At Omega Optical, our Research and Development (R&D) capabilities are at the forefront of optical innovation. We are committed to developing cutting-edge technologies that drive progress in various industries. Our dedicated R&D team leverages extensive expertise and state-of-the-art facilities to create custom solutions tailored to the unique needs of our clients. From pioneering new coating techniques to advancing multiphoton microscopy, Omega Optical’s R&D efforts are fueled by a relentless pursuit of excellence and a passion for discovery.
These coatings came out of the R&D department's desire for transparent electrodes with specific work functions that were not commercially available during work on a thin-film photovoltaic project. We have produced a number of variations including Indium Tin Oxide (ITO), Indium Zinc Oxide (IZO), Fluorinated Zinc Oxide (FZO) and Zinc Tin Oxide (ZTO) and are continually adding to this list. By choosing the correct material, we are able to tune the reflection edge and electrical properties of the film to meet your needs. TCO development also led to the introduction of a broad-band hot mirror that blocks all the way out into the IR.
An integral part of the Multispectral Scanning System described below, Omega has mastered the ability to coat fiber tips. Nearly any filter can be applied to the tip of a fiber optic (anti-reflection, bandpass, shortpass, longpass, etc). We have demonstrated optical filters on fiber tips up to 30 microns thick with good adhesion. The R&D department has perfected in-fiber monitoring and fixturing to enable this technology.
R&D began experimenting with absorbing semiconductors as an integral part of the thin-film photovoltaic project. An offshoot of this work was to develop filters using these materials. An ongoing effort is to fully characterize the complex refractive index values of these materials so predictive models of thin-film stacks can be developed and turned into a product. Absorbing materials can be used to replace colored glass for blocking and to reduce angle-sensitivity of filters. efficitur.
Our thin-film solar goal centers on creating a photovoltaic (PV) cell prototype enabling significant reductions in module cost and significant increases in module efficiency – leading to acceptable payback times. Key thin films in our cells include perovskites, organic absorbers, and electrodes that are both optically transparent and electrically conductive. We have settled on a thin-film photovoltaic window concept that exploits Omega's expertise in color-balancing to maximize efficiency while maintaining a neutral-colored transparent window. Basic research focuses on glass-to-glass sealing technologies, PV degradation mechanisms and TCO development. Focusing on building-integrated window applications minimizes the cost of substrates and installation. This effort has been co-funded by Omega Optical and the Department of Energy. We have an ongoing collaboration with the University of Vermont's Department of Physics in this area.
Our biomedical goal centers on developing a high-speed fiber-optic based multispectral confocal scanner that can enable real time imaging of cancer at the cellular level. Existing technologies have not combined sufficient spatial, spectral, and temporal resolution in one instrument. Standard imaging spectrometers are not fast enough to generate multispectral images at the speeds required in an operating room (< 1 image/sec). We have already demonstrated the ability to image autofluorescence (intrinsic fluorescence) in a small field of view (500 micron) and 10 wavelength channels within 0.1 s in a microscope format. This was done in collaboration with The Cancer Center and Pathology Departments at the University of Vermont Medical Center. We plan to translate this system into a hand-held probe that will generate larger (5 mm) images by the surgeons in the operating room. The 10 channel images are reduced to a single color-coded image using software algorithms. This will ultimately enable surgeons to assess surgical margins in real-time which should lead to fewer follow-up surgeries. Originally funded with a fast-track SBIR from the National Cancer Institute at the NIH, it has been internally funded since 2011. The technology can also be applied to other types of cancer, as well as to questions in basic research (for instance, neural regeneration studies, developmental biology, etc.) We are open to new collaborations in this area.
- High-Speed Multispectral Confocal Biomedical Imaging Journal of Biomedical Optics (2014)
- Multispectral Endoscopic Imaging Enabled by Mapping Spectral Bands into the Time Domain Frontiers in Optics (2016)
- Multispectral Imaging for Diagnosis & Treatment Proc. SPIE 8947 (2014)
High-Speed Multispectral Confocal Imaging Proc. SPIE 8587 (2013)
A natural extension of the project described above is the development of a confocal imaging flow-cytometer that can sample up to 12 wavelength bins and 2 scatter channels while the cell is traversing the scanning laser beam. Because the sample is flowing past the illumination/detection system, only a single scanning mirror is required to generate an image. Further, because the system was designed to detect very weak autofluorescence signals, single-cell detection of labeled cells (typical of flow-cytometry) is well within the signal-to-noise. The concept for this system was presented at Photonics West 2018 and won a Pi Photonics Best Paper award. We are actively looking for partners who are experts in flow systems and fluidics to help us move this concept to the next level.
Multispectral Flow Cytometry using Serial Fiber Arrays and a Single-Element Detector CYTO (2017);
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Full Optical Capabilities
Learn more about the full suite of capabilities which are trusted by leading Global OEM’s and their Start-up challengers to deliver the right photons, to the right place, at the right time.
R&D Success
DUV Transmission Grating
Patent-pending, our deep ultraviolet (DUV) transmission grating provides the performance of etched fused silica gratings at a fraction of the price, widely expanding the application set to point-of-care and hand-held devices.
Ultra-Narrow SWIR Filters
Omega has been producing small quantities of ultra narrowband (sub-nm FWHM) for many years for Astronomy applications (i.e. Hydrogen-alpha filters) in the visible wavelengths.
We are expanding into longer wavelengths using more durable sputtered oxide coatings. These are used in applications such as free-space optical communications.
Linear Variable Filters
Linear variable filters are bandpass filters that change center wavelength across one dimension of the part. They can be used as rudimentary spectrometers or in order-sorting applications. The spectral properties of the bandpass must be specified as described above as well as the gradient (nm/mm) across the part.
Filters on Fiber Tips
What started as a research project has turned into one of Omega's most unique capabilities- coating the tips of fiber optics with spectrally-complex coatings including broadband antireflection coatings, reflectors and our full-range of filters. We use the same plasma-assisted reactive magnetron sputtering (PARMS) system that produces coatings on flat-glass to provide extremely durable and versatile hard-oxide coatings on fiber tips.
Baffle Box Filters
In some cases, it is easier to design a reflective filter in the UV, which in transmission looks like a notch (or rejection band) filter, but when used in a reflective assembly as shown below, can attain high effective transmission over a narrow wavelength range. In these designs, the blocking OD is additive as the number of bounces increases, while the effect on %T is small.
Key supporting capabilities
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Optical Coatings
Omega coating heritage dates back to 1936, and spans a wide range of technologies: Sunglasses to space-borne sun-visors; halogen light bulbs to COVID-fighting UV-C lamps, supermarket scanners to modern printers, astronomical mirrors to prestigious art installations to entertainment optics: if an application requires a precision or decorative coatings we surely have a proven solution.
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Grating Manufacturing
We have the diffractive optics trifecta of multiple Ruling Engines, Holographic Mastering, and Lithographic exposure to create diffractive elements. Our in-house design and manufacturing processes provide standard or custom gratings for a range of applications, in both Original and Replicated formats.
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Specialty Patterning & Cutting
We produce more than just circles and rectangular shaped components. Challenge us to produce a complex shape or pattern demanded by your application.
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Metrology & Quality Assurance
We believe you cannot confidently make what you cannot measure, and therefore have invested in standard and custom metrology and inspection stations. Certified ISO 9001:2015. Lean manufacturing, including 6 Sigma methodologies and approaches to problem solving.
