

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

Size-dependent strong metal-support interaction in TiO2 supported Au nanocatalysts

Effect of CeO2 morphology on the catalytic properties of Au/CeO2 for base-free glucose oxidation

Low‐energy Hemiacetal Dehydrogenation Pathway: Co‐production of Gluconic Acid and Green Hydrogen via Glucose Dehydrogenation

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Effect of CeO₂ morphology on the catalytic properties of Au/CeO₂ for base-free glucose oxidation