technologies available for licensing

Rensselaer Polytechnic Institute has a variety of technologies ranging from chemicals to lighting systems to algorithms and everything in-between. Rensselaer’s technologies can help you start a company or be a great addition to your current technology portfolio. To see what technologies are currently available for licensing at Rensselaer, please use the search below. If you have a technology need that Rensselaer’s technologies don’t currently solve, please reach out to IPO to discuss more your needs.

Use arrow keys to navigate
Displaying 21 - 30 of 62
Computed Tomography (CT) is an important tool in diagnostic imaging. It plays a key role in diagnosis and intervention. Many advanced CT systems use wide detector arrays, multiple sources, andor very fast rotation speed, for important clinical applications (e.g., coronary artery and whole organ perfusion imaging). As a result, modern CT scanners are expensive and are typically…
Existing batteries suffer from performance deficiencies, for example, they have limited power density and may drain rapidly when used for certain applications. By employing sulfur in their cathodes, LiS batteries can realize substantially greater energy densities than existing energy storage devices. Sulfur by itself is not a suitable electrode material due to its poor…
This technology relates to adaptive optical devices, and particularly to liquid lenses. Such optical devices avoid the increased weight and fabrication complexity associated with moving solid lenses. This technology utilizes a lens magnification control for adjusting magnification of the liquid lens by increasing a volume of protruding liquid residing in a chamber.
This technology relates to anion exchange membranes with enhanced stability to high pH environments including poly(arylene sulfone) or poly(arylene ketone) with anion exchange groups. Membranes according to this technology are simple to produce and have good mechanical properties, improved alkaline stability, as well as good anionic conductivity. This technology is…
This technology relates to active flow control using an active roughness actuator. The active roughness actuator includes a surface having an aperture; a compliant layer covering the aperture; a chamber containing a fluid and a piezoelectric surface mechanically coupled to the chamber. The chamber is in fluid communication with the compliant layer via the at least one…
This technology relates to semiconductor devices and growth techniques in the field of III-N semiconductors. For example, the technology provides a semiconductor device with a substrate comprising a groove. A buffer layer is formed on a surface of the groove. The buffer layer has at least one material chosen from AIN, GaN or AlxGa1-xN, where x is between zero and one. An…
This technology relates to a photopolymerizable class of vinyl ether oligomers which can find application in the areas of coatings, adhesives, printing inks, photoresists and high impact composites. The versatile photopolymerization capability makes these oligomers an excellent strategic candidate for shrinkage control coatings in place of acrylates. These oligomers include…
This technology relates to a high thermal conductivity thermal interface material that allows for the formation of an interconnected, spanning, high thermal conductivity network within the matrix of a polymeric material using nano particles. This material can yield two orders of magnitude higher thermal conductivities than the non-network counterpart, as well as factorial…
This technology provides an LED design that can greatly improve polarization selectivity, 10:1, resulting in greater efficiency of the LED. The technology lies within a photonic crystal bi-refringent polarization rotator and an oxide spacer. The design blue-shifts transmission, which greatly improves overall efficiency of the LED by recycling wasted light and increasing…
This technology relates to an ultra high efficient LED system with the capability to modify an LEDs radiation pattern by changing its physical dimension-emission beam shape. The ultra high efficiency and redistribution of light has been achieved without the use of a back reflector. The ultra high efficiency can be controlled by changing the size of the nanorods within the…