Synthesis, Characterization and Applications in Catalysis of Polyoxometalate/Zeolite Composites

Lefèbvre, F.

doi:10.3390/inorganics4020013

Cited by 17 publications

(9 citation statements)

References 71 publications

(132 reference statements)

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“…Recently, we found that carbon-supported H 3 PW 12 O 40 could be used as a catalyst in the conversion of D,L-lactic acid to enantioselective blends of PLA [16]. Keggin heteropolyacid (HPA) is an important class of solid acids among which 12-tungstophosphoric acid (H 3 PW 12 O 40 , H 3 PW) is particularly important because it can be used in acid catalysis for greener processes [17, 18, 19, 20, 21]. It has been shown that the H 3 PW/C catalyst is an alternative for use in such reactions involving an inexpensive monomer of D,L-lactic acid.…”

Section: Introductionmentioning

confidence: 99%

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Chafran

Paiva

França

et al. 2019

Heliyon

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Poly(lactic acid) (PLA) is a significant polymer that is based on renewable biomass resources. The production of PLA by polycondensation using heterogeneous catalysis is a focus for sustainable and economical processes. A series of samples comprising 12-tungstophosphoric acid (H 3 PW) supported on activated carbon, silica, and alumina induced the catalytic polymerization of D,L-lactic acid to form blends of PLA. The catalysts were characterized by multiple techniques to confirm the integrity of the Keggin anion as well as the acidity, which is the key property for relating structure to activity. The best reaction conditions were established for H 3 PW/C and tested for the other supported catalysts. The obtained polymer was a blend that was characterized as an enantiomeric excess (ee) of as much as 95% L-PLA (PLLA) with a mass average molar mass ( M w ) of approximately 14,900 daltons. The role of H 3 PW in these polymerizations was demonstrated, i.e., without the Keggin acid, only oligomeric units ( M w < 10,000 daltons) could be obtained. Additionally, inverse relationships between the M w of PLA and the enthalpy (–Δ H ) of the strongest sites of the catalysts were distinguished, i.e., PLA Mw-H3PW/C > PLA Mw-H3PW/Al2O3 > PLA Mw-H3PW/SiO2 , whereas the acidity (–Δ H ) order was as follows: H 3 PW/SiO 2 > H 3 PW/Al 2 O 3 > H 3 PW/C. These findings could be attributed to the correct tuning of strength and the accessibility of the sites to produce longer polymeric chains.

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Section: Introductionmentioning

confidence: 99%

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Chafran

Paiva

França

et al. 2019

Heliyon

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“…25,26 Due to their high solubility, low surface area, and instability under reaction conditions, the processability of POMs alone is often poor. 5 To overcome these undesirable properties, significant efforts have been made to heterogenize POMs on a variety of supports, including mesoporous silica, 27,28 high surface area carbon, 29,30 zeolites, 31 polymers, 32 metal−organic macrocycles, 33 covalent−organic frameworks, 34 and metal−organic frameworks (MOFs), among others. 35 Unlike conventional supports, MOFs offer a highly tunable, crystalline scaffold for anchoring small to large molecules.…”

Section: ■ Introductionmentioning

confidence: 99%

Strategies for Incorporating Catalytically Active Polyoxometalates in Metal–Organic Frameworks for Organic Transformations

Buru

Farha

2020

ACS Appl. Mater. Interfaces

116

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Polyoxometalates (POMs) can benefit from immobilization on solid supports to overcome their difficulty in processability and stability. Among the reported solid supports, metal–organic frameworks (MOFs) offer a crystalline, versatile platform for depositing highly active POMs. The combination of these structures can at times benefit from the combined reactivity of both the POM and MOF, sometimes synergistically, to improve catalysis while balancing desirable properties like porosity, substrate diffusion, or stability. In this Review, we survey the strategies for immobilizing POMs within MOF structures, with an emphasis on how physical and catalytic properties of the parent materials are affected in the composite when employed in organic transformations.

