Star Catcher and Intuitive Machines Demonstrates Power Beaming for Lunar Surface Operations

Star Catcher and Intuitive Machines Demonstrates Power Beaming for Lunar Surface Operations

Star Catcher and Intuitive Machines have achieved a major milestone in lunar technology, successfully demonstrating power beaming capabilities that could support long-duration missions on the Moon. This breakthrough comes as interest intensifies around the lunar South Pole, a region attracting scientists, space agencies, and commercial innovators due to its potential reserves of water ice and strategic importance for exploration. 

Deep craters remain in permanent shadow, creating cold traps where ice may have accumulated over billions of years and offer a possible source of life support and fuel for future missions. These deposits, if confirmed and accessible, could enable a sustained human presence. With its combination of resource potential and location advantages, the South Pole has become a focal point for NASA’s Artemis program and other international lunar initiatives. 

To support this vision, new technologies are being tested to overcome the region’s harsh environmental constraints, including how lunar terrain vehicles receive power. One promising advancement is Star Catcher Industries’ orbital energy grid, which is designed to deliver power on demand to spacecraft and lunar vehicles by collecting sunlight in orbit, converting it into laser-based energy, and beaming it wirelessly to solar panels on the lunar surface. In recent tests at NASA’s Kennedy Space Center, Star Catcher successfully demonstrated how beamed power could support operations in extreme environments by transmitting energy to Intuitive Machines’ Moon RACER Lunar Terrain Vehicle.

During Star Catcher’s multi-day test campaign, the team surpassed the previous wireless power transmission benchmark set by the U.S. Defense Advanced Research Projects Agency (DARPA) earlier this year and proved that high-efficiency optical beaming can deliver meaningful power levels to standard solar panel without requiring custom receivers. The results suggest that future missions could receive scalable, on-demand energy without the need for extensive ground infrastructure, dramatically simplifying deployment and extending mission reach. 

Rethinking Power Delivery for the Lunar Surface

Traditional power sources like solar panels and regenerative fuel cells perform reliably in sunlit regions but are poorly suited to shadowed terrain, especially during the 150-hour lunar night. Solar arrays require precise placement, extensive surface area, and complex deployment mechanisms, adding significant mass and setup time to missions. Regenerative fuel cells, while capable of storing energy for extended periods, involve cryogenic systems and gas storage tanks that further increase weight and operational complexity. Combined, these systems can account for hundreds of kilograms of a vehicle’s total mass and drive up mission costs due to added weigh and engineering overhead. To address these limitations, scientific, commercial, and industry organizations alike are seeking ways to reduce mission mass, complexity, and duration, enabling operations that previously were out of reach. 

One emerging solution to the Moon’s power constraints is optical power beaming, which is a method of wirelessly transmitting concentrated solar energy from lunar orbit to surface vehicles. This approach bypasses the need for labor-intensive and costly ground infrastructure, such as fixed solar farms or buried power lines, which are difficult to deploy in rugged terrain. Instead, it delivers energy directly from orbit and is designed to intelligently support both real-time operations and back-up power needs. By enabling continuous operation in shadowed regions and reducing reliance on bulky onboard systems, optical power beaming offers a path to lighter, more flexible vehicle designs and longer mission durations.  

Building for Expanding Space Infrastructure 

By delivering energy directly from orbit, Star Catcher helps reduce the need for heavy onboard systems and complex ground infrastructure, enabling continuous activity in shadowed regions and through the long lunar night. With its first on-orbit demonstration planned for 2026 and full-scale multi-orbit deployment targeted for 2030, Star Catcher could help reshape how missions are powered, supported, and sustained at the Moon’s South Pole. 

The orbital power grid represents the kind of innovative technology that could help power and support the space infrastructure Intuitive Machines is building, including its Space Data Network (SDN) and space delivery services. As missions become more autonomous and distributed across lunar and cislunar space, they require both reliable energy and persistent connectivity. Optical power beaming enables continuous operations in shadowed regions and throughout the lunar night, while Intuitive Machines’ infrastructure ensures real-time coordination, data delivery, and mission control across surface and orbital assets. Together, these systems form a scalable foundation for extended exploration and commercial activity in space. 

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GNSS Constellations - A list of all GNSS satellites by constellations

beidou

Satellite NameOrbit Date
BeiDou-3 G4Geostationary Orbit (GEO)17 May, 2023
BeiDou-3 G2Geostationary Orbit (GEO)09 Mar, 2020
Compass-IGSO7Inclined Geosynchronous Orbit (IGSO)09 Feb, 2020
BeiDou-3 M19Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M20Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M21Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 M22Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 I3Inclined Geosynchronous Orbit (IGSO)04 Nov, 2019
BeiDou-3 M23Medium Earth Orbit (MEO)22 Sep, 2019
BeiDou-3 M24Medium Earth Orbit (MEO)22 Sep, 2019

galileo

Satellite NameOrbit Date
GSAT0223MEO - Near-Circular05 Dec, 2021
GSAT0224MEO - Near-Circular05 Dec, 2021
GSAT0219MEO - Near-Circular25 Jul, 2018
GSAT0220MEO - Near-Circular25 Jul, 2018
GSAT0221MEO - Near-Circular25 Jul, 2018
GSAT0222MEO - Near-Circular25 Jul, 2018
GSAT0215MEO - Near-Circular12 Dec, 2017
GSAT0216MEO - Near-Circular12 Dec, 2017
GSAT0217MEO - Near-Circular12 Dec, 2017
GSAT0218MEO - Near-Circular12 Dec, 2017

glonass

Satellite NameOrbit Date
Kosmos 2569--07 Aug, 2023
Kosmos 2564--28 Nov, 2022
Kosmos 2559--10 Oct, 2022
Kosmos 2557--07 Jul, 2022
Kosmos 2547--25 Oct, 2020
Kosmos 2545--16 Mar, 2020
Kosmos 2544--11 Dec, 2019
Kosmos 2534--27 May, 2019
Kosmos 2529--03 Nov, 2018
Kosmos 2527--16 Jun, 2018

gps

Satellite NameOrbit Date
Navstar 82Medium Earth Orbit19 Jan, 2023
Navstar 81Medium Earth Orbit17 Jun, 2021
Navstar 78Medium Earth Orbit22 Aug, 2019
Navstar 77Medium Earth Orbit23 Dec, 2018
Navstar 76Medium Earth Orbit05 Feb, 2016
Navstar 75Medium Earth Orbit31 Oct, 2015
Navstar 74Medium Earth Orbit15 Jul, 2015
Navstar 73Medium Earth Orbit25 Mar, 2015
Navstar 72Medium Earth Orbit29 Oct, 2014
Navstar 71Medium Earth Orbit02 Aug, 2014

irnss

Satellite NameOrbit Date
NVS-01Geostationary Orbit (GEO)29 May, 2023
IRNSS-1IInclined Geosynchronous Orbit (IGSO)12 Apr, 2018
IRNSS-1HSub Geosynchronous Transfer Orbit (Sub-GTO)31 Aug, 2017
IRNSS-1GGeostationary Orbit (GEO)28 Apr, 2016
IRNSS-1FGeostationary Orbit (GEO)10 Mar, 2016
IRNSS-1EGeosynchronous Orbit (IGSO)20 Jan, 2016
IRNSS-1DInclined Geosynchronous Orbit (IGSO)28 Mar, 2015
IRNSS-1CGeostationary Orbit (GEO)16 Oct, 2014
IRNSS-1BInclined Geosynchronous Orbit (IGSO)04 Apr, 2014
IRNSS-1AInclined Geosynchronous Orbit (IGSO)01 Jul, 2013
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