Search

Your search keyword '"Telalovic, Selvedin"' showing total 42 results
Start Over Author "Telalovic, Selvedin"
42 results on '"Telalovic, Selvedin"'

3. Author Correction: Origin of active sites on silica–magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process

Author

Chung, Sang-Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnincx, Pieter C. A., Gascon, Jorge, and Ruiz-Martínez, Javier

Published
2023
Full Text
View/download PDF

5. Unlocking mixed oxides with unprecedented stoichiometries from heterometallic metal-organic frameworks for the catalytic hydrogenation of CO2

Author

Castells-Gil, Javier, Ould-Chikh, Samy, Ramírez, Adrian, Ahmad, Rafia, Prieto, Gonzalo, Gómez, Alberto Rodríguez, Garzón-Tovar, Luis, Telalovic, Selvedin, Liu, Lingmei, Genovese, Alessandro, Padial, Natalia M., Aguilar-Tapia, Antonio, Bordet, Pierre, Cavallo, Luigi, Martí-Gastaldo, Carlos, and Gascon, Jorge

Published
2021
Full Text
View/download PDF

6. Copper nanoparticles encapsulated in zeolitic imidazolate framework-8 as a stable and selective CO2 hydrogenation catalyst

Author

Universidad de Alicante. Departamento de Química Inorgánica, Universidad de Alicante. Instituto Universitario de Materiales, Velisoju, Vijay Kumar, Cerrillo, Jose L., Ahmad, Rafia, Mohamed, Hend Omar, Attada, Yerrayya, Cheng, Qingpeng, Yao, Xueli, Zheng, Lirong, Shekhah, Osama, Telalovic, Selvedin, Narciso, Javier, Cavallo, Luigi, Han, Yu, Eddaoudi, Mohamed, Ramos-Fernández, Enrique V., Castaño, Pedro, Universidad de Alicante. Departamento de Química Inorgánica, Universidad de Alicante. Instituto Universitario de Materiales, Velisoju, Vijay Kumar, Cerrillo, Jose L., Ahmad, Rafia, Mohamed, Hend Omar, Attada, Yerrayya, Cheng, Qingpeng, Yao, Xueli, Zheng, Lirong, Shekhah, Osama, Telalovic, Selvedin, Narciso, Javier, Cavallo, Luigi, Han, Yu, Eddaoudi, Mohamed, Ramos-Fernández, Enrique V., and Castaño, Pedro

Abstract

Metal–organic frameworks have drawn attention as potential catalysts owing to their unique tunable surface chemistry and accessibility. However, their application in thermal catalysis has been limited because of their instability under harsh temperatures and pressures, such as the hydrogenation of CO2 to methanol. Herein, we use a controlled two-step method to synthesize finely dispersed Cu on a zeolitic imidazolate framework-8 (ZIF-8). This catalyst suffers a series of transformations during the CO2 hydrogenation to methanol, leading to ~14 nm Cu nanoparticles encapsulated on the Zn-based MOF that are highly active (2-fold higher methanol productivity than the commercial Cu–Zn–Al catalyst), very selective (>90%), and remarkably stable for over 150 h. In situ spectroscopy, density functional theory calculations, and kinetic results reveal the preferential adsorption sites, the preferential reaction pathways, and the reverse water gas shift reaction suppression over this catalyst. The developed material is robust, easy to synthesize, and active for CO2 utilization.

Published
2024

7. Environmental Challenges and Opportunities in Marine Engine Heavy Fuel Oil Combustion

Author

Abdul Jameel, Abdul Gani, Alkhateeb, Abdulrahman, Telalović, Selvedin, Elbaz, Ayman M., Roberts, William L., Sarathy, S. Mani, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Solari, Giovanni, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Murali, K., editor, Sriram, V., editor, Samad, Abdus, editor, and Saha, Nilanjan, editor

Published
2019
Full Text
View/download PDF

10. Zeolite Synthesis in the Presence of Metallosiloxanes for the Quantitative Encapsulation of Metal Species for the Selective Catalytic Reduction (SCR) of NOx

