Peculiarities of Chemisorption of Dimethyl Carbonate on Silica Surface
DOI:
https://doi.org/10.15330/pcss.17.1.88-92Keywords:
fumed silica, dimethyl carbonate, chemisorption, silanol groups, siloxane bondAbstract
This paper presents the results of studies of dimethyl carbonate interaction with sites of the fumed silica surface. The investigations were performed in a vacuum quartz cuvette using IR spectroscopy method. Chemical interaction of dimethyl carbonate with sites of the dehydrated silica surface was shown to occur at temperature of 200 °C and higher, chemisorption processes take place involving both structural silanol groups and siloxane bridges on the surface.
References
[1] V. A. Tertykh, L. A. Belyakova, Khymycheskye reaktsyy s uchastyem poverkhnosty kremnezema (Naukova dumka, Kyyiv, 1991).
[2] M. H. Voronkov, Heterolytycheskye reaktsyy rasshcheplenyya syloksanovykh svyazey (Yzd-vo AN SSSR, Moskva, 1961).
[3] I. F. Myronyuk, S. A. Kurta, T. V. Herhel', Ye. M. Voronin, V. L. Chelyadin, O. S. Kurta, Physics and Chemistry of Solid State 10(1), 157 (2009).
[4] O. S. Kurta, V. M. Kyslenko, I. F. Myronyuk, S. A. Kurta, Skhid-Yevrop. Zhurn. Pered. Tekhn. 3(6), 54 (2011).
[5] P. Tundo, M. Selva, Acc. Chem. Res. 35(9), 707 (2002).
[6] L. M. Kustov, Y. P. Beletskaya, Ros. khym. zh. 48(6), 3 (2004).
[7] Y. Ono, Appl. Catal. A, 155(2), 133 (1997).
[8] G. Lamoureux, C. Aguergo, ARKIVOC (1), 251 (2009).
[9] Y. Ono, Pure Appl. Chem. 68(2), 367 (1996).
[10] F. Aryko, P. Tundo, Usp. Khym. 79(6), 532 (2010).
[11] P. Tundo, L. Rossi, A. Loris, J. Org. Chem. 70(6), 2219 (2005).
[12] I. S. Protsak, V. A. T'ortykh, Yu. M. Bol'bukh, R. B. Kozakevych, KhPU (4), 58 (2013).
[13] M. Okamoto, S. Suzuki, E. Suzuki, Appl. Catal. A 261(2), 239 (2004).
[14] I. S. Protsak, V. A. T'ortykh, O. V. Honcharuk, Yu. M. Bol'bukh, R. B. Kozakevych Khim., fiz. ta tekhn. pover. 5(2), 226 (2014).
[15] I. S. Protsak, V. A. Tertykh, Y. M. Bolbukh, D. Sternik, A. Derylo-Marczewska, WJNSE (5), 152 (2015).
[16] Y. Ono, M. Akiyama, E. Suzuki, Chem. Mater. (5), 442 (1993).
[17] S. P. Mushtakova, Yu. B. Monakhova, T. M. Varlamova, Yzv. Sarat. un-ta. 8(1), 12 (2008).
[18] W. Hertl, M. Hair, J. Phys. Chem. 75(14), 2181 (1971).
[2] M. H. Voronkov, Heterolytycheskye reaktsyy rasshcheplenyya syloksanovykh svyazey (Yzd-vo AN SSSR, Moskva, 1961).
[3] I. F. Myronyuk, S. A. Kurta, T. V. Herhel', Ye. M. Voronin, V. L. Chelyadin, O. S. Kurta, Physics and Chemistry of Solid State 10(1), 157 (2009).
[4] O. S. Kurta, V. M. Kyslenko, I. F. Myronyuk, S. A. Kurta, Skhid-Yevrop. Zhurn. Pered. Tekhn. 3(6), 54 (2011).
[5] P. Tundo, M. Selva, Acc. Chem. Res. 35(9), 707 (2002).
[6] L. M. Kustov, Y. P. Beletskaya, Ros. khym. zh. 48(6), 3 (2004).
[7] Y. Ono, Appl. Catal. A, 155(2), 133 (1997).
[8] G. Lamoureux, C. Aguergo, ARKIVOC (1), 251 (2009).
[9] Y. Ono, Pure Appl. Chem. 68(2), 367 (1996).
[10] F. Aryko, P. Tundo, Usp. Khym. 79(6), 532 (2010).
[11] P. Tundo, L. Rossi, A. Loris, J. Org. Chem. 70(6), 2219 (2005).
[12] I. S. Protsak, V. A. T'ortykh, Yu. M. Bol'bukh, R. B. Kozakevych, KhPU (4), 58 (2013).
[13] M. Okamoto, S. Suzuki, E. Suzuki, Appl. Catal. A 261(2), 239 (2004).
[14] I. S. Protsak, V. A. T'ortykh, O. V. Honcharuk, Yu. M. Bol'bukh, R. B. Kozakevych Khim., fiz. ta tekhn. pover. 5(2), 226 (2014).
[15] I. S. Protsak, V. A. Tertykh, Y. M. Bolbukh, D. Sternik, A. Derylo-Marczewska, WJNSE (5), 152 (2015).
[16] Y. Ono, M. Akiyama, E. Suzuki, Chem. Mater. (5), 442 (1993).
[17] S. P. Mushtakova, Yu. B. Monakhova, T. M. Varlamova, Yzv. Sarat. un-ta. 8(1), 12 (2008).
[18] W. Hertl, M. Hair, J. Phys. Chem. 75(14), 2181 (1971).
