When it comes to selecting optical materials for high-performance applications, synthetic sapphire, fused quartz, silica, borosilicate glass, and soda lime glass are frequently considered. Each has distinct properties that make them suitable for specific uses, and understanding their differences is key for making informed choices.
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Synthetic sapphire, made from Aluminum Oxide (Al2O3), is a single crystal material with unique qualities. It stands out for its extreme hardness, second only to diamond, making it highly resistant to scratches, wear, and impact. Sapphire also offers exceptional optical clarity, transmitting up to 98.5% of light and performing well in a broad spectrum from UV to infrared (190 nm to 5 microns). It conducts heat but is an electrical insulator. Its high thermal stability, remaining unchanged at temperatures up to °C, makes it ideal for demanding environments where both mechanical and optical qualities must be preserved.
Despite its superior properties, sapphire has limitations. Its production costs are high due to complex and energy-intensive manufacturing processes. It cannot be molded or shaped like glass; instead, it must be ground and polished, restricting the sizes and shapes it can take. Additionally, larger sapphire pieces, especially of lower quality, are prone to thermal shock, which can lead to breakage if not uniformly heated.
Fused quartz and fused silica are amorphous forms of SiO2. They are known for their excellent thermal shock resistance, thanks to their extremely low coefficient of expansion, making them ideal for applications where temperature variation is a concern. These materials can handle continuous temperatures up to °C and brief exposures to °C, making them suitable for high-temperature environments.
Their transmission properties are impressive, ranging from 175 to 3 microns, though they fall short of sapphires full range. One advantage of fused quartz and silica is their versatilitythey can be melted, drawn, and molded into various shapes, offering flexibility in applications like semiconductor equipment.
However, they are more prone to surface devitrification, sagging over time at high temperatures, and are vulnerable to certain chemicals and high-radiation environments. While they are less expensive than sapphire for larger parts, the cost of fabrication can still be significant.
Borosilicate glass, commonly known by brand names like Pyrex, is valued for its relatively low cost and good thermal resistance, making it useful in laboratory settings and everyday applications like cookware. It is less scratch-resistant than quartz and sapphire, but easier to work with due to its lower melting point, making fabrication cheaper.
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However, borosilicate glass has its drawbacks, particularly when exposed to temperatures above 450°C. It is not as resistant to thermal shock as fused quartz or sapphire, and it is vulnerable to chemical leaching over time, limiting its use in high-purity environments.
Soda lime glass is the most widely used form of glass, representing about 90% of glass products globally, including windows and dinnerware. Its inexpensive, easy to mass-produce, and offers reasonable optical clarity. However, it is highly prone to thermal shock and chemical leaching, making it unsuitable for high-performance or high-purity applications. Additionally, it has poor scratch resistance compared to borosilicate glass and sapphire.
Sapphire is the go-to material for high-performance optical applications requiring extreme durability, optical clarity, and thermal stability. Fused quartz and silica offer excellent thermal shock resistance and versatility, while borosilicate and soda lime glass provide cost-effective solutions for less demanding environments. The choice between these materials depends on the specific requirements of the application, including cost, durability, and thermal and optical performance.
Heres an overview table comparing the advantages and disadvantages of synthetic sapphire, fused quartz, fused silica, borosilicate glass, and soda lime glass:
Sapphire as material can has any traces of Cr and Ti (3+). But the concentration of these impurities is very small. You can measure the fluorescence of sapphire at first and then the fluorescence your samples through sapphire window. As to fused silica or optical glasses it will be depend from raw material quality too.
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