Author

Khairova, Rushana, primary, Komaty, Sarah, additional, Dikhtiarenko, Alla, additional, Cerrillo, Jose L, additional, Veeranmaril, Sudheesh Kumar, additional, Telalovic, Selvedin, additional, Tapia, Antonio Aguilar, additional, Hazemann, Jean-Louis, additional, Ruiz-Martinez, Javier, additional, and Gascon, Jorge, additional

Published
2023
Full Text
View/download PDF

13. Author Correction: Origin of active sites on silica–magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process (Nature Catalysis, (2023), 6, 4, (363-376), 10.1038/s41929-023-00945-0)

Author

Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnincx, Pieter C.A., Gascon, Jorge, Ruiz-Martínez, Javier, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnincx, Pieter C.A., Gascon, Jorge, and Ruiz-Martínez, Javier

Abstract

In the version of the article initially published, Pieter C. A. Bruijnincx’s name was misspelt as Bruijnicx. The error has now been corrected in the HTML and PDF versions of the article.

Published
2023

14. Origin of active sites on silica–magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process

Author

Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnicx, Pieter C.A., Gascon, Jorge, Ruiz-Martínez, Javier, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnicx, Pieter C.A., Gascon, Jorge, and Ruiz-Martínez, Javier

Abstract

Wet-kneaded silica–magnesia is a benchmark catalyst for the one-step ethanol-to-butadiene Lebedev process. Magnesium silicates, formed during wet kneading, have been proposed as the active sites for butadiene formation, and their properties are mainly explained in terms of the ratio of acid and base sites. However, their mechanism of formation and reactivity have not yet been fully established. Here we show that magnesium silicates are formed by the dissolution of Si and Mg subunits from their precursors, initiated by the alkaline pH of the wet-kneading medium, followed by cross-deposition on the precursor surfaces. Using two individual model systems (Mg/SiO2 and Si/MgO), we demonstrate that the location of the magnesium silicates (that is, Mg on SiO2 or Si on MgO) governs not only their chemical nature, but also the configuration of adsorbed ethanol and resulting selectivity. By using an NMR approach together with probe molecules, we demonstrate that acid and basic sites in close atomic proximity (~5 Å) promote butadiene formation. [Figure not available: see fulltext.].

Published
2023

15. Author Correction: Origin of active sites on silica–magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process (Nature Catalysis, (2023), 6, 4, (363-376), 10.1038/s41929-023-00945-0)

Author

Faculteit Betawetenschappen, Sub Inorganic Chemistry and Catalysis, Sub Organic Chemistry and Catalysis, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnincx, Pieter C.A., Gascon, Jorge, Ruiz-Martínez, Javier, Faculteit Betawetenschappen, Sub Inorganic Chemistry and Catalysis, Sub Organic Chemistry and Catalysis, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnincx, Pieter C.A., Gascon, Jorge, and Ruiz-Martínez, Javier

Published
2023

16. Origin of active sites on silica–magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process

Author

Faculteit Betawetenschappen, Sub Inorganic Chemistry and Catalysis, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnicx, Pieter C.A., Gascon, Jorge, Ruiz-Martínez, Javier, Faculteit Betawetenschappen, Sub Inorganic Chemistry and Catalysis, Chung, Sang Ho, Li, Teng, Shoinkhorova, Tuiana, Komaty, Sarah, Ramirez, Adrian, Mukhambetov, Ildar, Abou-Hamad, Edy, Shterk, Genrikh, Telalovic, Selvedin, Dikhtiarenko, Alla, Sirks, Bart, Lavrik, Polina, Tang, Xinqi, Weckhuysen, Bert M., Bruijnicx, Pieter C.A., Gascon, Jorge, and Ruiz-Martínez, Javier

Published
2023

19. Origin of active sites on silica-magnesia catalysts and control of reactive environment in the one-step ethanol-to-butadiene process

