Вестник Пермского университета. Геология

Приведены результаты исследования энергетических свойств поверхности глин, активированных высоким давлением с использованием атомно-силовой микроскопии. Построены графики изменения средних значений определяемых характеристик, выявлены корреляционные зависимости.

Aleksandr A. Dzh., Zayni M.A.A., Abdulsalam S., El'-Nafati U.A., Aroke U.O. 2018. Fiziko-khimicheskiye kharakteristiki poverkhnostno-modifitsirovannogo bentonite [Physical-chemical characteristics of the surface-modified bentonite]. Nauka i tekhnika o tverdykh chastitsakh, 38(3):287-297. (in Russian)

Belchinskaya L.I., Kozlov K.A., Bondarenko A.V., Petukhova G.A., Gubkina M.L. 2007. Izucheniye strukturno-adsorbtsionnykh kharakteristik pri aktivatsii i modifitsirovanii prirodnykh silikatov [Study of structural-absorption characteristics caused by activation and modification of natural silicates]. Sorbtsionnye i khromatograficheskiye protsessy. 7(4):571-576. (in Russian)

Boldyrev V.V. 2006. Mekhanokhimiya i mekhanicheskaya aktivatsiya tverdykh veshchestv [Mechanic-chemistry and mechanical activation of solid materials]. Khimicheskoye dostizheniye. 75 (3):203- 216. (in Russian)

Galan E., Aparisio P., La Iglesia A., Gonsales I. 2006. The effect of pressure on order/disorder in kaolinite under wet and dry conditions. Clay and clay minerals. 54(2):230-239. doi: 10.1346/CCMN.2006.0540208

Goylo E.A., Kotov N.V., Frank-Kamenetskiy V.A. 1966. Eksperimentalnoye issledovaniye vliyaniya davleniya i temperatury na kristallicheskuyu strukturu kaolina, illita i montmorillonita [Experimental study of pressure and temperature impact on the crystal structure of kaolinite, illite, and montmorillonite]. Fizicheskiye metody issledovaniya osadochnykh porod. Moskva, pp. 123-129. (in Russian)

Kara-Sal B.K., Sapelkina T.V. 2012. Uluchsheniye adsorbtsionnykh svoystv tuvinskikh glinistykh mineralov v zavisimosti ot metoda aktivatsii [Inhansment of absorption properties of Tuva clay minerals in relation of activation method]. Aktualnye problemy sovremennoy nauki. 5:158-162. (in Russian)

La Iglesia A. 1993. Pressure induced disorder in kaolinite. Clay minerals. 28:311-319.

Mironov V.L. 2004. Osnovy skaniruyushchey zondovoy mikroskopii [Fundamentals of scanning probe microscopy]. Institut fiziki mikrostruktur RAN, Nizhniy Novgorod, p. 114. (in Russian)

Nichiporenko S.P., Kruglitskiy N.N., Panasevich A.A., Khilko V.V. 1974. Fiziko-khimicheskaya mekhanika dispersnykh mineralov [Physical-chemical mechanics of the dispersed minerals]. Naukova dumk, Kiyev. p. 243. (in Russian)

Poleva Ye.A., Chichvarin A.V., Krakht L.N. 2012. Modifikatsiya kleyevykh kompozitsiy nanoso-yedineniyami ugleroda fulleyernovogo ryada [Modification of the glued compositions by the nano-compound of carbon of fullerene class]. Tekhnicheskiye nauki v Rossii i za rubezhom: materialy II Mezhdunar. nauch. konf. Moskva, Buki-Vedi. (in Russian)

Pushkareva G.I. 2000. Vliyaniye temperaturnoy obrabotki brusita na yego adsorbtsionnyye svoystva [Influence of the temperature processing on brucite absorption properties]. Fiziko-tekhnicheskiye voprosy obogashcheniya poleznykh iskopayemykh. 6:90-93. (in Russian)

Sapronova ZH.A., Lesovik V.S., Gomes M.Zh., Shaykhiyeva K.I. 2015. Sorbtsionnyye svoystva UFaktivirovannykh glin mestorozhdeniy Angoly [Sorption properties of UF-activated clays of the Angola deposits]. Izvestiya vysshikh uchebnykh zavedeniy, pp. 34-42. (in Russian)

Seredin V.V., Khrulev A.S., Pushkareva M.V. 2017. Otsenka napryazhennogo sostoyaniya gornykh porod i geomaterialov [Evaluation of stress state of rocks and geomaterials]. Zhurnal gornogo dela. 53(1):49-52. (in Russian)

Seredin V.V., Khrulev A.S., Rastegayev A.V., Galkin V.I. 2020. Metodika otsenki napryazhennogo sostoyaniya gornykh porod [Methdology of evaluation of rock stress state]. Gornyy zhurnal. 2:30-34. (in Russian)

Fedorov M.V. 2018. Issledovaniye adgezionnoy sily v kaolinitovoy gline metodom atomno-silovoy mikroskopii [Study of adhesion force in kaolinite clay by atomic force microscopy]. Nauchnyy zhurnal. GVRM PGNIU, p. 7. (in Russian)

Frank-Kamenetskiy V.A., Kotov N.V., Goylo E.A. 1970. Izmeneniya glinistykh mineralov menyayutsya pri razlichnykh termodinamicheskikh usloviyakh [Clay minerals alteration changes under different thermo-dynamic conditions]. Rentgenologicheskoye issledovaniye mineralnogo syrya. 7:166-174. (in Russian)

Fedorov M. V., Seredin V.V., Lunegov I.V. 2021. Formirovaniye energeticheskikh svoystv poverkhnosti glinistykh chastits, modifitsirovannykh vysokim davleniyem [Formation of the Energy Properties of the Surface of Clay Particles Modified by High Pressure]. Vestnik Permskogo Universiteta. Geologiya. 20(1):33-48. (in Russian) doi:/10.17072/psu.geol.20.1.33

Erenberg S.N., Aagard P., Uilson M.Dzh., Freyzer A.R., Dati D.M.L. 1993. Depth-dependent transformation of kaolinite to dickite in sandstones of the Norwegian continental shelf. Clay minerals. 28:325-352.

Yakovleva A.A., Maltseva G.D. 2018. Kristallokhimicheskiye aspekty otsenki energii vzaimodeystviya chastits glinistogo minerala [Crystallochemical aspects in the evaluation of clay mineral particle interaction energy]. Izvestiya Sibirskogo otdeleniya. Sektsii nauk o Zemle Rossiyskoy akademii yestestvennykh nauk. 41(1):99–114. (in Russian)

Korolev V.A., Nesterov V.S. 2017. Fizikokhimicheskiye zakonomernosti izmeneniya elektricheskikh zaryadov chastits glinistykh gruntov [Physico-chemical regularities of changes of the clay soil particles electrical charge]. Inzhenernaya geologiya. 4:50–60. (in Russian)

Fil B., Özmetin C., Korkmaz M. 2014. Characterization and electrokinetic properties of montmorillonite. Bulgarian Chemical Communications. 46(2):258–263.