AEROSPACE

           Delivering 5 GW to the grid would require a vast   with advances likely to spill over into mainstream
          orbital array. A representative concept might use a   terrestrial photovoltaics.
          solar collector spanning ~50–60 km , a transmitter
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          ~1 km in diameter, and a ground rectenna about      NASA’s vision for space-based
          10 km wide. Billions of high-efficiency photovoltaic   power beaming
          cells would feed microwave generation units—such     Unlike the ESA, NASA focuses on experimental
          as solid-state power amplifiers, traveling-wave tubes,   demonstrations, modular prototypes, and cutting-edge
          or klystrons—with individual conversion efficiencies   component development, involving energy transmission
          exceeding 70%.                                      between spacecraft.


           At 5.8 GHz (λ ≈ 52 mm), achieving safe power        After testing low-power transmission modules
          density and low loss requires limiting beam         designed to explore beam steering, transmission
          divergence to ~100 µrad and maintaining pointing    efficiency, and receiver optimization, including small
          accuracy near 10 µrad. Such precision is beyond     arrays of klystron-type microwave oscillators and
          the routine capability of current spaceborne        high-efficiency photovoltaic converters for laser
          communications hardware.                            reception, NASA’s long-term aim is to make SBSP
                                                              scalable, flexible, and resilient—not only for civilian use
           Among obstacles are high launch costs,             but also for enhancing future missions where energy
          large-scale robotic assembly in orbit, and addressing   resupply is difficult. While it doesn’t yet have a timeline
          environmental concerns, such as optical pollution   for deploying gigawatt-level systems like the ESA’s
          for astronomy, radio-frequency interference, and    program, NASA’s work underpins much of the theoretical
          potential biological effects of low-level microwave   and technological foundation.
          exposure. While SBSP remains technologically
          demanding and capital-intensive, pilot-scale        Caltech’s pioneering space solar power test
          systems could appear in the 2030s, with large-scale   In early 2023, Caltech deployed its Space Solar Power
          commercial deployment possible in the 2040s.        Demonstrator aboard a SpaceX Falcon 9 to evaluate
                                                              key technologies for orbital solar energy systems.
          SPACE SOLAR POWER INITIATIVES                       The mission validated three subsystems: lightweight
           Several nations (Japan, China, Korea, U.S., U.K.) are   deployable structures, high-efficiency photovoltaic
          actively researching SBSP systems, but three projects   arrays, and MAPLE—an experimental microwave array
          look well placed to advance technology in the next   for WPT. MAPLE achieved two benchmarks: transmitting
          years, run by the European Space Agency (ESA),      energy from orbit to Earth and intra-spacecraft
          NASA, and Caltech.                                  transmission between rectennas. The ultimate goal
                                                              is the commercial deployment of a constellation of
          ESA’s Solaris project                               modular spacecraft that can beam solar energy to Earth.
           The ESA’s Solaris initiative is exploring the feasibility
          of SBSP systems, targeting commercial deployment    WHAT TO EXPECT NEXT
          by around 2040. Concept studies envision             WPT has evolved from theoretical concept to tested
          kilometer-scale satellites in GEO, up to 2 km across   technology, promising solutions for untapped energy
          and weighing about 11,000 metric tons. These        access. In orbital solar platforms, the physics of
          massive platforms would be assembled from roughly   electromagnetism converges with precision engineering
          100 heavy-lift launches and designed to deliver     to open new frontiers.
          gigawatt-scale power, on par with nuclear plants.
                                                               As global demand for clean energy surges and space
           A near-term milestone planned for the early 2030s   infrastructure becomes increasingly accessible, WPT
          is a ~1-MW orbital demonstrator that could scale up   could emerge as a cornerstone technology of the
          through automated modular expansion to gigawatt     21st century. Building and deploying a 1-MW orbital
          capacity.                                           plant—and eventually scaling to hundreds of
                                                              megawatts or more—will likely require an international
           A key enabling technology is III–V multijunction   consortium, comparable to Europe’s CERN in
          photovoltaics (e.g., InGaP/GaAs/Ge or InGaAs-based).   fundamental physics or ITER in nuclear fusion
          By stacking layers with different bandgaps, each    research. This time, however, the goal is not to discover
          sub-cell captures a distinct part of the solar      ephemeral particles but to fully harness the privilege
          spectrum, boosting total conversion efficiency.     of having a star at just the right distance from an
          Efficiency is expected to rise from 30% today to    inhabited planet.
          40% within a decade when commercially deployed,

  28      OCTOBER 2025 | www.powerelectronicsnews.com                                                                                                                                         OCTOBER 2025 | www.powerelectronicsnews.com   29