Abstract
Near ultraviolet (λ ≈ 400 nm) femtosecond laser annealing (400 nm-FLA) in a scanning mode was employed to crystallize amorphous silicon (a-Si) films at room temperature. The average grain size of polycrystalline silicon annealed was studied as a function of the incident laser fluence and beam overlap or the number of laser shots irradiated. In general, the grain size can be enlarged by either increasing the beam overlap at a fixed laser fluence or increasing the laser fluence for a fixed number of laser shots. An apparent threshold for the onset of rapid enlargement of grain size was observed for processing at ∼90% overlap and fluences above 25 mJ/cm2. A maximum grain size of ∼280 nm was attained at a laser fluence of 30 mJ/cm2 and overlap of 93.75%, beyond which the grain size attained was smaller, and eventually, ablation was observed at an overlap of 97.5% and higher. These trends and observed surface morphology of annealed samples suggest that the crystallization mechanism is like sequential lateral solidification, similar to 800 nm-FLA and excimer laser annealing. Raman spectroscopic studies show that the degree of crystallization achieved with 400 nm-FLA is even higher than that of 800 nm-FLA. Cross-sectional scanning electron microscopic images indicate that the 100 nm-thick a-Si film is not fully crystallized. This can be explained by the much shorter penetration depth of 400 nm light than that of 800 nm light in a-Si.
Highlights
Optical energy in the controllable form from state-of-the-art laser sources has provided unique solutions in materials processing and precision nano-fabrication in the fields of electronics, optoelectronics, micro- and nanomachining, new materials synthesis, and medical and biological applications.[1,2] Lasers have been broadly accepted as indispensable tools in industries with applications ranging from cutting fine intricate cardiovascular stents to drilling of guide vanes in the aerospace industry to welding of thick steel for the ship building industry.[3]
Employing near IR (λ = 800 nm) Femtosecond laser annealing (FLA) assisted by spatial scanning of the laser strip spot, which constitutes sequential lateral solidification (SLS),[23] we reported crystallization of amorphous silicon (a-Si) films into polycrystalline silicon with grains as large as ∼800 nm with the substrate at 400 ○C while requiring laser fluence as low as ∼45 mJ/cm[2] and a lesser number of laser shots.[24]
The average grain size achieved by 800 nm-FLA was ∼150 nm, which is smaller than that reported here for 400 nm-FLA at optimum operating conditions
Summary
Optical energy in the controllable form from state-of-the-art laser sources has provided unique solutions in materials processing and precision nano-fabrication in the fields of electronics, optoelectronics, micro- and nanomachining, new materials synthesis, and medical and biological applications.[1,2] Lasers have been broadly accepted as indispensable tools in industries with applications ranging from cutting fine intricate cardiovascular stents to drilling of guide vanes in the aerospace industry to welding of thick steel for the ship building industry.[3]. Femtosecond laser ablation[4] was shown to exhibit unique capabilities for microand nano-machining in a variety of materials, including transparent materials.[5]. Crystallization is one of the most important applications of laser processing of bulk materials. Laser-induced crystallization or annealing is nowadays widely used in the semiconductor manufacturing industry.[6,7,8,9] Crystal engineering of amorphous silicon (a-Si) is essential for fabrication of polycrystalline silicon (pc-Si) thin-film transistors used in flat panel displays as well as photovoltaics. Excimer laser annealing (ELA)[9] is currently the technology of choice for such applications
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