Author

Chung, Sang-Ho, primary, Li, Teng, additional, Shoinkhorova, Tuiana, additional, Ramirez, Adrian, additional, Mukhambetov, Ildar, additional, Abou-Hamad, Edy, additional, Shterk, Genrikh, additional, Telalovic, Selvedin, additional, Dikhtiarenko, Alla, additional, Sirks, Bart, additional, Lavrik, Polina, additional, Tang, Xinqi, additional, Weckhuysen, Bert, additional, Bruijnincx, Pieter, additional, Gascon, Jorge, additional, and Ruiz-Martinez, Javier, additional

Published
2022
Full Text
View/download PDF

20. How Reproducible Are Surface Areas Calculated from the BET Equation?

Author

Osterrieth, Johannes, primary, Rampersad, James, additional, Madden, David G., additional, Rampal, Nakul, additional, Skoric, Luka, additional, Connolly, Bethany, additional, Allendorf, Mark, additional, Stavila, Vitalie, additional, SNIDER, JONATHAN, additional, Ameloot, Rob, additional, Marreiros, Joao, additional, Ania, Conchi O., additional, Azevedo, Diana C. S., additional, Vilarrasa-García, Enrique, additional, Santos, Bianca F, additional, Bu, Xian-He, additional, Zang, Xe, additional, Bunzen, Hana, additional, Champness, Neil, additional, Griffin, Sarah L., additional, Chen, Banglin, additional, Lin, Rui-Biao, additional, Coasne, Benoit, additional, Cohen, Seth M., additional, Moreton, Jessica C., additional, Colon, Yamil J., additional, Chen, Linjiang, additional, Clowes, Rob, additional, Coudert, François-Xavier, additional, Cui, Yong, additional, Hou, Bang, additional, D’Alessandro, Deanna, additional, Doheny, Patrick W., additional, Dinca, Mircea, additional, Sun, Chenyue, additional, Doonan, Christian, additional, Huxley, Michael, additional, Evans, Jack D., additional, falcaro, paolo, additional, Riccò, Raffaele, additional, Farha, Omar K., additional, Idrees, Karam B., additional, Islamoglu, Timur, additional, Feng, Pingyun, additional, Yang, Huajun, additional, Forgan, Ross, additional, Bara, Dominic, additional, Furukawa, Shuhei, additional, Sanchez, Elisabeth, additional, Gascon, Jorge, additional, Telalovic, Selvedin, additional, Ghosha, Sujit K., additional, MUKHERJEE, SOUMYA, additional, Hill, Matthew R., additional, Sadiq, Muhammad Munir, additional, Horcajada, Patricia, additional, Salcedo-Abraira, Pablo, additional, Kaneko, Katsumi, additional, Kukobat, Radovan, additional, Kenvin, Jeffrey, additional, Keskin, Seda, additional, Kitagawa, Susumu, additional, Otake, Kenichi, additional, Lively, Ryan P., additional, DeWitt, Stephen J. A., additional, Llewellyn, Philip L., additional, Lotsch, Bettina, additional, Emmerling, Sebastian T., additional, Pütz, Alexander, additional, Martí-Gastaldo, Carlos, additional, Muñoz, Natalia, additional, Garcia-Martinez, Javier, additional, Linares, Noemi, additional, Maspoch, Daniel, additional, Suarez, Jose Antonio, additional, Moghadam, Peyman, additional, Oktavian, Rama, additional, Morris, Russell, additional, Wheatley, Paul, additional, Navarro, Jorge, additional, Petit, Camille, additional, Danaci, David, additional, Rosseinsky, Matthew, additional, Katsoulidis, Alexandros, additional, Schroder, Martin, additional, Han, Xue, additional, Yang, Sihai, additional, Serre, Christian, additional, Mouchaham, Georges, additional, Sholl, David, additional, Thyagarajan, Raghuram, additional, Siderius, Daniel, additional, Snurr, Randall Q., additional, Goncalves, Rebecca B., additional, Telfer, Shane G., additional, Lee, Seok J., additional, Ting, Valeska, additional, Rowlandson, Jemma, additional, Uemura, Takeshi, additional, Iiyuka, Tomoya, additional, van der Veen, Monique, additional, Rega, Davide, additional, Vanspeybroeck, Veronique, additional, Lamaire, Aran, additional, Rogge, Sven, additional, Walton, Krista, additional, Bingel, Lukas W., additional, Wuttke, Stefan, additional, Andreo, Jacopo, additional, Yaghi, Omar, additional, Zhang, Bing, additional, Yavuz, Cafer, additional, Nguyen, Thien, additional, Zamora, Felix, additional, Montoro, Carmen, additional, Zhou, Hong-Cai, additional, Angelo, Kirchon, additional, and Fairen-Jimenez, David, additional

