The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation

Standard

The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation. / Bukharbayeva, Farida; Zharmagambetova, Alima; Talgatov, Eldar; Auyezkhanova, Assemgul; Akhmetova, Sandugash; Jumekeyeva, Aigul; Naizabayev, Akzhol; Kenzheyeva, Alima; Данилов, Денис Васильевич.

In: Molecules, Vol. 29, No. 19, 4584, 26.09.2024.

Research output: Contribution to journal › Article › peer-review

Harvard

Bukharbayeva, F, Zharmagambetova, A, Talgatov, E, Auyezkhanova, A, Akhmetova, S, Jumekeyeva, A, Naizabayev, A, Kenzheyeva, A & Данилов, ДВ 2024, 'The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation', Molecules, vol. 29, no. 19, 4584. https://doi.org/10.3390/molecules29194584

APA

Bukharbayeva, F., Zharmagambetova, A., Talgatov, E., Auyezkhanova, A., Akhmetova, S., Jumekeyeva, A., Naizabayev, A., Kenzheyeva, A., & Данилов, Д. В. (2024). The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation. Molecules, 29(19), [4584]. https://doi.org/10.3390/molecules29194584

Vancouver

Bukharbayeva F, Zharmagambetova A, Talgatov E, Auyezkhanova A, Akhmetova S, Jumekeyeva A et al. The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation. Molecules. 2024 Sep 26;29(19). 4584. https://doi.org/10.3390/molecules29194584

Author

Bukharbayeva, Farida ; Zharmagambetova, Alima ; Talgatov, Eldar ; Auyezkhanova, Assemgul ; Akhmetova, Sandugash ; Jumekeyeva, Aigul ; Naizabayev, Akzhol ; Kenzheyeva, Alima ; Данилов, Денис Васильевич. / The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation. In: Molecules. 2024 ; Vol. 29, No. 19.

BibTeX

@article{be31df9040914540baccfe3ea773d512,

title = "The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation",

abstract = "The proposed paper describes a simple and environmentally friendly method for the synthesis of three-component polymer-inorganic composites, which includes the modification of zinc oxide or montmorillonite (MMT) with chitosan (CS), followed by the immobilization of palladium on the resulting two-component composites. The structures and properties of the obtained composites were characterized by physicochemical methods (IRS, TEM, XPS, SEM, EDX, XRD, BET). Pd-CS species covered the surface of inorganic materials through two different mechanisms. The interaction of chitosan polyelectrolyte with zinc oxide led to the deprotonation of its amino groups and deposition on the surface of ZnO. The immobilization of Pd on CS/ZnO occurred by the hydrolysis of [PdCl 4] 2-, followed by forming PdO particles by interacting with amino groups of chitosan. In the case of CS/MMT, protonated amino groups of CS interacted with negative sites of MMT, forming a positively charged CS/MMT composite. Furthermore, [PdCl 4] 2- interacted with the -NH 3+ sites of CS/MMT through electrostatic force. According to TEM studies of 1%Pd-CS/ZnO, the presence of Pd nanoclusters composed of smaller Pd nanoparticles of 3-4 nm in size were observed on different sites of CS/ZnO. For 1%Pd-CS/MMT, Pd nanoparticles with sizes of 2 nm were evenly distributed on the support surface. The prepared three-component CS-inorganic composites were tested through the hydrogenation of 2-propen-1-ol and acetylene compounds (phenylacetylene, 2-hexyn-1-ol) under mild conditions (T-40 °C, P H2-1 atm). It was shown that the efficiency of 1%Pd-CS/MMT is higher than that of 1%Pd-CS/ZnO, which can be explained by the formation of smaller Pd particles that are evenly distributed on the support surface. The mechanism of 2-hexyn-1-ol hydrogenation over an optimal 1%Pd-CS/MMT catalyst was proposed. ",

keywords = "chitosan, composite, montmorillonite, palladium catalysts, polysaccharide",

author = "Farida Bukharbayeva and Alima Zharmagambetova and Eldar Talgatov and Assemgul Auyezkhanova and Sandugash Akhmetova and Aigul Jumekeyeva and Akzhol Naizabayev and Alima Kenzheyeva and Данилов, {Денис Васильевич}",

year = "2024",

month = sep,

day = "26",

doi = "10.3390/molecules29194584",

language = "English",

volume = "29",

journal = "Molecules",

issn = "1420-3049",

publisher = "MDPI AG",

number = "19",

}

RIS

TY - JOUR

T1 - The Synthesis of Green Palladium Catalysts Stabilized by Chitosan for Hydrogenation

