Licensing Opportunities for Quantum and Photonics Technologies

Quantum technology represents one of the most promising frontiers of modern science, potentially revolutionizing industries from computing to healthcare and beyond. At the University of babyÖ±²¥app, cutting-edge quantum research is not only advancing theoretical knowledge but also driving practical applications.

The university is at the forefront of this exciting field, leveraging its robust academic and research capabilities to push the boundaries of what quantum technologies can achieve. CU's focus on commercializing quantum research discoveries stems from a robust ecosystem of interdisciplinary collaboration that facilitates the transition from laboratory discoveries to market-ready technologies.

Many of our technologies that are available for licensing are not published online. Contact our licensing team to discuss opportunities and for information on our full portfolio of technologies.

Questions?

Joshua Bennet

Joshua Bennett · Senior Licensing Manager and Director of the Lab Venture Challenge

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Featured CU Quantum and Photonics Technologies

Mid-IR Optical Frequency Comb

Optical Frequency Combs are a Nobel Prize-winning technology developed at CU Boulder and the National Institute of Standards and Technology (NIST). They create infrared light to allow for molecular fingerprinting or substance identification. Current comb sources are restricted to wavelengths below 6 µm, which only allows for identifying certain molecules in a discrete spectrum. This technology allows for the theoretical identification of all molecules across the spectrum with greater precision and accuracy.

Researchers

Abijith Kowligy (), Alexander Lind (), Henry Timmers (), Scott Diddams (CU Boulder Electrical, Computer & Energy Engineering), Scott Papp (CU Boulder Physics)

Patent Status

Issued US Patent

Recent Publications

 (Optica)

Potential Industry Applications

Biotech, Environment and Sustainability, Cleantech, Smart Cities, Therapeutics, Diagnostics, Hardware and Instrumentation, Medical Devices, Optics, Quantum, Aerospace, Advanced Materials

Atomic Clocks—100% all-optical time scale

Atomic clocks are the current and future of geo-location applications. World-renowned physicist Jun Ye (CU Boulder Physics, ) and his team have created a state-of-the-art atomic clock utilizing Nobel Prize-winning optical frequency combs. The invention is an all-optical time scale that operates entirely at optical frequency to provide greater accuracy and stability than any other current technology.

Latest Milestone

Estimated Time Error of 48±94 ps over 34 days

Researchers

Jun Ye (CU Boulder Physics, ), Eric Oelker (), William Milner (), John Robinson (CU Boulder Physics '22, ), Colin Kennedy (), Tobias Bothwell (CU Boulder Physics '21, ), Khruv Kedar (), Terry Brown (; CU Boulder Electrical, Computer & Energy Engineering)

Patent Status

Issued US Patent

Recent Publications

 (Nature Photonics)

Potential Industry Applications

Biotech, Environment and Sustainability, Cleantech, Smart Cities, Hardware and Instrumentation, Optics, Quantum, Aerospace, Advanced Materials

Measurement and feedback on a superconducting qubit using casualty and tunable coupling

In quantum computing, accurately measuring qubit readouts is an ongoing problem. To address this quantum error correction problem, researchers at CU Boulder and the University of Innsbruck have created a superconducting amplifier device comprising a parametric amplifier and a readout cavity external to the superconducting amplifier device. The tunable coupling allows an entangled signal to transfer from the readout cavity directly to the parametric amplifier with a single directionality.

Latest Milestone

Demonstrated viability without the need for a magnetic resonator

Researchers

Eric Rosenthal (), Konrad Lehnert (CU Boulder Physics, ), Christian Schneider ()

Patent Status

US Issued Patent

Recent Publications

(APS)

Potential Industry Applications

Hardware and Instrumentation, Optics, Quantum

Quantum Quartz—Converting quantum signals through a quartz medium

Sound waves travel much slower than the speed of light. Therefore, engineers can achieve exciting signal processing in the acoustic domain if RF can effectively be converted to sound. Quartz is the best medium for this type of work in the quantum computing industry; however, there have been significant issues with finding the proper geometry of the material—until now.

Latest Milestone

Operative at temperatures below 10 K

Researchers

Alec Emser (), Konrad Lehnert (CU Boulder Physics, ), Brendon Rose (), Lucas Sletten ()

Patent Status

US Patent Pending

Recent Publications

(ResearchGate)

Potential Industry Applications

Biotech, Manufacturing, Environment and Sustainability, Cleantech, Artificial Intelligence (AI) and Machine Learning, Information Technology, Software, Cybersecurity, Diagnostics, Hardware and Instrumentation, Medical Devices, Optics, Robotics, Quantum, Aerospace, Advanced Materials

World’s first photonic mm-wave frequency synthesizer

The world’s first photonic millimeter wave frequency synthesizer utilizes the Nobel Prize-winning Optical Frequency Comb technology invented at CU Boulder and NIST; this novel approach can create virtually any frequency (microwave to terahertz) in one device. Critical applications include LIDAR and spectroscopy, among others.

Latest Milestone

Integrated on chip

Researchers

Jizhao Zang (CU Boulder Physics, ), Scott Papp (CU Boulder Physics)

Patent Status

Issued US Patent

Recent Publications

 (IEEE Xplore)

Potential Industry Applications

Environment and Sustainability, Smart Cities, Hardware and Instrumentation, Optics, Quantum, Aerospace

Environmentally robust, compact and inexpensive photonic resonator

Latest Milestone

>100,000 finesse

Researchers

Wei Zhang (CU Boulder Chemistry), Liron Stern, Scott Papp (CU Boulder Physics)

Patent Status

US Patent Pending

Recent Publications

(Optica)

Potential Industry Applications

Hardware and Instrumentation, Optics, Quantum

Featured CU Quantum and Photonics Startups

Infleqtion is a quantum atomic company developing quantum computing, sensing and signal processing hardware.

Industry: Quantum, Hardware & Instrumentation
Funding Stage: Series B Round or beyond

Continuous methane emissions monitoring for the oil and gas industry that reduces data liability, relieves the risk of super emitters and delivers on voluntary and regulatory compliance frameworks.

Industry: Environment and Sustainability, Cleantech, Hardware and Instrumentation, Optics, Quantum
Funding Stage: Series A Round

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Developing advanced chip-scale quantum sensing for next-generation position, navigation and timing capabilities.

Industry: Hardware and Instrumentation, Quantum, Aerospace, Advanced Materials, Robotics, Optics
Funding Stage: Seed Round

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Based on semiconductor quantum dot technologies perfected over the past 30 years at the National Institute of Standards and Technology (NIST), Icarus Quantum is developing the first of the building blocks of quantum internet.

Industry: Information Technology, Software, Cybersecurity​, Smart Cities, Hardware and Instrumentation, Optics, Quantum, Advanced Materials
Funding Stage: Series A Round

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CUbit Quantum Initiative

The image shows two masculine researchers in a well-equipped electrical engineering lab. They are gathered around a workbench, intently focused on their projects. The lab is filled with various electronic components, tools, and equipment.

The CUbit Quantum Initiative reinforces babyÖ±²¥app’s prominence in quantum information science and technology, partners with regional universities and laboratories, links closely with quantum-intensive companies, and serves a spectrum of local, regional and national interests, including workforce development.

Visit the CUbit Website