Published
2022
Full Text
View/download PDF

21. Unlocking mixed oxides with unprecedented stoichiometries from heterometallic metal-organic frameworks for the catalytic hydrogenation of CO2

Author

Universitat Politècnica de València. Instituto Universitario Mixto de Tecnología Química - Institut Universitari Mixt de Tecnologia Química, European Commission, Agencia Estatal de Investigación, Ministerio de Economía y Competitividad, Castells-Gil, Javier, Ould-Chikh, Samy, Ramírez, Adrian, Ahmad, Rafia, Prieto González, Gonzalo, Rodríguez Gómez, Alberto, Garzón-Tovar, Luis, Telalovic, Selvedin, Liu, Lingmei, Genovese, Alessandro, Padial, Natalia M., Aguilar-Tapia, Antonio, Bordet, Pierre, Cavallo, Luigi, Martí-Gastaldo, Carlos, Universitat Politècnica de València. Instituto Universitario Mixto de Tecnología Química - Institut Universitari Mixt de Tecnologia Química, European Commission, Agencia Estatal de Investigación, Ministerio de Economía y Competitividad, Castells-Gil, Javier, Ould-Chikh, Samy, Ramírez, Adrian, Ahmad, Rafia, Prieto González, Gonzalo, Rodríguez Gómez, Alberto, Garzón-Tovar, Luis, Telalovic, Selvedin, Liu, Lingmei, Genovese, Alessandro, Padial, Natalia M., Aguilar-Tapia, Antonio, Bordet, Pierre, Cavallo, Luigi, and Martí-Gastaldo, Carlos

Abstract

[EN] Their complex surface chemistry and high oxygen lattice mobilities place mixed-metal oxides among the most important families of materials. Modulation of stoichiometry in mixed-metal oxides has been shown to be a very powerful tool for tuning optical and catalytic properties. However, accessing different stoichiometries is not always synthetically possible. Here, we show that the thermal decomposition of the recently reported metal-organic framework MUV-101(Fe, Ti) results in the formation of carbon-supported titanomaghemite nanoparticles with an unprecedented Fe/Ti ratio close to 2, not achievable by soft-chemistry routes. The resulting titanomaghemite phase displays outstanding catalytic activity for the production of CO from CO2 via the reverse water-gas shift (RWGS) reaction with CO selectivity values of ca. 100% and no signs of deactivation after several days on stream. Theoretical calculations suggest that the reaction proceeds through the formation of COOH¿ species, favoring in this way CO over other byproducts.