AU - Bukharbayeva, Farida

AU - Zharmagambetova, Alima

AU - Talgatov, Eldar

AU - Auyezkhanova, Assemgul

AU - Akhmetova, Sandugash

AU - Jumekeyeva, Aigul

AU - Naizabayev, Akzhol

AU - Kenzheyeva, Alima

AU - Данилов, Денис Васильевич

PY - 2024/9/26

Y1 - 2024/9/26

N2 - The proposed paper describes a simple and environmentally friendly method for the synthesis of three-component polymer-inorganic composites, which includes the modification of zinc oxide or montmorillonite (MMT) with chitosan (CS), followed by the immobilization of palladium on the resulting two-component composites. The structures and properties of the obtained composites were characterized by physicochemical methods (IRS, TEM, XPS, SEM, EDX, XRD, BET). Pd-CS species covered the surface of inorganic materials through two different mechanisms. The interaction of chitosan polyelectrolyte with zinc oxide led to the deprotonation of its amino groups and deposition on the surface of ZnO. The immobilization of Pd on CS/ZnO occurred by the hydrolysis of [PdCl 4] 2-, followed by forming PdO particles by interacting with amino groups of chitosan. In the case of CS/MMT, protonated amino groups of CS interacted with negative sites of MMT, forming a positively charged CS/MMT composite. Furthermore, [PdCl 4] 2- interacted with the -NH 3+ sites of CS/MMT through electrostatic force. According to TEM studies of 1%Pd-CS/ZnO, the presence of Pd nanoclusters composed of smaller Pd nanoparticles of 3-4 nm in size were observed on different sites of CS/ZnO. For 1%Pd-CS/MMT, Pd nanoparticles with sizes of 2 nm were evenly distributed on the support surface. The prepared three-component CS-inorganic composites were tested through the hydrogenation of 2-propen-1-ol and acetylene compounds (phenylacetylene, 2-hexyn-1-ol) under mild conditions (T-40 °C, P H2-1 atm). It was shown that the efficiency of 1%Pd-CS/MMT is higher than that of 1%Pd-CS/ZnO, which can be explained by the formation of smaller Pd particles that are evenly distributed on the support surface. The mechanism of 2-hexyn-1-ol hydrogenation over an optimal 1%Pd-CS/MMT catalyst was proposed.

AB - The proposed paper describes a simple and environmentally friendly method for the synthesis of three-component polymer-inorganic composites, which includes the modification of zinc oxide or montmorillonite (MMT) with chitosan (CS), followed by the immobilization of palladium on the resulting two-component composites. The structures and properties of the obtained composites were characterized by physicochemical methods (IRS, TEM, XPS, SEM, EDX, XRD, BET). Pd-CS species covered the surface of inorganic materials through two different mechanisms. The interaction of chitosan polyelectrolyte with zinc oxide led to the deprotonation of its amino groups and deposition on the surface of ZnO. The immobilization of Pd on CS/ZnO occurred by the hydrolysis of [PdCl 4] 2-, followed by forming PdO particles by interacting with amino groups of chitosan. In the case of CS/MMT, protonated amino groups of CS interacted with negative sites of MMT, forming a positively charged CS/MMT composite. Furthermore, [PdCl 4] 2- interacted with the -NH 3+ sites of CS/MMT through electrostatic force. According to TEM studies of 1%Pd-CS/ZnO, the presence of Pd nanoclusters composed of smaller Pd nanoparticles of 3-4 nm in size were observed on different sites of CS/ZnO. For 1%Pd-CS/MMT, Pd nanoparticles with sizes of 2 nm were evenly distributed on the support surface. The prepared three-component CS-inorganic composites were tested through the hydrogenation of 2-propen-1-ol and acetylene compounds (phenylacetylene, 2-hexyn-1-ol) under mild conditions (T-40 °C, P H2-1 atm). It was shown that the efficiency of 1%Pd-CS/MMT is higher than that of 1%Pd-CS/ZnO, which can be explained by the formation of smaller Pd particles that are evenly distributed on the support surface. The mechanism of 2-hexyn-1-ol hydrogenation over an optimal 1%Pd-CS/MMT catalyst was proposed.

KW - chitosan

KW - composite

KW - montmorillonite

KW - palladium catalysts

KW - polysaccharide

UR - https://www.mendeley.com/catalogue/e6703e40-a448-310a-a052-60a3bb449ed9/

U2 - 10.3390/molecules29194584

DO - 10.3390/molecules29194584

M3 - Article

C2 - 39407514

VL - 29

JO - Molecules

JF - Molecules

SN - 1420-3049

IS - 19

M1 - 4584

ER -

ID: 126391912