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“…Polyoxometalates (POMs) as soluble anionic metal oxide clusters of d-block transition metals in high oxidation states, typically W(VI), Mo(V,VI) or V(IV,V), exhibit redox and acid-base properties and are particularly exploited in catalysis, either in homogeneous conditions 1,2 or immobilized in solid supports. [3][4][5][6] In the hot field of solar energy conversion, although numerous studies have revealed their potentialities as catalysts for water splitting, [7][8][9][10] there have been scarce reports on POMs for CO2RR. 11,12 Besides rare examples of transition metal (M)-substituted polyoxotungstates, [13][14][15][16] reduced polyoxomolybdates (i.e.…”

Section: Introductionmentioning

confidence: 99%

Understanding the Photocatalytic Reduction of CO₂with Heterometallic Molybdenum(V) Phosphate Polyoxometalates in Aqueous Media

et al. 2021

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Three crystalline heterometallic molybdenum(V) phosphates have been synthesized under hydrothermal conditions. They all contain {M[P4Mo6O28(OH)3]2} 16-(M = Mn(II) or Co(II)) polyoxometalate (POM) units, with the M ions sandwiched between two {P4Mo V 6} rings. In the presence of Fe(II) ions in the reaction medium, a 3D Fe-Mn compound built from the connection of Mn(P4Mo6)2 units to Fe(II) and Fe(III) centers by extra phosphate ions is obtained. Alternatively, the introduction of [Ru(bpy)3] 2+ complexes in the synthetic medium prevents the formation of such high dimensional compounds. In the two Ru(bpy)-Mn and Ru(bpy)-Co hybrids, chains are indeed formed whereby the Mn(P4Mo6)2 or Co(P4Mo6)2 anions are bridged by Mn(II) or Co(II) ions, respectively. The charge of these anionic chains is compensated by neighboring [Ru(bpy)3] 2+ complexes. Among these three compounds, only Fe-Mn and Ru(bpy)-Mn act as heterogeneous catalysts for the photocatalytic reduction of CO2 into CH4 as the major product and CO (yield in CH4 of 1440 nmol g -1 h -1 and 600 nmol g -1 h -1 with a selectivity in CH4 equal to 92.6 and 85.2%, respectively, under 8 h irradiation) in water, in the presence of TEOA as an electron donor and [Ru(bpy)3] 2+ as a photosensitizer. A DFT analysis allowed proposing a reaction mechanism involving the formation of a solvated electron via photoionization of a one-electron reduced [Ru II (bpy)2(bpy •-)] + complex as the key step to reduce CO2 to CO2 •-. The latter can then coordinate to the peripheral M(II) ions to yield CO through electron and proton transfer steps involving reduced POMs and protons generated in the photooxidation of the sacrificial donor. Concerning the non-active compound, Ru(bpy)-Co, DFT calculations revealed that the Co(II) dimers present in the structure may spontaneously take the extra electron out of CO2 •-to form a Co-Co bond, releasing CO2 back. Finally, preliminary results suggest that the reduction of CO to CH4 could be photochemically accomplished by the POM-based materials in the presence of TEOA, with no mechanistic requirement for the participation of [Ru(bpy)3] 2+ .

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Synthesis, Characterization and Applications in Catalysis of Polyoxometalate/Zeolite Composites

Cited by 17 publications

References 71 publications

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Strategies for Incorporating Catalytically Active Polyoxometalates in Metal–Organic Frameworks for Organic Transformations

Understanding the Photocatalytic Reduction of CO₂with Heterometallic Molybdenum(V) Phosphate Polyoxometalates in Aqueous Media

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Synthesis, Characterization and Applications in Catalysis of Polyoxometalate/Zeolite Composites

Cited by 17 publications

References 71 publications

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Preparation of PLA blends by polycondensation of D,L-lactic acid using supported 12-tungstophosphoric acid as a heterogeneous catalyst

Strategies for Incorporating Catalytically Active Polyoxometalates in Metal–Organic Frameworks for Organic Transformations

Understanding the Photocatalytic Reduction of CO2with Heterometallic Molybdenum(V) Phosphate Polyoxometalates in Aqueous Media

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Understanding the Photocatalytic Reduction of CO₂with Heterometallic Molybdenum(V) Phosphate Polyoxometalates in Aqueous Media