Fabrication by Spin-Coating and Optical Characterization of Poly(styrene-co-acrylonitrile) Thin Films

Abstract: The optical characteristics of poly(styrene-co-acrylonitrile) thin films obtained by spin-coating of polymer blend in tetrahydrofuran were investigated by spectroscopic ellipsometry, spectrophotometry, and atomic force microscopy. Film thickness can be broadly varied by changing the polymer concentration.The film thickness dependence on PSAN concentration shows a non-linear behavior that can be explained by a concentration-dependent viscosity. According to previously proposed models, prepared solutions are clo… Show more

“…It can be spin coated after dilution in solvent at 1 − 4/wt% to achieve films of the desired thickness. 7 The next sections focus on the development of the key components in the photonic circuit, i.e. the waveguides and directional couplers.…”

Laser-written Mach Zehnder interferometer in silica with surface-written sensing arms and sub-micron thick doped-polymer film for increased evanescent field interferometric methane sensing

“…It can be spin coated after dilution in solvent at 1 − 4/wt% to achieve films of the desired thickness. 7 The next sections focus on the development of the key components in the photonic circuit, i.e. the waveguides and directional couplers.…”

Laser-written Mach Zehnder interferometer in silica with surface-written sensing arms and sub-micron thick doped-polymer film for increased evanescent field interferometric methane sensing

“…In the realm of materials science and thin film fabrication, the spin coating process stands as an indispensable technique, offering a thin film deposition technique with precise control over film thickness, uniformity, and morphology. Thin film coatings, characterized by their nanometer to micrometer thickness, have become integral in various applications across industries such as semiconductor generation, optical and solar panel coatings, consumer electronics, and biomedical engineering research [1][2][3][4], owing to the profound impact of thin films on material properties and device functionalities. The spin coating method has emerged as a pivotal step in the creation of high-performance, tailored thin films, in part due to being relatively inexpensive and simple to execute in both research and industrial settings [1].…”

Utilizing Machine Learning to Model Interdependency of Bulk Molecular Weight, Solution Concentration, and Thickness of Spin Coated Polystyrene Thin Films

“…In the realm of materials science and thin film fabrication, the spin coating process stands as an indispensable technique, offering a thin film deposition technique with precise control over film thickness, uniformity, and morphology. Thin film coatings, characterized by their nanometer to micrometer thickness, have become integral in various applications across industries such as semiconductor generation, optical and solar panel coatings, consumer electronics, and biomedical engineering research (1)(2)(3)(4)(5), owing to the profound impact of thin films on material properties and device functionalities. The spin coating method has emerged as a pivotal step in the creation of high-performance, tailored thin films, in part due to being relatively inexpensive and simple to execute in both research and industrial settings (1).…”

Utilizing Machine Learning to Model Interdependency of Bulk Molecular Weight, Solution Concentration, and Thickness of Spin Coated Polystyrene Thin Films