[111] Niederberger,  M.,  Pinna,  N.  (2009).  Metal  Oxide  Nanoparticles  in  Organic
                  Solvents:  Synthesis,  Formation,  Assembly  and  Application  (Engineering  Materials

                  and Processes). Springer, Berlin, Germany.
                  [112] Feinle, A., Elsaesser, M.S., Hüsing, N. (2016). Sol-gel synthesis of monolithic
                  materials with hierarchical porosity. Chemical Society Reviews, 45(12), 3377–3399.

                  [113] Liao,  Y.,  Xu,  Y.,  Chan,  Y.  (2013).  Semiconductor  nanocrystals  in  sol-gel
                  derived matrices. Physical Chemistry Chemical Physics, 15(33), 13704.
                  [114] Owens, G.J., Singh, R.K., Foroutan, F. et al. (2016). Sol-gel based materials for

                  biomedical applications. Progress in Materials Science, 77, 1–79.
                  [115] Haruta,  M.  (2004).  Nanoparticulate  gold  catalysts  for  low-temperature  CO
                  oxidation. Journal of New Materials for Electrochemical Systems, 7, 163–172.

                  [116] Tian,  N.,  Zhou,  Z.Y.,  Sun,  S.G.,  Ding,  Y.,  Wang,  Z.L.  (2007).  Synthesis  of
                  tetrahexahedral  platinum  nanocrystals  with  high-index  facets  and  high  electro-
                  oxidation activity. Science, 316(5825), 732–735.

                  [117] Xu, R., Wang, D., Zhang, J., Li, Y. (2006). Shape-dependent catalytic activity
                  of silver nanoparticles for the oxidation of styrene.  Chemistry – An Asian Journal,
                  1(6), 888–893.
                  [118] Rahman, I.A., Padavettan, V. (2012). Synthesis of silica nanoparticles by sol-

                  gel:  size-dependent  properties,  surface  modification,  and  applications  in  silica-
                  polymer  nanocomposites—a  review.  Journal  of  Nanomaterials,  2012,  Article  ID
                  132424.

                  [119] Adam,  F.,  Chew,  T.S.,  Andas,  J.  (2011).  A  simple  template-free  sol-gel
                  synthesis  of  spherical  nanosilica  from  agricultural  biomass.  Journal  of  Sol-Gel
                  Science and Technology, 59(3), 580–583.

                  [120] Catauro,  M.,  Tranquillo,  E.,  Di  Poggetto,  G.,  Pasquali,  M.,  Dell’Era,  A.,
                  Vecchio, S.C. (2018). Influence of the heat treatment on the particles size and on the
                  crystalline phase of TiO  synthesized by the sol-gel method. Materials, 11(12).
                                             2
                  [121] Gupta, S., Tripathi, M. (2012). A review on the synthesis of TiO  nanoparticles
                                                                                                  2
                  by solution route. Open Chemistry, 10(2), 279–294.
                  [122] Yoldas, B.E. (1979). Monolithic glass formation by chemical polymerization.
                  Journal of Materials Science, 14(8), 1843–1849.

                  [123] Scherer,  G.W.  (1988).  Aging  and  drying  of  gels.  Journal  of  Non-crystalline
                  Solids, 100(1–3), 77–92.

                  [124] Isley,  S.L.,  Penn,  R.L.  (2008).  Titanium  dioxide  nanoparticles:  effect  of
                  Sol−Gel  pH  on  phase  composition,  particle  size,  and  particle  growth  mechanism.
                  Journal of Physical Chemistry C, 112(12), 4469–4474.
                  [125] Марчук,  І.  Є.,  Засадний,  Т.  М.,  Завалій,  І.  Ю.  (2024).  Наводнювання

                  нікелю  та  матеріалів  на  його  основі  (Огляд).  Фізико-хімічна  механіка
                  матеріалів, 60(6), 5–14.
                                                                                                               191