Top 50 Nano Optics

Irradiant Technologies develops a 3D nano-optics and photonics fabrication platform that utilizes implosion fabrication lithography to create complex, non-contiguous geometries at nanoscale. This technology enables rapid prototyping and mass production of advanced optical components, addressing the challenges of miniaturization and integration in light-based systems.

NILT provides a full‑stack meta‑optics platform that designs, prototypes, and mass‑produces planar metalenses and diffractive optical components using nano‑imprint lithography. By replacing curved glass elements with sub‑wavelength nanostructures, it delivers thinner, lighter, and lower‑cost optical modules for AR/MR headsets, ultra‑compact cameras, LiDAR/ToF sensors, and display systems. The offering includes optical design, wave‑optics simulation, and high‑volume manufacturing, delivering ready‑to‑integrate components or turnkey manufacturing tools.

Morphotonics offers a large-area nanoimprinting platform for high-volume manufacturing of nanoscale optical components. Their integrated solution enables the precise replication of sub-100 nm features across meter-scale surfaces, accelerating the production of advanced displays and smart glasses.

Myrias develops all-inorganic printed meta-optics and AR/VR waveguides using direct nanoimprint lithography, enabling the production of lightweight, compact optical components with high refractive index and transparency. This technology reduces the size, weight, and part count of traditional optics, addressing the need for more efficient and cost-effective solutions in advanced imaging and augmented reality applications.

AllFocal Optics develops nanophotonic solutions that enhance display technology by providing natural visual clarity and comfort, particularly for users with vision impairments such as myopia and astigmatism. The company's technology, rooted in research from Cambridge University, ensures compatibility and scalability for next-generation visual experiences.

eyeo develops advanced image sensors using nanophotonic color-splitting technology to eliminate absorptive color filters. This innovation significantly boosts light sensitivity for improved low-light performance and enables smaller pixel sizes for higher resolution in compact designs.

Crest Optics provides custom design, fabrication, and coating of high‑performance optical components—including lenses, mirrors, prisms, and subsystems—using precision engineering and advanced material science. It offers end‑to‑end services from ray‑tracing design and rapid prototyping to full‑scale production with sub‑nanometer surface finish and ISO‑9001 quality control, supporting integration for aerospace, defense, semiconductor, medical imaging, and laser applications.

Lumotive develops Light Control Metasurface (LCM™) technology, which enables precise light manipulation at a sub-micron level for applications in 3D sensing, communications, and automation without moving parts. This technology addresses the need for compact, scalable, and reliable optical solutions in diverse environments, enhancing capabilities in industrial automation, smart spaces, and autonomous systems.

Nanosys provides proprietary quantum dots that offer precise control over light, color, and energy for enhanced product performance. Our advanced materials enable spectrum engineering for superior displays and new application development. We support customers in scaling production and exploring innovative uses for quantum dot technology.

UpNano manufactures high-resolution 3D printing systems utilizing two-photon polymerization (2PP) technology to produce microparts with feature sizes below 100 nm. Their service addresses the need for efficient, scalable production of complex microstructures in industries such as electronics, optics, and medtech.

ONI develops super-resolution microscopy tools, including the Nanoimager and Aplo Flow, to facilitate single-molecule imaging for researchers in various fields. Their technology simplifies sample preparation and data analysis, enabling more accurate and reproducible results in studies involving lipid nanoparticles and other biological samples.

Aluvia Photonics provides a CMOS‑compatible aluminium‑oxide photonic integrated circuit platform that supports continuous transmission from 200 nm to ~3 µm with ultra‑low waveguide loss and native rare‑earth‑doped on‑chip amplifiers. The offering includes multi‑project wafer prototyping, dedicated volume runs, and a library of pre‑qualified passive and active design blocks to accelerate development of broadband photonic systems for communications, LIDAR, quantum information and biomedical instrumentation.

Neurophos develops a photonic computing architecture that utilizes ultra-dense optical modulators to achieve 160,000 TOPS at 300 TOPS per watt, significantly outperforming traditional GPUs. This technology addresses the escalating demand for AI compute power by providing a solution that replaces 100 GPUs with a single processor while consuming only 1% of the energy.

HyperLight develops thin-film lithium niobate photonic integrated circuits (PICs) that deliver high bandwidth and low power consumption for applications in data centers, telecommunications, and sensing. Their technology addresses the need for efficient, high-performance electro-optic solutions with minimal on-chip loss and low drive voltage, enabling advanced communication systems and sensor functionalities.

