Knowledge

Why Thick Stainless Masks Cannot Achieve High-R...

Thick stainless steel shadow masks (0.3–0.5 mm) offer mechanical stability but cannot achieve high-resolution micro-patterns. This article explains why aspect ratio, laser cutting physics, and heat effects prevent thick masks...

Why Thick Stainless Masks Cannot Achieve High-R...

Thick stainless steel shadow masks (0.3–0.5 mm) offer mechanical stability but cannot achieve high-resolution micro-patterns. This article explains why aspect ratio, laser cutting physics, and heat effects prevent thick masks...

Laser-Cut vs Etched Shadow Masks | Resolution, ...

For high-resolution micro-patterns and rapid custom fabrication, laser cutting provides better accuracy, tighter tolerances, and lower cost compared to chemical etching. Etching is suitable for medium-sized features and volume production...

Laser-Cut vs Etched Shadow Masks | Resolution, ...

For high-resolution micro-patterns and rapid custom fabrication, laser cutting provides better accuracy, tighter tolerances, and lower cost compared to chemical etching. Etching is suitable for medium-sized features and volume production...

Minimum Feature Size & Tolerance Limits for Sta...

This guide explains the minimum feature size, tolerance limits, and design constraints for laser-cut stainless steel shadow masks used in PVD, CVD, and sputtering systems, helping research labs design manufacturable...

Minimum Feature Size & Tolerance Limits for Sta...

This guide explains the minimum feature size, tolerance limits, and design constraints for laser-cut stainless steel shadow masks used in PVD, CVD, and sputtering systems, helping research labs design manufacturable...

2000°C High-Temperature Furnace Design & Manufacturing

2000°C High-Temperature Furnace Design & Manufa...

Design and manufacture of custom high-temperature furnaces up to 2000°C for materials science, crystal growth, sintering, and advanced laboratory research.

2000°C High-Temperature Furnace Design & Manufa...

Design and manufacture of custom high-temperature furnaces up to 2000°C for materials science, crystal growth, sintering, and advanced laboratory research.

Etching

Technical overview of etching processes used in microfabrication, including chemical etching, plasma etching, and reactive-ion etching (RIE), with applications in semiconductors, MEMS, and thin-film devices.

Etching

Technical overview of etching processes used in microfabrication, including chemical etching, plasma etching, and reactive-ion etching (RIE), with applications in semiconductors, MEMS, and thin-film devices.

Photolithography

Photolithography is a core semiconductor fabrication process that uses UV light and photomasks to transfer micro-scale patterns onto substrates. This guide explains how photolithography works, why it is critical for...

Photolithography

Photolithography is a core semiconductor fabrication process that uses UV light and photomasks to transfer micro-scale patterns onto substrates. This guide explains how photolithography works, why it is critical for...