Semiconductor-to-metal surface reconstruction in copper selenide/copper heterostructures steered by photoinduced interlayer atom migration.

The photoinduced semiconductor-to-metal transition (PSMT) unveils crucial photodynamic mechanisms and holds great promise for information storage, sensing, optoelectronics, optical switches, etc. All previously reported PSMTs have occurred between two structural phases of the same material, lacking real-space evidence at the atomic or molecular level. Herein, we report atomic-scale observations of a photoinduced 'face changing': light irradiation transforms a semiconductor copper selenide (CuSe) surface layer on Cu(111) into a well-defined metallic Cu layer. Se atoms sink to form a new CuSe sublayer, while the original subsurface Cu atoms are lifted to the top layer. The CuSe-to-Cu transition barrier is significantly lower in the excited state compared to the ground state. Thermoactivation enables the reverse transition. The photoinduced CuSe-to-Cu and thermoactivated Cu-to-CuSe transitions are highly reversible. This work, which demonstrates PSMT between two distinct materials and photo-driven interlayer atom migration, unlocks an unconventional and intriguing route for PSMT and surface modification technologies.