SPECIAL NOTICE
99 -- TECHNOLOGY/BUSINESS OPPORTUNITY QUANTUM SCIENCE AND TECHNOLOGY PARTNERSHIPS
- Notice Date
- 9/16/2020 1:06:07 PM
- Notice Type
- Special Notice
- Contracting Office
- LLNS � DOE CONTRACTOR Livermore CA 94551 USA
- ZIP Code
- 94551
- Solicitation Number
- FBO458-20
- Response Due
- 10/29/2020 9:00:00 PM
- Archive Date
- 10/31/2020
- Point of Contact
- Connie Pitcock, Phone: 9254221072
- E-Mail Address
-
pitcock1@llnl.gov
(pitcock1@llnl.gov)
- Description
- Opportunity: Lawrence Livermore National Laboratory (LLNL), operated by the Lawrence Livermore National Security (LLNS), LLC under contract no. DE-AC52-07NA27344 (Contract 44) with the U.S. Department of Energy (DOE), is offering the opportunity to partner with LLNL to conduct research and development in quantum science and technology. Background: Quantum science and technology is a focal point of research at LLNL. Quantum-coherent devices offer the potential for unprecedented precision in sensing and the ability to directly simulate complex quantum phenomena that have no known efficient classical algorithms. Development and implementation of quantum technologies is expected to have a significant impact on our ability to address some of the most complex national security problems. Our teams study quantum science challenges from a broad range of perspectives, drawing on deep talent pools in areas such as physics, chemistry, optics, engineering, data science, and materials science. Our multidisciplinary research teams are exploring novel solutions that will enable development of a new generation of quantum computing and sensing systems. Our novel solutions include: Synthesis and characterization of materials with special quantum properties Developing a fundamental understanding and control of the sources of noise and decoherence in quantum systems Careful engineering of the interface between quantum and classical control, sensing, and computing elements Our research and development activities focus on five main priorities: Quantum-coherent device physics Quantum materials Quantum�classical interfaces Computing and simulation Sensing and detection Description:� LLNL is seeking industry partners to collaborate on quantum science and technology research and development in the following areas: Quantum-coherent device physics The building blocks of a quantum system are its highly specialized components, including superconducting qubits and resonators that enable better control of the electrical flow. Our physicists and materials scientists collaborate to design, fabricate, and characterize qubits and resonators that offer the performance needed for quantum computing and sensing systems. Our physicists combine qubits in new configurations to enable faster calculations, such as a system where all qubits are interconnected. They also develop qubits with unique resonator geometries, enabling better control of the electrical flow and improving coherence time, including 3D resonators fabricated via additive manufacturing with cavity shapes that enable better qubit control. Quantum materials Our materials science experts develop and optimize quantum materials with extremely low energy and exotic physical properties. These superconductive materials are needed to build quantum devices and systems, including scalable qubits that form the building blocks of quantum computing systems, as well as materials that will be needed by quantum sensors and quantum-enabled imaging devices. Our teams are engineering complex metamaterials with new geometries and tailored properties, as well as expanding our ability to design, synthesize, and manipulate the properties of quantum materials. We develop materials that can function at the extremely low temperatures required for quantum coherence, while remaining stable over long timeframes. The materials need to be immune to environmental noise and free from defects that can reduce quantum coherence and degrade performance. Quantum�classical interfaces Quantum computing systems require a high-fidelity classical interface to achieve qubit control and to conduct measurements of the quantum device. We leverage LLNL�s expertise with photonic systems, such as radar and laser systems, to develop and optimize a quantum�classical interface. Our researchers are exploring ways to use low-noise, high-fidelity, radio frequency signal generation, transport, and measurement to increase the information capacity of a novel quantum�classical interface. Computing and simulation Our multidisciplinary research teams design, develop, and evaluate prototype quantum computing systems, bringing us closer to demonstrating a fully programmable quantum computing system with powerful simulation capabilities. To date, our researchers have designed and built two fully programmable prototype systems, where they test new system architectures by evaluating design choices that affect connectivity, efficiency, complexity, and control. We are exploring ways to connect and control multiple qubits, to identify the ideal number of qubits in a system, and to isolate the system from the environment, control it, and prolong coherence. We are developing advanced quantum control techniques for quantum computing environments as well as new mathematical approaches to machine learning that are more amenable to implementation on quantum computers than today�s algorithms. Sensing and detection LLNL has a long history of developing sophisticated sensing and detection technology, and we are exploring ways to exceed the capabilities of today�s tools by exploiting quantum phenomena, such as entanglement, Bose�Einstein statistics, and wave�particle duality. We are exploring ways to manipulate superposition and entanglement to achieve multi-photon quantum states that can support ultra-high-resolution sensing and imaging capabilities. These atomic-scale, optical and microwave sensing capabilities are expected to provide control and intrinsic self-calibration for real-time, high-impact applications. New quantum sensing capabilities will support LLNL�s efforts to solve mission-relevant challenges in areas such as remote sensing, gravity gradiometry, and inertial motion sensors. For More Information:� Learn more about our research by exploring the sections below or by reading the Science & Technology Review article titled �Livermore Leaps into Quantum Computing.� More information on LLNL�s Quantum Science and Technology research program is available at https://quantum.llnl.gov/.� LLNL is seeking industry partners with a demonstrated ability to bring quantum science and technology innovations to the market. Moving critical technology beyond the Laboratory to the commercial world helps our licensees gain a competitive edge in the marketplace. All partnership and licensing activities are conducted under policies relating to the strict nondisclosure of company proprietary information.� Please visit the IPO website at https://ipo.llnl.gov/resources for more information on working with LLNL and the industrial partnering and technology transfer process. Note:� THIS IS NOT A PROCUREMENT.� Companies interested in commercializing LLNL's Quantum Science and Technology Partnerships should provide a written statement of interest, which includes the following: 1.�� Company Name and address. 2.�� The name, address, and telephone number of a point of contact. 3.� �A description of corporate expertise and facilities relevant to commercializing this technology. Written responses should be directed to: Lawrence Livermore National Laboratory Innovation and Partnerships Office P.O. Box 808, L-795 Livermore, CA� 94551-0808 Attention:� FBO 458-20 Please provide your written statement within forty-five (45) days from the date this announcement is published to ensure consideration of your interest in LLNL's Quantum Science and Technology Partnerships.
- Web Link
-
SAM.gov Permalink
(https://beta.sam.gov/opp/199c105fefeb472d959dd974ed3fe980/view)
- Record
- SN05799298-F 20200918/200916230158 (samdaily.us)
- Source
-
SAM.gov Link to This Notice
(may not be valid after Archive Date)
| FSG Index | This Issue's Index | Today's SAM Daily Index Page |