Chemistry, Physics and Technology of Surface

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

In this paper, changes in the porous structure of carbon material are investigated during chemical activation of apricot pit at different temperatures. The main purpose of the research has been to study the features of the internal micro- and mesostructure of the carbon surface, as well as to find patterns in the size distribution of pores dependent on the carbonization temperature of plant raw materials and subsequent chemical activation.

The object of the study is porous carbon material, obtained from dried apricot fruit pits, pre-crushing, and cleaned from the core. This raw material has been carbonized at 300–900 °C with an interval of 100 °C and subjected to chemical activation by potassium hydroxide in the weight ratio X_К, where Х_К = m(KOH)/m(C). Thereby, a series of samples C3÷C9 has been obtained.

The porous structure characteristics (specific surface area and total pore volume) of porous carbon material have been determined based on the analysis of nitrogen adsorption / desorption isotherms. It has been found that these materials have a frame structure with a large number of micropores. The analysis of literature data has revealed that the experimental curves belong to the isotherms that are characteristic of multilayer adsorption in micro- and mesopores of materials of organic origin. The hysteresis loop observed on these isotherms is related to the sorption processes in narrow pores. It has been found that carbonization of raw materials and chemical activation contribute to the cleaning of the frame structure, and there are acceptable modes of heat treatment of raw materials of plant origin, which determine the optimal pore size distribution and have a specific surface area S = (1042–1313) m²/g.

With the help of scanning electron microscopy, the peculiarities of the formation of impurities on the surface of the original samples have been studied and their nature has been elucidated. It has been found that the largest total pore area has a sample carbonized at 600 ºC, and the largest pore volume V_total = 0.68 cm³/g for sample C3 is associated with a significant number of mesopores in the porous structure. As the carbonation temperature increases to 800-900 °C, narrow micropores degenerate and the carbon matrix transforms, resulting in a decrease in both the total pore area and the total porous volume.

Viswanathan B., Indra Neel P., Varadarajan T. Methods of activation and specific applications of carbon materials. (India: Chennai, 2009).

Conway B.E. Electrochemical supercapacitors. Scientific fundamentals and technological applications. (Kluwer Academic. New York: Plenum Publ., 1999).

Sugimoto W., Iwata H., Yasunaga Y., Murakami Y., Takasu Y. Preparation of ruthenic acid nanosheets and utilization of its interlayer surface for electrochemical energy storage. Angew. Chem. Int. Ed. 2003. 42(34): 4092.  https://doi.org/10.1002/anie.200351691

Rudge A., Davey J., Raistrick I., Gottesfeld S., Ferraris J.P. Conducting Polymers as Active Materials in Electrochemical Capacitors. J. Power Sources. 1994. 47(1-2): 89. https://doi.org/10.1016/0378-7753(94)80053-7

Shpak A.P., Budzulyak I.M., Lisovskyi R.P., Merena R.I., Berkeshchuk M.V. Removal of that modification of nanoporous carbon for molecular storage of electrical energy. (Kyiv: Naukova Dumka, 2006). [in Ukrainian].

Butyrin H.M. Highly porous materials. (Moscow: Khimiia, 1976). [in Russian].

Fridman L.I., Hrebennikov S.F. Theoretical aspects of obtaining and using fibrous adsorbents. Khim. Volokna. 1990. 6: 10. [in Russian].

Budzulyak I.M., Lisovskyi R.P., Merena R.I., Myronyuk I.F., Ostafiychuk B.K., Solovko Ya.T. Modification of the properties of activated carbon used in capacitor engineering. Elektrokhimicheskaya enerhetika. 2005. 6(2): 97. [in Russian].

Vashchynskyi V.M., Boychuk A.M., Vashchynska Ya.B. Structural Properties of Porous Carbon Material Formation Activated with Potassium Hydroxide. Journal of Nano- and Electronic Physics. 2019. 11(3): 03012. https://doi.org/10.21272/jnep.11(3).03012

Hreh S., Sinkh K. Adsorption, specific surface area, porosity. (Moscow: Mir, 1984). [in Russian].

Budzulyak I.M., Vashchynskyi V.M., Rachiy B.I. Adsorption properties of porous carbon materials obtained by chemical activation. Fizychna inzheneriya poverkhni. 2015. 13(1): 84. [in Ukrainian].

Lurie Yu.Yu. Handbook of Analytical Chemistry. (Moscow: Ripol Klassik, 2013). [in Russian].

Tamarkina Yu.V., Kucherenko V.A., Shendrik T.G. Alkaline activation of coals and carbon materials. Khimiya tverdogo topliva. 2014. (4): 38. [in Russian]. https://doi.org/10.3103/S0361521914040119

Karnaukhov A.P. Adsorption. Texture of dispersed and porous materials. (Novosibirsk: Nauka. Sib. predpriyatiye RAN, 1999). [in Russian].

Tamarkina Yu.V., Bovan L.A., Kucherenko V.A. Formation of humic acids during the thermolysis of brown coal with potassium hydroxide. Voprosy khimii i khimicheskoy tekhnologii. 2008. (2): 112. [in Russian].