Ephos designs and manufactures glass-based integrated photonic circuits using proprietary femtosecond laser writing techniques to minimize signal loss in computational devices. This technology enables the development of scalable classical and quantum infrastructures, addressing the need for efficient and high-performance computing solutions.

The startup manufactures silicon nitride photonic chips for optical communication applications, utilizing wafer-scale manufacturing and light propagation techniques to handle wavelengths from visible to near-infrared. This technology enables industries to achieve high-performance data transmission with minimal loss, addressing the need for efficient communication solutions in a data-driven world.

Polariton Technologies manufactures the fastest electro-optic modulators using plasmonic structures integrated into photonic circuits, enabling high-speed data transmission for next-generation transceivers. Their technology addresses the demand for increased bandwidth in telecommunications, achieving speeds of up to 3.2 terabits per second.

Midel Photonics designs and manufactures diffractive optical elements that shape and split laser beams. Their products enable efficient redistribution of laser light for various applications.

Miraex develops photonic sensors and distributed quantum computing solutions that utilize fiber optics to monitor critical assets in harsh environments, providing real-time digital data and alerts. Their technology integrates optical components on a millimeter scale, enabling reliable sensing and connectivity for low-energy signals at the quantum level.

Innolume designs and manufactures semiconductor diode lasers and optical amplifiers from 780-1350 nm. They offer a vertically integrated process, from epitaxy to packaging, providing high-performance photonic components tailored for medical, scientific, industrial, and networking applications.

Develops nanolayered metamaterials and AI-optimized LGRIN optics to create lightweight, high-performance solutions for industries such as defense, fusion energy, and electric vehicles. These technologies enable faster target acquisition in night vision systems, scalable power delivery in grids, and improved energy storage in capacitors, addressing challenges in efficiency, weight, and reliability.

NLM Photonics develops organic electro-optic modulation technology that enhances data throughput by up to four times while reducing power consumption by up to 50%. This technology addresses the high energy demands of data centers and next-generation communication systems, enabling efficient data transfer across various applications, including quantum computing and AI processing.

2Pi develops patented metasurface optics technology that produces ultra-compact, lightweight optical components with enhanced imaging quality and wider field-of-view for applications in consumer electronics, industrial automation, and automotive sectors. This technology overcomes the limitations of traditional optical systems, which are often bulky and costly, by enabling scalable manufacturing with reduced size, weight, power, and cost.

MICRO-LAM offers advanced optical manufacturing solutions using proprietary laser-assisted machining (LAM) technology and ultra-precision diamond tooling. Their patented OPTIMUS system machines challenging materials like glass optics with enhanced precision, reduced subsurface damage, and improved surface quality, enabling faster production of complex geometries.

Imagia designs and manufactures flat optical lenses using metamaterial principles to achieve complex optical functions that traditional lenses cannot provide. Their technology simplifies optical system design by reducing the number of components and alignment steps, enabling high-performance imaging and display systems.

Imagia designs and manufactures flat optical lenses using metamaterial principles to achieve complex optical functions that traditional lenses cannot provide. Their technology simplifies optical system design by reducing the number of components and alignment steps, enabling high-performance imaging and display systems.

ArgusEye develops sensor systems utilizing nanoplasmonic sensing and fiber optics for real-time monitoring of biological processes. Their technology enables in-line analysis, enhancing efficiency in bioprocessing by providing immediate data on critical quality attributes.

Tiny Bright Things develops microscopy technology that utilizes low-power visible light for the characterization of organic, inorganic, and synthetic samples at micron to sub-micron scales. This approach enables detailed analysis of morphology and complex structures with minimal sample preparation in both wet and dry environments.

Dispertech develops a system that simultaneously measures the size and scattering intensity of individual nanoparticles using optical techniques. This precise characterization is crucial for advancing applications in materials science and nanotechnology, where accurate nanoparticle analysis is essential for research and development.

Nexus Photonics develops photonic integrated circuits that combine active and passive materials on a single chip, enabling high-performance functionality across a wide range of wavelengths from blue to infrared. This technology addresses the need for compact, efficient solutions in various applications, enhancing capabilities in fields such as telecommunications and sensing.

Beacon Photonics develops a heterogeneous photonics platform that integrates advanced optical microsystems on a chip, significantly reducing the cost and size of photonic devices. Their technology addresses the limitations of traditional, expensive, hand-built optical systems, enabling high-performance applications in communications, sensing, and quantum technologies.

This company designs and manufactures silicon photonics chips for light emission and detection. Their advanced photonic components and systems, including nano-photonic sensors and integrated photonic circuits, leverage Taiwan's semiconductor manufacturing ecosystem.

