"This project has the potential to advance power beaming by orders of magnitude, which could radically reshape society's relationship with energy," said Dr. Paul Jaffe, who leads the POWER program at DARPA. "A wireless energy web could unlock power from new and diverse sources, including from space, and rapidly and reliably connect them to energy-starved consumers."
To support rapid development, the optical energy relays designed in POWER's phase one will be demonstrated in pods carried by existing aircraft in the project's second phase. Additionally, power beaming will enable smaller, less expensive future aircraft since fuel storage and engine volume could be dramatically reduced. This will be explored through conceptual designs in phase one.
Eventually these new, small, distributed platforms could provide cost-effective aircraft with unlimited range and endurance to support military missions. Each relay design will be evaluated based on accurate and efficient energy redirection, wavefront correction for high beam quality, and throttleable energy harvesting. In the third and final phase of the program, the relays will be demonstrated through an airborne optical pathway that aims to deliver 10 kilowatts of optical energy to a ground receiver that is 200 kilometers away from the ground source laser.
"Energy underpins every human activity, including defense. We need ways to deliver energy that overcome the vulnerabilities and other shortcomings of our current paradigm," explains Jaffe. "The next leap forward in optical power beaming could hinge on relay technologies."
Effective relays are a critical missing component necessary for a practical, flexible, and adaptive wireless energy web. These relays will overcome the unacceptable conversion losses that occur when changing from propagating waves to electricity repeatedly in a multiple-hop network. Relays also enable high-altitude transmission, which is vastly more efficient than beaming power through the thick, turbulent, lower atmosphere. This high-altitude optical layer will provide the long-range, high throughput backbone for the wireless energy web.
"Each of the selected teams proposed unique technical approaches to the power beaming relay problem, ranging from novel combinations of existing technologies to high-risk, high-reward technological innovations," said Jaffe. "The range of proposed solutions encompasses a balance of assured performance and potential breakthroughs in size, weight, and power to enable small distributed systems for the future wireless energy web."
The first phase will include benchtop demonstrations of critical technologies and is expected to last 20 months with potential for a three-month option of additional risk reduction efforts. The second phase will involve an open solicitation in early 2025 and will focus on integration of the relay technologies onto an existing platform for a low-power, airborne demonstration.
Related Links
Defense Advanced Research Projects Agency
Powering The World in the 21st Century at Energy-Daily.com
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