One of the major problems endangering plant growth and productivity worldwide is salt stress. This study aimed to assess the efects of potassium silicate (K2O3Si) on the physical, biochemical, and morphological characteristics of chicory (Cichorium intybus L.) under various levels of salinity stress. The plants were treated with K2O3Si at concen‑ trations of 0, 1, 2, and 3 mM and cultivated under diferent salt stress conditions (0, 80, 160, and 240 mM NaCl). The fndings revealed that salt stress led to decreased root and shoot dry weights, Fv/Fm ratio, chlorophyll a, b, and total chlorophyll, as well as inulin contents. However, foliar exposure to K2O3Si at all salinity levels resulted in improvements in the measured traits. As salinity levels increased, there was a corresponding increase in the accumulation of sodium ions (Na+) and a sharp reduction in potassium ions (K+) in the shoot. Nonetheless, treatment with K2O3Si caused a decrease in Na+accumulation and an improvement in K+ content under all salinity levels. Carotenoid content increased under 80 mM salinity stress, but decreased with higher salinity levels. Application of K2O3Si at all levels resulted in increased carotenoid content under salinity stress conditions. The content of MDA increased signifcantly with increasing salinity stress, particularly at 240 mM. However, foliar spraying with K2O3Si signifcantly decreased MDA content at all salinity levels. Salinity stress up to 160 mM increased the total phenol, favonoid, and anthocyanin contents, while 240 mM NaCl decreased the biosynthesis of phytochemicals. Additionally, the use of K2O3Si increased the content of total phenol, favonoid, and anthocyanin at all salt levels. Foliar application of K2O3Si increased the tol‑ erance of chicory plants to salinity stress by reducing MDA and increasing phenolic compounds and potassium content. These results suggest that exogenous K2O3Si can be a practical strategy to improve the growth and yield of chicory plants exposed to saline environments.