XRnanotech manufactures high-precision nanostructured X-ray optics, including high-aspect-ratio Fresnel zone plates and ultra-stable diamond optics, for applications in scientific research, material testing, and medical imaging. The company provides customized optical solutions with resolutions down to 10nm, addressing the need for advanced imaging capabilities in various high-tech fields.

Iris Light Technologies develops photonic inks that enable the production of active opto-electronic components, such as lasers and LEDs, on silicon chips using high-quality semiconducting nanomaterials. This technology addresses the need for efficient manufacturing methods in the silicon photonics and printed electronics industries, particularly for energy-efficient data center applications.

OptoGlo utilizes nanotechnology to create transparent ultra-high-definition displays that enhance visual clarity and reduce bulk in electronic devices. This technology addresses the demand for lightweight, high-resolution screens in consumer electronics and professional applications.

Envue Technologies offers a label-free optical biosensing method for the characterization of single nanoparticles, enabling precise analysis of molecular weight, interactions, and conformations. This technology addresses the challenge of studying freely moving nano-objects, providing researchers with a sensitive and easy-to-use tool for in-depth molecular analysis.

The startup has developed a nanoscale imaging technology that measures the size and concentration of nanoparticles, enabling visualization of living entities such as viruses and extracellular vesicles without the need for labeling. This technology allows researchers to detect the presence of viruses in samples, facilitating more accurate analysis in various scientific fields.

Everix manufactures ultra-thin optical filters that enhance signal-to-noise ratios in compact optical devices, enabling improved performance in space-constrained applications. Their technology allows for conformal integration with non-flat surfaces, addressing the limitations of traditional coating methods and reducing the weight of optical components.

The startup develops photoresist materials and low-temperature processes for manufacturing high aspect ratio nanostructures and UV-curable optical coatings. These technologies enable the production of robust, high-refractive-index components essential for smart devices in augmented reality and OLED applications.

Prio Optics utilizes inkjet printing technology to manufacture customized optical filters on thin, flexible, or sensitive substrates, overcoming the limitations of traditional PVDCVD production methods. This approach enables cost-effective solutions for the optics and photonics industry, including patterned and large-area filters for applications in electronics and photovoltaics.

The startup develops a solid-state adaptive micromirror array for optical beam control, enabling precise digital manipulation of light. This technology replaces traditional optical front-end systems, offering enhanced speed, reduced size, and lower power consumption for improved performance in optical technology applications.

This startup automates 3D imaging of nanostructures using artificial intelligence and machine learning, converting raw 2D data into accurate 3D models within minutes. Their technology enhances the precision of sample preparation and STEM microscopy, enabling researchers and manufacturers to gain deeper insights into microstructures at the nanoscale.

The startup develops numerical modeling software for simulating metalenses, diffractive optical elements, and holograms, enabling precise design of nano-structured optics and flat lenses. This technology allows engineers and scientists to efficiently integrate planar optics into optical systems, enhancing performance and usability.

The startup develops adaptive optics technology, including transmissive wavefront modulators and reflectivity deformable mirrors, for precise wavefront sensing metrology. This enables businesses to create high-performance optical systems without the complexities typically associated with optical component development.

Solnil develops advanced optical materials and nanoimprint lithography processes for fabricating high-performance optical coatings and metasurfaces. Their proprietary resin formulations enable tunable refractive indices from 1.12 to 2.6 with ultra-low optical loss, facilitating the creation of next-generation optical components for AR and photonics.

This company develops silicon photonic circuits with organic electro-optic materials to improve light manipulation. Their technology enhances data transmission and communication, enabling clients to build faster and more efficient data communication infrastructures.

The startup develops a process for producing photonic integrated circuits (PICs) on thin-film lithium niobate (TFLN), enabling rapid design iterations within weeks at a lower cost. This silicon-compatible method facilitates seamless scaling of production in standard semiconductor fabrication facilities.

Lux Labs develops optical materials through nanophotonics and polymer fabrication techniques to enhance light manipulation in various applications. Their technology addresses the need for improved performance in optical devices, enabling more efficient energy use and better signal transmission.

The startup develops metasurface lenses that utilize meta-optics and advanced reconstruction software to create compact, wide-field tunable focal length optics. This technology enables precise optical data transformation for digital processing, providing customers with clear focus on objects without loss of field.

NanoLockin is developing a technology for the detection and analysis of nanoparticles using advanced spectroscopic methods. This technology provides precise measurements that enhance the understanding of nanoparticle behavior in various applications, addressing the need for reliable data in fields such as pharmaceuticals and environmental monitoring.