Article ID Journal Published Year Pages File Type
735367 Optics and Lasers in Engineering 2011 9 Pages PDF
Abstract

Microstructures are usually fabricated on the surface of optical sheets to improve the optical characteristics. In this study, a new fabrication process with UV (ultraviolet) laser direct writing method is developed to embed microstructures inside the glass. Then the optical properties of glass such as reflection and refraction indexes can be modified. Single- and multi-layer microstructures are designed and embedded inside glass substrate to modify the optical characteristics. Both luminance and uniformity can be controlled with the embedded microstructures. Thus, the glass with inside pattern can be used as a light guide plate to increase optical performance. First, an optical commercial software, FRED, is applied to design the microstructure configuration. Then, UV laser direct writing with output power 2.5–2.6 W, repetition rate 30 kHz, wave length: 355 nm, and pulse duration 15 ns is used to fabricate the microstructures inside the glass. The effect of dot pattern in the glass such as the dot pitch, the layer gap, and the number of layer on the optical performance is discussed. Machining capacity of UV laser ranges from micron to submicrometer; hence with this ultrafast laser pulse, objectives of various dimensions such as dot, line width, and layers can be easily embedded in the glass by one simple process. In addition, the embedded microstructures can be made with less contamination. Finally, the optical performance of the glasses with various configurations is measured using a Spectra Colorometer (Photo Research PR650) and compared with the simulated results.

► A new process with UV laser direct writing is developed to embed micro-dot in glass. ► Optical properties of glass such as refraction index can be modified. ► Both luminance and uniformity can be controlled with the embedded micro-dot. ► Glass as a light guide plate with pattern can increase optical performance. ► With the UV laser, of dot, line, and layer can be embedded in the glass.

Related Topics
Physical Sciences and Engineering Engineering Electrical and Electronic Engineering
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