Free-form matrix of lenses
Our Matrix of Freeform Lenses is engineered with an array of lenses, each featuring unique, non-traditional geometries that extend well beyond standard circular or elliptical designs. This Microlens Matrix allows for exceptional precision in beam shaping and mode propagation across multiple axes, dramatically enhancing the functionality and efficiency of compact all-fiber optical systems, harnessing the […]
Free-form lens
Our Freeform Nanostructured Lenses are designed for superior control and efficiency in light manipulation by leveraging the unique properties of freeform geometries, extending beyond the conventional circular or elliptical shapes. This advanced design enables unparalleled precision in beam shaping, significantly enhancing the performance and versatility of compact optical systems.
Free-form fibre
Our Nanostructured Fibers feature cores with free-from core symmetry, beyond just circular or elliptical, allowing for precise beam shaping and mode propagation and enchancing the capabilities of compact all-fiber optical systems.
High-Order Nanostructured Vortex
Our High-Order Nanostructured Gradient Index Vortex Phase Components (HO-nVPC) are designed for the efficient generation of optical vortices with high topological charges. Developed through sophisticated nanostructuring techniques, these components are capable of converting Gaussian beams into vortex beams with topological charges up to 5 in both visible and near-infrared regions. Optimized for integration into both […]
Broadband Infrared NanostructuredGRIN Microlens Array
Our Broadband Infrared Gradient Index Microlenses Arrays are crafted using advanced nanostructurization techniques, tailored for mid-infrared applications. Made from a specialized blend of glasses, these microlenses achieve a continuous parabolic refractive index distribution across the infrared spectrum. Designed for seamless integration into both fiber-optic and free-space optical systems, they deliver unparalleled performance and quality for […]
Broadband Infrared Nanostructured GRIN Microlens
Our Broadband Infrared Gradient Index Microlenses are crafted using advanced nanostructurization techniques, tailored for mid-infrared applications. Made from a specialized blend of glasses, these microlenses achieve a continuous parabolic refractive index distribution across the infrared spectrum. Designed for seamless integration into both fiber-optic and free-space optical systems, they deliver unparalleled performance and quality for a […]
Large Diameter Nanostructured GRIN Microlens
Large diameter nanostructured GRIN microlenses, enhanced with temperature-controlled diffusion are designed for superior performance across a broad wavelength spectrum.
Nanostructured GRIN Lenses Array(Shack-Hartman sensor)
Our High-Resolution Shack-Hartmann Sensor, leveraging the nanostructured GRIN lens technology, sets a new standard for wavefront distortion measurement. This sensor utilizes a hexagonal array of hundreds of GRIN microlenses, each of tens of µm in diameter, to provide unparalleled precision in detecting and analyzing wavefront distortions. This novel approach results in a completely flat element, […]
Achromatic Nanostructured GRIN Microlens
Our Achromatic Nanostructured Gradient Index (nGRIN) Microlenses, designed to revolutionize near-infrared imaging and beam manipulation. These microlenses boast achromatic correction across a broad spectral range (600–1550 nm), ensuring nearly wavelength-independent performance. Unlike traditional optics that suffer from chromatic aberrations due to the dispersive nature of glass, our nGRIN microlenses maintain a consistent focal plane, thanks […]
Microaxicon
Our Nanostructured Gradient Index Microaxicons are designed for seamless integration with optical fibers. These cutting-edge microaxicons leverage advanced nanostructured optics and gradient index (GRIN) technology to offer unparalleled precision and efficiency in light manipulation. Ideal for a wide range of applications, including optical trapping, microfabrication, and optofluidics, they provide enhanced performance across different media, thanks […]