Published
2021

22. How Reproducible Are Surface Areas Calculated from the BET Equation?

Author

Osterrieth, Johannes, primary, Rampersad, James, primary, Madden, David G., primary, Rampal, Nakul, primary, Skoric, Luka, primary, Connolly, Bethany, primary, Allendorf, Mark, primary, Stavila, Vitalie, primary, SNIDER, JONATHAN, primary, Ameloot, Rob, primary, Marreiros, Joao, primary, Ania, ConchiO., primary, Azevedo, Diana C. S., primary, Vilarrasa-García, Enrique, primary, Santos, Bianca F, primary, Bu, Xian-He, primary, Zang, Xe, primary, Bunzen, Hana, primary, Champness, Neil, primary, Griffin, Sarah L., primary, Chen, Banglin, primary, Lin, Rui-Biao, primary, Coasne, Benoit, primary, Cohen, Seth M., primary, Moreton, JessicaC., primary, Colon, Yamil J., primary, Chen, Linjiang, primary, Clowes, Rob, primary, Coudert, François-Xavier, primary, Cui, Yong, primary, Hou, Bang, primary, D’Alessandro, Deanna, primary, Doheny, Patrick W., primary, Dinca, Mircea, primary, Sun, Chenyue, primary, Doonan, Christian, primary, Huxley, Michael, primary, Evans, Jack D., primary, falcaro, paolo, primary, Riccò, Raffaele, primary, Farha, OmarK., primary, Idrees, Karam B., primary, Islamoglu, Timur, primary, Feng, Pingyun, primary, Yang, Huajun, primary, Forgan, Ross, primary, Bara, Dominic, primary, Furukawa, Shuhei, primary, Sanchez, Elisabeth, primary, Gascon, Jorge, primary, Telalovic, Selvedin, primary, Ghosha, Sujit K., primary, MUKHERJEE, SOUMYA, primary, Hill, Matthew R., primary, Sadiq, Muhammad Munir, primary, Horcajada, Patricia, primary, Salcedo-Abraira, Pablo, primary, Kaneko, Katsumi, primary, Kukobat, Radovan, primary, Kenvin, Jeffrey, primary, Keskin, Seda, primary, Kitagawa, Susumu, primary, Otake, Kenichi, primary, Lively, Ryan P., primary, DeWitt, Stephen J. A., primary, Llewellyn, Philip L., primary, Lotsch, Bettina, primary, Emmerling, Sebastian T., primary, Pütz, Alexander, primary, Martí-Gastaldo, Carlos, primary, Muñoz, Natalia, primary, Garcia-Martinez, Javier, primary, Linares, Noemi, primary, Maspoch, Daniel, primary, Suarez, Jose Antonio, primary, Moghadam, Peyman, primary, Oktavian, Rama, primary, Morris, Russell, primary, Wheatley, Paul, primary, Navarro, Jorge, primary, Petit, Camille, primary, Danaci, David, primary, Rosseinsky, Matthew, primary, Katsoulidis, Alexandros, primary, Schroder, Martin, primary, Han, Xue, primary, Yang, Sihai, primary, Serre, Christian, primary, Mouchaham, Georges, primary, Sholl, David, primary, Thyagarajan, Raghuram, primary, Siderius, Daniel, primary, Snurr, Randall Q., primary, Goncalves, Rebecca B., primary, Telfer, Shane G., primary, Lee, Seok J., primary, Ting, Valeska, primary, Rowlandson, Jemma, primary, Uemura, Takeshi, primary, Iiyuka, Tomoya, primary, van der Veen, Monique, primary, Rega, Davide, primary, Vanspeybroeck, Veronique, primary, Lamaire, Aran, primary, Rogge, Sven, primary, Walton, Krista, primary, Bingel, LukasW., primary, Wuttke, Stefan, primary, Andreo, Jacopo, primary, Yaghi, Omar, primary, Zhang, Bing, primary, Yavuz, Cafer, primary, Nguyen, Thien, primary, Zamora, Felix, primary, Montoro, Carmen, primary, Zhou, Hong-Cai, primary, Angelo, Kirchon, primary, and Fairen-Jimenez, David, primary

Published
2021
Full Text
View/download PDF

26. Metal–Organic Framework-Derived Synthesis of Cobalt Indium Catalysts for the Hydrogenation of CO2 to Methanol

Author

Pustovarenko, Alexey, primary, Dikhtiarenko, Alla, additional, Bavykina, Anastasiya, additional, Gevers, Lieven, additional, Ramírez, Adrian, additional, Russkikh, Artem, additional, Telalovic, Selvedin, additional, Aguilar, Antonio, additional, Hazemann, Jean-Louis, additional, Ould-Chikh, Samy, additional, and Gascon, Jorge, additional

Published
2020
Full Text
View/download PDF

27. A strategy to convert propane to aromatics (BTX) using TiNp4 grafted at the periphery of ZSM-5 by surface organometallic chemistry

Author

Al Maksoud, Walid, primary, Gevers, Lieven E., additional, Vittenet, Jullian, additional, Ould-Chikh, Samy, additional, Telalovic, Selvedin, additional, Bhatte, Kushal, additional, Abou-Hamad, Edy, additional, Anjum, Dalaver H., additional, Hedhili, Mohamed N., additional, Vishwanath, Vinu, additional, Alhazmi, Abdulrahman, additional, Almusaiteer, Khaled, additional, and Basset, Jean Marie, additional

