March 3, 2026

Metastable Materials with Linear Chains: Photoinduced Chemical Reactions in K 2 X 2 (X = S, Se, Te)

Key Points

Metastable materials emerge from photochemical reactions in semiconducting crystals, creating novel bonding configurations.
The study indicates a successful transformation facilitated by ultrafast light-induced phase transitions in specific materials.
Assessment involved computational modeling of the photochemical reaction processes for K2X2 crystals (X = S, Se, Te).
The findings may enable new avenues for practical applications of metastable materials as catalysts or superconductors.

Abstract

Metastable materials are attractive candidates for new catalysts, electrodes, and unconventional superconductors. Their unusual properties are rooted in nonstandard bonding, oxidation states, or coordination. However, potential applications of metastable materials are understudied, as it is difficult to obtain them via standard high-temperature solid-state synthesis methods, which result in the most thermodynamically stable products. Here, we computationally model a photochemical reaction that transforms synthetically available semiconducting crystals with a general formula K2X2 (X = S, Se, Te) into metastable materials with hypervalently bonded chains. The proposed reactions are an extension of well-documented ultrafast light-induced phase transitions, indicating the plausibility of these transformations under similar conditions.

Bookmark

Metastable Materials with Linear Chains: Photoinduced Chemical Reactions in K 2 X 2 (X = S, Se, Te)

Key Points

Abstract

Cite This Study