Effect of Laser Pulse Width and Intensity Distribution on the Crystallographic Characteristics of GeSn Film

Abstract: Germanium-tin (GeSn) alloy is considered a promising candidate for a Si-based short-wavelength infrared range (SWIR) detector and laser source due to its excellent carrier mobility and bandgap tunability. Pulsed laser annealing (PLA) is one of the preeminent methods for preparing GeSn crystal films with high Sn content. However, current reports have not systematically investigated the effect of different pulse-width lasers on the crystalline quality of GeSn films. In addition, the intensity of the spot follows… Show more

“…Apart from the formation of Ni(GeSn) alloys, laser annealing processes have mainly been employed to tailor and enhance the crystalline quality (grain growth, crystallization and so on) of GeSn layers during, or after, their low thermal budget growth [33]- [37]. Laser annealing was also used to reverse the stress in GeSn layers [36] or to modulate photodiode optoelectronic properties by Sn atoms redistribution [38].…”

Use of Nanosecond Laser Annealing for Thermally Stable Ni(GeSn) Alloys

“…Apart from the formation of Ni(GeSn) alloys, laser annealing processes have mainly been employed to tailor and enhance the crystalline quality (grain growth, crystallization and so on) of GeSn layers during, or after, their low thermal budget growth [33]- [37]. Laser annealing was also used to reverse the stress in GeSn layers [36] or to modulate photodiode optoelectronic properties by Sn atoms redistribution [38].…”

Use of Nanosecond Laser Annealing for Thermally Stable Ni(GeSn) Alloys

Study on the periodic structure of polycrystalline GeSn prepared by femtosecond pulse laser direct writing