Published
2019
Full Text
View/download PDF

28. Stable High‐Pressure Methane Dry Reforming Under Excess of CO2.

Author

Ramirez, Adrian, Lee, Kunho, Harale, Aadesh, Gevers, Lieven, Telalovic, Selvedin, Al Solami, Bandar, and Gascon, Jorge

Subjects
CATALYST poisoning, CARBON dioxide, PRESSURE, COKE (Coal product), SYNTHESIS gas, METHANE, DRYING
Abstract

Dry reforming of methane (DRM), the conversion of carbon dioxide and methane into syngas, offers great promise for the recycling of CO2. However, fast catalyst deactivation, especially at the industrially required high pressure, still hampers this process. Here we present a comprehensive study of DRM operation at high pressure (7–28 bars). Our results demonstrate that, under equimolar CH4 : CO2 mixtures, coke formation is unavoidable at high pressures for all catalysts under study. However, under substoichiometric CH4 : CO2 ratios (1 : 3), a stable high pressure operation can be achieved for most catalysts with no sign of deactivation for at least 60 hours at 14 bars, 800 °C and 7500 h−1. In addition to the enhanced stability, under these conditions, the amount of CO2 abated per mol of CH4 fed increases by a 50 %. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

31. A strategy to convert propane to aromatics (BTX) using TiNp4 grafted at the periphery of ZSM-5 by surface organometallic chemistry.

Author

Al Maksoud, Walid, Gevers, Lieven E., Vittenet, Jullian, Ould-Chikh, Samy, Telalovic, Selvedin, Bhatte, Kushal, Abou-Hamad, Edy, Anjum, Dalaver H., Hedhili, Mohamed N., Vishwanath, Vinu, Alhazmi, Abdulrahman, Almusaiteer, Khaled, and Basset, Jean Marie

Subjects
SURFACE chemistry, ORGANOMETALLIC chemistry, AROMATIZATION catalysts, PROPANE, BRONSTED acids, DEHYDROGENATION
Abstract

The direct conversion of propane into aromatics (BTX) using modified ZSM-5 was achieved with a strategy of “catalysis by design”. In contrast to the classical mode of action of classical aromatization catalysts which are purely based on acidity, we have designed the catalyst associating two functions: One function (Ti-hydride) was selected to activate the C–H bond of propane by σ-bond metathesis to further obtain olefin by β-H elimination and the other function (Brønsted acid) being responsible for the oligomerization, cyclization, and aromatization. This bifunctional catalyst was obtained by selectively grafting a bulky organometallic complex of tetrakis(neopentyl)titanium (TiNp4) at the external surface (external silanol (≡Si–OH) group) of [H-ZSM-5300] to obtain [Ti/ZSM-5] catalyst 1. This metal was chosen to activate the C–H bond of paraffin at the periphery of the ZSM-5 while maintaining the Brønsted acid properties of the internal [H-ZSM-5] for oligomerization, cyclization, and aromatization. Catalyst 2 [Ti–H/ZSM-5] was obtained after treatment under H2 at 550 °C of freshly prepared catalyst 1 ([Ti/ZSM-5]) and catalyst 1 was thoroughly characterized by ICP analysis, DRIFT, XRD, N2-physisorption, multinuclear solid-state NMR, XPS and HR-TEM analysis including STEM imaging. The conversion of propane to aromatics was studied in a dynamic flow reactor. With the pristine [H-ZSM-5300] catalyst, the conversion of propane is very low. However, with [Ti–H/ZSM-5] catalyst 2 under the same reaction conditions, the conversion of propane remains significant during 60 h of the reaction (ca. 22%). Furthermore, the [Ti–H/ZSM-5] catalyst shows a good and stable selectivity (55%) for aromatics (BTX) of time on stream. With 2, it was found that the Ti remains at the periphery of the [H-ZSM-5] even after reaction time. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

34. On the Synergistic Catalytic Properties of Bimetallic Mesoporous Materials Containing Aluminum and Zirconium: The Prins Cyclisation of Citronellal

