Summary
Objectives
The H-CCAT project designs, upscales and shapes hybrid catalysts for the C-H functionalization of aromatic compounds. These solid catalysts will possess better recoverability, higher turnover numbers and better selectivity than current homogeneous catalysts for these reactions. The solid catalysts are applied at demonstration scale in the step-economical production of arylated or alkenylated aromatics, yielding motifs of active pharmaceutical ingredients.
Methodology
We will design heterogeneous hybrid catalysts featuring deactivation-resistant active sites, based on N-heterocyclic carbenes (NHCs) or diimine ligands and active metal ions. Via efficient, one-step protocols based on self-assembly, these sites will be embedded in robust porous hybrid materials like hybrid silica or metal-organic frameworks. Deactivation or metal aggregation will be prevented by site isolation or by efficient metal reoxidation (for the oxidative alkenylations). Metal leaching is precluded by using strong bonds between metals and embedded ligands like NHCs. Flow protocols will be designed to maximize the turnover numbers. Catalyst synthesis will be scaled up to kg scale, using efficient one-step protocols, minimizing use of solvents or waste formation. Soft shaping methods, e.g. spray drying, will preserve porosity and activity of the hybrid solids. A demonstration is conducted at minipilot scale at the J&J site (Belgium), allowing LCA analysis, techno-economic assessment and elaboration of the business plan.
Relevance to work program
The catalysts feature new, deactivation resistant active sites; their TOF/TON is maximized by an appropriate porous structure which even can be swelling. Catalysts are produced using innovative one-step protocols to form porous hybrid catalysts as powders or even immediately as shaped objects. The molecules targeted have strong biological and pharmaceutical relevance; they target diseases like influenza, cancer or HIV (case study: Rilpivirine).
The H-CCAT project designs, upscales and shapes hybrid catalysts for the C-H functionalization of aromatic compounds. These solid catalysts will possess better recoverability, higher turnover numbers and better selectivity than current homogeneous catalysts for these reactions. The solid catalysts are applied at demonstration scale in the step-economical production of arylated or alkenylated aromatics, yielding motifs of active pharmaceutical ingredients.
Methodology
We will design heterogeneous hybrid catalysts featuring deactivation-resistant active sites, based on N-heterocyclic carbenes (NHCs) or diimine ligands and active metal ions. Via efficient, one-step protocols based on self-assembly, these sites will be embedded in robust porous hybrid materials like hybrid silica or metal-organic frameworks. Deactivation or metal aggregation will be prevented by site isolation or by efficient metal reoxidation (for the oxidative alkenylations). Metal leaching is precluded by using strong bonds between metals and embedded ligands like NHCs. Flow protocols will be designed to maximize the turnover numbers. Catalyst synthesis will be scaled up to kg scale, using efficient one-step protocols, minimizing use of solvents or waste formation. Soft shaping methods, e.g. spray drying, will preserve porosity and activity of the hybrid solids. A demonstration is conducted at minipilot scale at the J&J site (Belgium), allowing LCA analysis, techno-economic assessment and elaboration of the business plan.
Relevance to work program
The catalysts feature new, deactivation resistant active sites; their TOF/TON is maximized by an appropriate porous structure which even can be swelling. Catalysts are produced using innovative one-step protocols to form porous hybrid catalysts as powders or even immediately as shaped objects. The molecules targeted have strong biological and pharmaceutical relevance; they target diseases like influenza, cancer or HIV (case study: Rilpivirine).
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/720996 |
Start date: | 01-01-2017 |
End date: | 30-06-2021 |
Total budget - Public funding: | 7 588 312,50 Euro - 7 588 312,00 Euro |
Cordis data
Original description
ObjectivesThe H-CCAT project designs, upscales and shapes hybrid catalysts for the C-H functionalization of aromatic compounds. These solid catalysts will possess better recoverability, higher turnover numbers and better selectivity than current homogeneous catalysts for these reactions. The solid catalysts are applied at demonstration scale in the step-economical production of arylated or alkenylated aromatics, yielding motifs of active pharmaceutical ingredients.
Methodology
We will design heterogeneous hybrid catalysts featuring deactivation-resistant active sites, based on N-heterocyclic carbenes (NHCs) or diimine ligands and active metal ions. Via efficient, one-step protocols based on self-assembly, these sites will be embedded in robust porous hybrid materials like hybrid silica or metal-organic frameworks. Deactivation or metal aggregation will be prevented by site isolation or by efficient metal reoxidation (for the oxidative alkenylations). Metal leaching is precluded by using strong bonds between metals and embedded ligands like NHCs. Flow protocols will be designed to maximize the turnover numbers. Catalyst synthesis will be scaled up to kg scale, using efficient one-step protocols, minimizing use of solvents or waste formation. Soft shaping methods, e.g. spray drying, will preserve porosity and activity of the hybrid solids. A demonstration is conducted at minipilot scale at the J&J site (Belgium), allowing LCA analysis, techno-economic assessment and elaboration of the business plan.
Relevance to work program
The catalysts feature new, deactivation resistant active sites; their TOF/TON is maximized by an appropriate porous structure which even can be swelling. Catalysts are produced using innovative one-step protocols to form porous hybrid catalysts as powders or even immediately as shaped objects. The molecules targeted have strong biological and pharmaceutical relevance; they target diseases like influenza, cancer or HIV (case study: Rilpivirine).
Status
CLOSEDCall topic
NMBP-01-2016Update Date
26-10-2022
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