Dina Shpasser scite author profile

The application of cooperative heterogeneous catalysts for the promotion of C-C bond formation is of great potential for making such chemical processes more sustainable. In the design of such materials, the main challenges are to form specific catalytic sites and to control the cooperative interactions. Because of the high complexity inherent to cooperative active site interactions, much of the research is focused on so called "enzyme inspired-materials." The current Progress Report identifies three material subgroups that are characterized by a rigid-ordered backbone (layered material), a flexible backbone (polymer based), or a constrained-flexibleordered backbone (metal organic frameworks). In each of these material types, examples that illustrate how key structural and chemical characteristics functions are associated with the efficient promotion of the cooperative mechanism are highlighted. The limitations and strengths of each of the systems are considered with the aim of providing an outlook with regard to the minimum requirements needed to construct an efficient cooperative catalytic material. Given the current accumulated common knowledge in this area, it is suggested that getting inspiration from the synthetic existing systems is perhaps more beneficial than from enzymes.

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Copolymerizations of propylene with functionalized long‐chain α‐olefins using group 4 organometallic catalysts and their membrane application

Zhao

Shpasser

Eisen

2011

J. Polym. Sci. A Polym. Chem.

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Introduction of functional groups into polyolefins has the potential of broadening their end use. An attractive method for preparing polyolefins containing functional groups is the copolymerization of the olefins with α‐olefins containing a functional group. Copolymerizations of propylene with 10‐undecen‐1‐ol, containing a hydroxyl group protected by either TIBA or TBDMSCl, 11‐chloro‐1‐undecene, 5‐bromopent‐1‐ene and N‐allyl‐2,2,2‐trifluoroacetamide were performed using three organometallic catalysts: the metallocene rac‐Et(Ind)2ZrCl2 and two new benzamidinate catalysts [3‐C5H4NC(NSiCH3)2]2TiCl2 and [(m‐OMe‐C6H4NC(NSiCH3)2]2ZrCl2. 10‐Undecene‐1‐ol protected “in situ” with TIBA and N‐(dec‐9‐enyl)‐2,2,2‐trifluoroacetamide gave copolymers with similar polar monomer incorporation percentages and molecular weights 17%; 28,900 g/mol for the protected 10‐undecene‐1‐ol, and 15%; 27,100 g/mol for N‐(dec‐9‐enyl)‐2,2,2‐trifluoroacetamide. 11‐Chloro‐1‐undecene gave copolymers with up to 22% incorporation for 0.12 M of the comonomer in the reaction feed. The obtained copolymers were characterized by NMR, DSC, and GPC. Membranes were prepared from two copolymers containing the hydroxyl groups (6 and 10%) and one copolymer containing chlorine groups (7%). The membranes prepared could be wetted in contrast to polypropylene membranes which do not contain functional groups. In addition, it was observed that for both type of membranes prepared from the different copolymers containing the hydroxyl groups, the flux was significantly greater than for the membrane prepared from the copolymer containing a chlorine groups. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011

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Atmospheric-Pressure Conversion of CO₂ to Cyclic Carbonates over Constrained Dinuclear Iron Catalysts

et al. 2022

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The conversion of CO 2 and epoxides to cyclic carbonates over a silica-supported di-iron(III) complex having a reduced Robson macrocycle ligand system is shown to proceed at 1 atm and 80 °C, exclusively producing the cis -cyclohexene carbonate from cyclohexene oxide. We examine the effect of immobilization configuration to show that the complex grafted in a semirigid configuration catalytically outperforms the rigid, flexible configurations and even the homogeneous counterparts. Using the semirigid catalyst, we are able to obtain a TON of up to 800 and a TOF of up to 37 h –1 under 1 atm CO 2 . The catalyst is shown to be recyclable with only minor leaching and no change to product selectivity. We further examine a range of epoxides with varying electron-withdrawing/donating properties. This work highlights the benefit arising from the constraining effect of a solid surface, akin to the role of hydrogen bonds in enzyme catalysts, and the importance of correctly balancing it.

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Polymerisations of ɛ-caprolactone and β-butyrolactone with Zn-, Al- and Mg-based organometallic complexes

Majoumo-Mbe

Smolensky

Lönnecke

et al. 2005

Journal of Molecular Catalysis A: Chemical

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Dina Shpasser

Mediating interaction strength between nickel and zirconia using a mixed oxide nanosheets interlayer for methane dry reforming

Progress in the Design of Cooperative Heterogeneous Catalytic Materials for C–C Bond Formation

Copolymerizations of propylene with functionalized long‐chain α‐olefins using group 4 organometallic catalysts and their membrane application

Atmospheric-Pressure Conversion of CO₂ to Cyclic Carbonates over Constrained Dinuclear Iron Catalysts

Polymerisations of ɛ-caprolactone and β-butyrolactone with Zn-, Al- and Mg-based organometallic complexes

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Dina Shpasser

Mediating interaction strength between nickel and zirconia using a mixed oxide nanosheets interlayer for methane dry reforming

Progress in the Design of Cooperative Heterogeneous Catalytic Materials for C–C Bond Formation

Copolymerizations of propylene with functionalized long‐chain α‐olefins using group 4 organometallic catalysts and their membrane application

Atmospheric-Pressure Conversion of CO2 to Cyclic Carbonates over Constrained Dinuclear Iron Catalysts

Polymerisations of ɛ-caprolactone and β-butyrolactone with Zn-, Al- and Mg-based organometallic complexes

Contact Info

Product

Resources

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Atmospheric-Pressure Conversion of CO₂ to Cyclic Carbonates over Constrained Dinuclear Iron Catalysts