Author

Sub Inorganic Chemistry and Catalysis, Faculteit Betawetenschappen, Telalovic, Selvedin, Ramanathan, Anand, Ng, Jeck Fei, Maheswari, Rajamanickam, Kwakernaak, Cees, Soulimani, Fouad, Brouwer, Hans C., Chuah, Gaik Khuan, Weckhuysen, Bert M., Hanefeld, Ulf, Sub Inorganic Chemistry and Catalysis, Faculteit Betawetenschappen, Telalovic, Selvedin, Ramanathan, Anand, Ng, Jeck Fei, Maheswari, Rajamanickam, Kwakernaak, Cees, Soulimani, Fouad, Brouwer, Hans C., Chuah, Gaik Khuan, Weckhuysen, Bert M., and Hanefeld, Ulf

Published
2011

38. ZIF‐67 Derived Cobalt Catalysts for the Hydroformylation of Liquid Olefins.

Author

Almeida, Leandro D., Patiño, Alejandra R., Cerrillo, Jose L., Telalovic, Selvedin, Garzon‐Tovar, Luis, and Gascon, Jorge

Subjects
*CATALYTIC activity, *HYDROFORMYLATION, *WASTE recycling, *ALKENES, *COBALT
Abstract

In this work, we described a general monometallic cobalt heterogeneous catalyst for the hydroformylation of olefins, achieving good yields and recyclability up to five times with no loss in catalytic activity. These catalysts were prepared through the pyrolysis of the well‐defined metal–organic framework ZIF‐67. The addition of steam during the pyrolysis did not affect the final phase composition of the cobalt particles; nonetheless, it resulted in an increase of the cobalt particle size and the partial removal of the carbonaceous matrix. The materials were extensively characterized by several techniques, and it was observed that the N‐doped carbon matrix played a crucial role in terms of activity and stability. Different liquid olefins, including internal, terminal, and cyclic were successfully tested in our hydroformylation protocol. Aldehydes yields of 48%–77% for different liquid olefins were achieved with the optimal catalyst. No leaching of the active sites was observed over five catalytic cycles. The high stability of the catalyst is attributed to the presence of stabilizing nitrogen atoms bearing the cobalt sites. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

39. Cover Feature: Stable High‐Pressure Methane Dry Reforming Under Excess of CO2 (ChemCatChem 23/2020).

Author

Ramirez, Adrian, Lee, Kunho, Harale, Aadesh, Gevers, Lieven, Telalovic, Selvedin, Al Solami, Bandar, and Gascon, Jorge

Subjects
PRESSURE, DRYING, COKE (Coal product), CARBON dioxide
Abstract

Cover Feature: Stable High-Pressure Methane Dry Reforming Under Excess of CO2 (ChemCatChem 23/2020) Keywords: Dry Reforming; CO2; CH4; Hydrogen; Syngas; Pressure EN Dry Reforming CO2 CH4 Hydrogen Syngas Pressure 5835 5835 1 12/07/20 20201204 NES 201204 B The Cover Feature b shows the potential of dry reforming in the recycling of carbon dioxide. Dry Reforming, CO2, CH4, Hydrogen, Syngas, Pressure. [Extracted from the article]

Published
2020
Full Text
View/download PDF

40. Stable High‐Pressure Methane Dry Reforming Under Excess of CO2.

Author

Ramirez, Adrian, Lee, Kunho, Harale, Aadesh, Gevers, Lieven, Telalovic, Selvedin, Al Solami, Bandar, and Gascon, Jorge

Subjects
*CATALYST poisoning, *CARBON dioxide, *PRESSURE, *COKE (Coal product), *SYNTHESIS gas, *METHANE, *DRYING
Abstract

Dry reforming of methane (DRM), the conversion of carbon dioxide and methane into syngas, offers great promise for the recycling of CO2. However, fast catalyst deactivation, especially at the industrially required high pressure, still hampers this process. Here we present a comprehensive study of DRM operation at high pressure (7–28 bars). Our results demonstrate that, under equimolar CH4 : CO2 mixtures, coke formation is unavoidable at high pressures for all catalysts under study. However, under substoichiometric CH4 : CO2 ratios (1 : 3), a stable high pressure operation can be achieved for most catalysts with no sign of deactivation for at least 60 hours at 14 bars, 800 °C and 7500 h−1. In addition to the enhanced stability, under these conditions, the amount of CO2 abated per mol of CH4 fed increases by a 50 %. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

41. A strategy to convert propane to aromatics (BTX) using TiNp 4 grafted at the periphery of ZSM-5 by surface organometallic chemistry.

