Acetylene selective hydrogenation: a technical review on catalytic aspects
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Maryam Takht Ravanchi
Maryam Takht Ravanchi holds a PhD in chemical engineering. She is a researcher at Petrochemical Research and Technology Company (NPC-RT). Her recent research activities focus on acetylene selective hydrogenation, CO2 utilization, and paraffin dehydrogenation. To date, she has published about 50 scientific papers in national and international journals and presented more than 50 papers at national and international conferences. Moreover, she has published four national patents and seven books.
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Saeed Sahebdelfar
Saeed Sahebdelfar holds a PhD in chemical engineering. He is the head of the Catalysis Research Group at NPC-RT. His research interests include catalysts for hydrogenation-dehydrogenation reactions, chemical fixation of CO2, reactor design, and environmental engineering. He has more than 20 years of experience in the petrochemical industry. To date, he has published or presented more than 100 scientific papers in national and international journals and at national and international conferences.
Samane Komeili obtained her PhD in chemical engineering from Iran University of Science and Technology in 2016. She is interested in process modeling and heterogeneous catalysts. Recently, she has done research on the design and application of supported metal catalysts in the fields of selective hydrogenation and selective catalytic reduction. Her special focus is on the synthesis of zeolite and aluminate as the catalyst support. To date, she has published seven scientific papers.
Abstract
The catalytic selective hydrogenation of multiunsaturated hydrocarbons, especially in pyrolysis products, to corresponding mono-olefins is a widely exploited way for the large-scale production of polymer-grade olefins as well as fuel upgrading. Thermodynamic and/or kinetic parameters could be effective for selective operation. The latter is primarily influenced by catalyst formulation, including promoters, support type, and metal dispersion and distribution. The solution to achieve an economically attractive commercial implementation lies in defining the optimal catalyst design and operating conditions. The theoretical and practical aspects of catalysis for the selective hydrogenation of acetylene to ethylene are reviewed and the potential new ways to improve catalyst formulation are examined.
About the authors
Maryam Takht Ravanchi holds a PhD in chemical engineering. She is a researcher at Petrochemical Research and Technology Company (NPC-RT). Her recent research activities focus on acetylene selective hydrogenation, CO2 utilization, and paraffin dehydrogenation. To date, she has published about 50 scientific papers in national and international journals and presented more than 50 papers at national and international conferences. Moreover, she has published four national patents and seven books.
Saeed Sahebdelfar holds a PhD in chemical engineering. He is the head of the Catalysis Research Group at NPC-RT. His research interests include catalysts for hydrogenation-dehydrogenation reactions, chemical fixation of CO2, reactor design, and environmental engineering. He has more than 20 years of experience in the petrochemical industry. To date, he has published or presented more than 100 scientific papers in national and international journals and at national and international conferences.
Samane Komeili obtained her PhD in chemical engineering from Iran University of Science and Technology in 2016. She is interested in process modeling and heterogeneous catalysts. Recently, she has done research on the design and application of supported metal catalysts in the fields of selective hydrogenation and selective catalytic reduction. Her special focus is on the synthesis of zeolite and aluminate as the catalyst support. To date, she has published seven scientific papers.
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©2018 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- In this issue
- Process intensification
- Cold plasmas in the modification of catalysts
- Acetylene selective hydrogenation: a technical review on catalytic aspects
- Selective acid-functionalized mesoporous silica catalyst for conversion of glycerol to monoglycerides: state of the art and future prospects
- Current scenario of catalysts for biodiesel production: a critical review
Artikel in diesem Heft
- Frontmatter
- In this issue
- Process intensification
- Cold plasmas in the modification of catalysts
- Acetylene selective hydrogenation: a technical review on catalytic aspects
- Selective acid-functionalized mesoporous silica catalyst for conversion of glycerol to monoglycerides: state of the art and future prospects
- Current scenario of catalysts for biodiesel production: a critical review
