, Chemical Sciences

Technology for obtaining potassium titanate by ilmenite alkaline leaching with potassium hydroxide

Chemical Sciences
Published 2026-05-04
Snizhana Kucheruk
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0002-5978-487X
Oleksandr Kaminskyi
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0003-1971-8437
Roman Denysiuk
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0003-3077-3795
Olena Anichkina
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0003-4843-0707
Olena Yevdochenko
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0001-6338-5372
Olga Avdieieva
Zhytomyr Ivan Franko State University, Ukraine
https://orcid.org/0000-0001-6550-0776
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Keywords

Mineral raw materials
Ilmenite
Leaching
Titanium-containing compounds
Potassium titanate
Titanium dioxide

How to Cite

Kucheruk, S., Kaminskyi, O., Denysiuk, R., Anichkina, O., Yevdochenko, O., & Avdieieva, O. (2026). Technology for obtaining potassium titanate by ilmenite alkaline leaching with potassium hydroxide. Revista De La Academia Colombiana De Ciencias Exactas, Físicas Y Naturales. https://doi.org/10.18257/raccefyn.3579
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Abstract

Among other uses, potassium titanate enhances materials’ heat resistance in the ceramic industry, acts as a dielectric and component of piezoelectric devices in electronics, and facilitates the production of catalytic materials. Here, we used ilmenite concentrate (96%) from the Irshansky deposit in Ukraine’s Zhytomyr region, characterized by a high TiO2 content, as a promising raw material for synthesizing potassium titanate. We aimed to synthesize potassium titanate (K2TiO3) via alkaline leaching of ilmenite and to determine the optimal process conditions for achieving a high degree of titanium(IV) extraction. The methodology included alkaline leaching under controlled temperature, time, particle size, and FeTiO3:KOH molar ratio, followed by phase and morphological characterization of the product obtained. The experimental results showed that the optimal leaching conditions include an ilmenite particle size of ≤71 μm, a FeTiO3:KOH molar ratio of 1:2, a temperature of 453 K, and a leaching duration of 3 h, providing a titanium(IV) extraction degree of 86.7%. Further increases in temperature or alkali content resulted in only a slight increase in extraction efficiency (up to 89.7%), which was deemed economically unfeasible. The high efficiency of the process was attributed to an increased reaction surface area, optimal thermal conditions, and favorable thermodynamic parameters. A technological scheme for the potential industrial production of potassium titanate is proposed based on these results, with prospects for reduced energy consumption, improved environmental safety, and minimal raw material losses.

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