Author

Al Maksoud W, Gevers LE, Vittenet J, Ould-Chikh S, Telalovic S, Bhatte K, Abou-Hamad E, Anjum DH, Hedhili MN, Vishwanath V, Alhazmi A, Almusaiteer K, and Basset JM

Abstract

The direct conversion of propane into aromatics (BTX) using modified ZSM-5 was achieved with a strategy of "catalysis by design". In contrast to the classical mode of action of classical aromatization catalysts which are purely based on acidity, we have designed the catalyst associating two functions: One function (Ti-hydride) was selected to activate the C-H bond of propane by σ-bond metathesis to further obtain olefin by β-H elimination and the other function (Brønsted acid) being responsible for the oligomerization, cyclization, and aromatization. This bifunctional catalyst was obtained by selectively grafting a bulky organometallic complex of tetrakis(neopentyl)titanium (TiNp4) at the external surface (external silanol ([triple bond, length as m-dash]Si-OH) group) of [H-ZSM-5300] to obtain [Ti/ZSM-5] catalyst 1. This metal was chosen to activate the C-H bond of paraffin at the periphery of the ZSM-5 while maintaining the Brønsted acid properties of the internal [H-ZSM-5] for oligomerization, cyclization, and aromatization. Catalyst 2 [Ti-H/ZSM-5] was obtained after treatment under H2 at 550 °C of freshly prepared catalyst 1 ([Ti/ZSM-5]) and catalyst 1 was thoroughly characterized by ICP analysis, DRIFT, XRD, N2-physisorption, multinuclear solid-state NMR, XPS and HR-TEM analysis including STEM imaging. The conversion of propane to aromatics was studied in a dynamic flow reactor. With the pristine [H-ZSM-5300] catalyst, the conversion of propane is very low. However, with [Ti-H/ZSM-5] catalyst 2 under the same reaction conditions, the conversion of propane remains significant during 60 h of the reaction (ca. 22%). Furthermore, the [Ti-H/ZSM-5] catalyst shows a good and stable selectivity (55%) for aromatics (BTX) of time on stream. With 2, it was found that the Ti remains at the periphery of the [H-ZSM-5] even after reaction time.

Published
2019
Full Text
View/download PDF

42. Zr-TUD-1: a Lewis acidic, three-dimensional, mesoporous, zirconium-containing catalyst.

Author

Ramanathan A, Castro Villalobos MC, Kwakernaak C, Telalovic S, and Hanefeld U

Abstract

A three-dimensional, mesoporous, silicate containing zirconium, Zr-TUD-1, was synthesized by a direct hydrothermal treatment method with triethanolamine as a complexing and templating reagent to ensure that zirconium was incorporated as isolated atoms. The mesoporosity of Zr-TUD-1 was confirmed by X-ray diffraction (XRD), N(2) sorption and high-resolution transmission electron micrograph (HR-TEM) studies. The nature and strength of the Lewis acid sites present in Zr-TUD-1 were evaluated by FTIR studies of pyridine adsorption and temperature-programmed desorption of ammonia. FTIR, X-ray photoelectron spectroscopic (XPS) and UV/Vis spectroscopic studies showed that, at Si/Zr ratios of 25 and higher, all the zirconium was tetrahedrally incorporated into the mesoporous framework, while at low Si/Zr ratios, a small part of the zirconium was present as ZrO(2) nanoparticles. Zr-TUD-1 is a Lewis acidic, stable and recyclable catalyst for the Meerwein-Ponndorf-Verley (MPV) reaction and for the Prins reaction.

Published
2008
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results