Extremely wide wavelength range:

Super Achromatic Waveplates are capable of providing virtually complete wavelength-independent phase delay over a very wide wavelength range. This is one of its most significant advantages.

High Phase Delay Stability:

Thanks to the use of a variety of birefringent materials such as quartz, magnesium fluoride, and sapphire, and through precise optical design, superachromatic waveplates are able to provide a flat and stable phase delay over a wide spectral range.

High transmittance:

These waveplates are typically coated with a broadband coating to increase the transmittance of the laser or other light source and reduce energy loss.

Low Dispersion:

By eliminating dispersion, superachromatic waveplates are able to provide consistent polarization conversion over a wide wavelength band, which is especially important for applications that require high-precision polarization control.

High-precision machining:

The manufacturing process of superachromatic waveplates often requires high-precision machining and assembly techniques to ensure that the performance of the waveplates meets the design requirements.

Applications: Laser system, Spectral analysis, Optical Communication, Optical Instruments, Scientific research, etc.