Functional illite clay/nano-TiO 2 composite mineral coating obtained by mechanical activation

Abstract

Self-cleaning coatings have the potential to protect building material surfaces against the effects of climate change and air pollution. In this study, composite powders containing 3 and 10 wt-% nano-TiO₂ impregnated on mineral illite clay were synthesised by mechanical activation. The particle size distribution, mineralogical composition, and photocatalytic activity of the composite powders were characterised. A coating prepared from the 10 wt-% nano-TiO₂/illite composite was applied to three different substrates (highly porous, porous and non-porous), and their surface properties, functional properties and durability were evaluated. The self-cleaning and photocatalytic activities of the coating were evaluated by measuring the initial contact angle and degradation efficiency, respectively. Rhodamine B was chosen as the model pollutant. The varying functional behaviours of the coating were analysed in relation to its structural, textural and morphological properties. The 10 wt-% nano-TiO₂/illite coating exhibited pronounced hydrophilicity and demonstrated potential applicability for both porous and non-porous substrates.

Keywords

mineral illite clay composites mechanical activation photocatalytic coating

Get full access to this article

View all access options for this article.

References

Rabajczyk

Zielecka

Klapsa

, et al. Self-cleaning coatings and surfaces of modern building materials for the removal of some air pollutants. Materials (Basel) 2020; 14: 2161.

Ranogajec

Vučetić

Milan

, et al. Photocatalytic protection of building materials in real environmental conditions. Microsc Microanal 2018; 24: 1698–1699.

Aissani

Kameche

Benabbou

. Synthesis and characterization of TiO₂/LDH layered double hydroxide composites: utilization as photocatalysts for amoxicillin degradation under UVA irradiation. Inorg Nano-Metal Chem 2022; 52: 1197–1207.

Augugliaro

Bellardita

Loddo

, et al. Overview on oxidation mechanisms of organic compounds by TiO₂ in heterogeneous photocatalysis. J Photochem Photobiol C 2012; 13: 224–245.

Verbruggen

. TiO₂ photocatalysis for the degradation of pollutants in gas phase: from morphological design to plasmonic enhancement. J Photochem Photobiol C 2015; 24: 64–82.

Banerjee

Dionysiou

Pillai

. Self-cleaning applications of TiO₂ by photo-induced hydrophilicity and photocatalysis. Appl Catal B 2015; 176-177: 6–428.

Manzoor

Sajid

Ali

, et al. Toxicity spectrum and detrimental effects of titanium dioxide nanoparticles as an emerging pollutant: a review. Desalin Water Treat 2023; 317: 100025.

Men

, et al. Enhanced capacitance performance of Al₂O₃–TiO₂ composite thin film via sol–gel using double chelators. J Colloid Interface Sci 2015; 443: 170–176.

Mishra

Mehta

Basu

. Clay supported TiO₂ nanoparticles for photocatalytic degradation of environmental pollutants: a review. J Environ Chem Eng 2018; 6: 6088–6107.

10.

Ozawa

Matui

Setsuhara

. Microstructure and surface/interface characterization of TiO₂-pillared mica for photocatalytic acetaldehyde degradation. Hybrid Adv 2025; 10: 100435.

11.

Jovanov

Rudic

Ranogajec

, et al. Synthesis of nanocomposite coating based on TiO₂/ ZnAl layer double hydroxides. Materiales de Construcción 2017; 67: 112–120.

12.

Cardona

Korili

Gil

. Use of clays and pillared clays in the catalytic photodegradation of organic compounds in aqueous solutions. Catal Rev 2023; 66: 2063–2110.

13.

Szczepanik

. Photocatalytic degradation of organic contaminants over clay-TiO₂ nanocomposites: a review. Appl Clay Sci 2017; 141: 227–239.

14.

Jovanov

Zečević

Vulić

, et al. Preparation and characterization of protective self-cleaning TiO₂/kaolin composite coating. Materiales de Construcción 2018; 68: 63.

15.

Zhao

Shen

, et al. A critical review of clay mineral-based photocatalysts for wastewater treatment. Catalysts 2024; 14: 75.

16.

Tole

Delogu

Qoku

, et al. Enhancement of the pozzolanic activity of natural clays by mechanochemical activation. Constr Build Mater 2022; 352: 128739.

17.

Baláž

. Mechanochemistry in nanoscience and minerals engineering. Berlin, Heidelberg: Springer, 2008, pp.257–296.

18.

Jovanov

Vučetić

Ranogajec

, et al. Photocatalytic illite clay/TiO₂ composite powder synthesized by mechanical activation. In: Green circ 2025 proceedings. https://congress.sctm.mk/event/6/book-of-abstracts.pdf.

19.

SRPS U.M8.300:1985. Determination of the Capillary Water Absorption of Building Material and Coatings, 1985.

20.

Pranjić

Ranogajec

Škrlep

, et al. Life cycle assessment of novel consolidants and a photocatalytic suspension for the conservation of the immovable cultural heritage. J Cleaner Prod 2018; 181: 293–308.

21.

Vulic

Hadnadjev-Kostic

Rudic

, et al. Improvement of cement-based mortars by application of photocatalytic active Ti-Zn-Al nanocomposites. Cem Concr Compos 2013; 36: 121–127.

22.

Nishimoto

Ohtani

Kajiwara

, et al. Correlation of the crystal structure of titanium dioxide prepared from titanium tetra-2-propoxide with the photocatalytic activity for redox reactions in aqueous propan-2-ol and silver salt solutions. J Chem Soc Faraday Trans I 1985; 81: 61–68.

23.

Rudic

Rajnovic

Cjepa

, et al. Investigation of the durability of porous mineral substrates with newly designed TiO₂-LDH coating. Ceram Int 2015; 41: 9779–9792.

24.

Rudic

Ranogajec

Vulic

, et al. Photo-induced properties of TiO₂/ZnAl layer double hydroxide coating onto porous mineral substrates. Ceramic Int 2014; 40: 9445–9455.

25.

UNI 11259:2008. Determination of the photocatalytic activity of hydraulic binders – Dodammina test method. Ente nazionale italiano di unificazione; 2008.

26.

Cassar

Beeldens

Pimpinelli

, et al. Photocatalysis of cementous materials. In: Proceedings pro055: international RILEM symposium on photocatalysis, environment and construction materials – TDP 2007, pp.131–145.