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 1 - 10 of 61
Researchers at RPI have developed a conceptual notebook/tablet/laptop device that integrates the ability to capture written text onto a flexible screen which can be rolled up after use into storage compartments. The device provides users a dedicated wide screen display for written text/image/drawing capture, is portable and easy to store with screen retraction capability via…
Space exploration within the commercial, business, and military sectors continues to increase, and the development of an autonomous navigation system capable of guidance navigation anywhere in the solar system free from the use of Earthbound orbiting satellites is required to ensure that these operations can be performed safely and accurately. Researchers at Rensselaer created…
Researchers at RPI are developing a cognitive logic-enabled AI that can operate on multiple screens and in multiple environments for the K-12 sector. Declining public school math and science test scores have concerned American politicians and educators since the 1980s. This educational failure coincides with the large number of employees unable to fill the growing number of…
Researchers at RPI have developed a mixed-reality museum installation called the “World of Plankton (WOP).” WOP offers users a multisensory, interactive game based on phytoplankton ecology. Thanks to a virtual touch pool, users can manipulate and augment imagery of specific fish, microalgae, and other aquatic flora and fauna. Doing so launches sound effects, animation and…
Rensselaer inventors created a nanocomposite fiber that promotes quick coagulation during hemorrhage resulting in reduced mobility and improved survival. The nanofiber composite is comprised of halloysite nanoclay, a natural occurring aluminosilicate nanoclay that exhibits a hollow tubular scroll structure. Hemostatic products on the market are effective in the short-term but…
Using raw materials (thermoplastic pellets and rolls of fiber tows), this invention will continuously impregnate fiber tows with molten thermoplastic resin for fabrication of custom composite shapes, unlike current methods, which do not use raw materials and are extremely expensive processes. The ‘In Situ’ process can be used to either directly “print” composite parts in an…
Rensselaer inventors created a multi-launch system and capture method to effectively clean up debris in a cost-effective manner. Operationally, the method consists of deploying a small-sized object called the CubeSat. This is a small satellite with a low mass and can be part of the launch of another larger satellite or other space-based object. The CubeSat is launched into…
Alkaline exchange membranes (AEMs), also called anion exchange membranes, allow transportation of anions (ex: OH-, Cl-, Br-, etc.) from the cathode to the anode in electrochemical reaction. AEMs are the most critical component of AEM fuel cells, water electrolysis, and certain batteries, sensors, and actuators. Many AEM materials tend to degrade easily under high alkaline.…
New processes are proposed for preparation of novel, highly reactive, renewable substrate oxetane polymers, making it possible to use cationic oxetane photopolymerizations in many high-speed coatings, printing inks, adhesives, as well as in additive manufacturing processes such as stereolithography, digital imaging and in ink-jet printing. Specifically, an epoxide accelerant,…
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…