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Stanford Advanced Materials Unveils New Optical and Nonlinear Crystals

Stanford Advanced Materials (SAM), headquartered in Santa Ana, California, has officially announced the launch of an exciting new series of optical and nonlinear crystals tailored for the burgeoning fields of photonics and laser research. This announcement is significant as the demand for advanced materials across various precision optical applications continues to grow, presenting an opportunity for SAM to expand its innovative product offerings.

New Product Series

The newly introduced series encompasses five unique additions to SAM's product line: PPLN (Periodically Poled Lithium Niobate), MGLN (Magnesium-Doped Lithium Niobate), BIBO (Bismuth Borate), CaF₂ (Calcium Fluoride), and PPKTP (Periodically Poled Potassium Titanyl Phosphate). Each crystal type is designed to meet specific requirements for cutting-edge research and industrial applications in laser technology.

PPLN - Periodically Poled Lithium Niobate

PPLN stands out with its exceptional ability to facilitate high-efficiency nonlinear wavelength conversion. It boasts a broad transparency range from 350 to 5200 nm and supports versatile quasi-phase matching structures. Its superior nonlinear coefficient and stable performance under regulated temperatures make it an optimal choice for compact and economical laser systems. Typical applications for PPLN include second-harmonic generation (SHG), optical parametric oscillators (OPO), and quantum optics experiments.

MGLN - Magnesium-Doped Lithium Niobate

MGLN is characterized by its high optical damage threshold, low absorption loss, and a stable refractive index. These features render it highly suitable for room-temperature phase matching and applications in optical modulation, wavelength conversion, high-power lasers, and telecommunications. This crystal type ensures reliable performance in various nonlinear optical devices, enhancing both stability and efficiency.

BIBO - Bismuth Borate

BIBO offers an impressive nonlinear coefficient that outperforms other materials, providing up to four times the effectiveness of LBO and two times that of BBO. Its high damage threshold allows for efficient frequency conversion, particularly in visible and blue light ranges. BIBO is notably effective in applications involving SHG and optical parametric amplifiers, where high efficiency is paramount.

CaF₂ - Calcium Fluoride

CaF₂ is celebrated for its broad transmission capabilities across ultraviolet to infrared wavelengths. This crystal ensures low dispersion and high optical clarity, making it a go-to choice for high-resolution imaging, spectroscopic systems, and various optical components such as lenses and prisms.

PPKTP - Periodically Poled Potassium Titanyl Phosphate

PPKTP features a structure that enables efficient quasi-phase matching, which is complemented by a nonlinear coefficient that is three times that of conventional KTP. This makes it an excellent candidate for applications in SHG, quantum optics, and the generation of entangled photons within the transparency range of KTP.

Commitment to Innovation

With these enhancements in its product portfolio, SAM reaffirms its reputation as a reliable supplier of advanced crystal materials, committed to fostering research and development in photonics. The new range of optical and nonlinear crystals is designed to provide technical excellence and customizable solutions, facilitating the needs of both researchers and industrial applications.

SAM's initiative is a clear reflection of its dedication to innovation, quality, and customer satisfaction in the highly competitive market for advanced materials. Founded in 1994, Stanford Advanced Materials has grown into a prominent provider, offering over 7,000 advanced materials for aerospace, technology, medical, and other sectors demanding high performance. As they continue to invest in research and development, SAM remains at the forefront of providing scalable solutions to challenges in materials science.

In conclusion, the introduction of these innovative optical and nonlinear crystals by Stanford Advanced Materials is poised to significantly advance the capabilities of researchers and engineers alike, paving the way for further breakthroughs in laser technology and photonics research.