Summary
The big challenge facing the chemical and related industries in the 21st century is the transition towards more sustainable manufacturing processes that efficiently use raw materials/energy and eliminate waste. Within this framework, catalysis engineering is recognized as the most important key enabling technology that has a substantial impact on key manufacturing sectors such as petroleum, energy, chemicals, pharma and food industry (about $ 10 trillion of the world’s Gross National Product) and highly contributes to the green deal, by reducing energy intensity for these products by 20% to 40% by 2050. To solve all these issues, an in-depth understanding of the phenomena occurring at the catalyst surface with atomic resolution and their micro-kinetic consequences within the reactor in conditions relevant to the industrial process is of paramount relevance.
Currently, a novel operando multi-technique reactor operating under realistic process-relevant conditions is still missing During the ERC “SHAPE” Stg (n. 677423), we have developed a spatially-resolved operando-Raman annular reactor able to provide a detailed real-time local information of the catalyst’ behaviour along the reactor, under strict kinetic control and nearly isothermal conditions for heterogeneous catalysis (80% of the total catalytic processes). The SPECTROKIN project aims to perform the technical-commercial feasibility of our integrated operando annular reactor by moving forward a ready to use equipment for the steam/dry methane reforming reactions on metal catalysts and upgrading the tool for other reactive systems, paving the way for a family of innovative devices.
Currently, a novel operando multi-technique reactor operating under realistic process-relevant conditions is still missing During the ERC “SHAPE” Stg (n. 677423), we have developed a spatially-resolved operando-Raman annular reactor able to provide a detailed real-time local information of the catalyst’ behaviour along the reactor, under strict kinetic control and nearly isothermal conditions for heterogeneous catalysis (80% of the total catalytic processes). The SPECTROKIN project aims to perform the technical-commercial feasibility of our integrated operando annular reactor by moving forward a ready to use equipment for the steam/dry methane reforming reactions on metal catalysts and upgrading the tool for other reactive systems, paving the way for a family of innovative devices.
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| Web resources: | https://cordis.europa.eu/project/id/966758 |
| Start date: | 01-04-2021 |
| End date: | 30-09-2022 |
| Total budget - Public funding: | - 150 000,00 Euro |
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Original description
The big challenge facing the chemical and related industries in the 21st century is the transition towards more sustainable manufacturing processes that efficiently use raw materials/energy and eliminate waste. Within this framework, catalysis engineering is recognized as the most important key enabling technology that has a substantial impact on key manufacturing sectors such as petroleum, energy, chemicals, pharma and food industry (about $ 10 trillion of the world’s Gross National Product) and highly contributes to the green deal, by reducing energy intensity for these products by 20% to 40% by 2050. To solve all these issues, an in-depth understanding of the phenomena occurring at the catalyst surface with atomic resolution and their micro-kinetic consequences within the reactor in conditions relevant to the industrial process is of paramount relevance.Currently, a novel operando multi-technique reactor operating under realistic process-relevant conditions is still missing During the ERC “SHAPE” Stg (n. 677423), we have developed a spatially-resolved operando-Raman annular reactor able to provide a detailed real-time local information of the catalyst’ behaviour along the reactor, under strict kinetic control and nearly isothermal conditions for heterogeneous catalysis (80% of the total catalytic processes). The SPECTROKIN project aims to perform the technical-commercial feasibility of our integrated operando annular reactor by moving forward a ready to use equipment for the steam/dry methane reforming reactions on metal catalysts and upgrading the tool for other reactive systems, paving the way for a family of innovative devices.
Status
CLOSEDCall topic
ERC-2020-POCUpdate Date
27-04-2024
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