Spaceflight ππ 2023 This #SBSP study by #Astrostrom for #ESA proposes a 29,339 m2 #solar βοΈ collector at the #Lagrange point, #SolarPanels from #Lunar π materials, transported by a #SpaceElevator π from the #Moon https://nebula.esa.int/sites/default/files/neb_study/2753/C4000136309ESR.pdf
The #UK π¬π§, #US πΊπΈ, #Japan π―π΅ and #China π¨π³ are now investing in #space based solar βοΈ power. The #atmosphere reflects around 30% of the #energy that reaches our planet while it absorbs around a quarter before it even reaches the Earth's surface. Space-based π solar panels can avoid this effect, but can remain in near-constant sunlight https://www.bbc.com/future/article/20251029-the-beam-dream-should-we-build-solar-farms-in-space
Based on the cost πΆ assumption of #SBSP, the projected value-adjusted levelised cost could even reach 69 EUR/MWh for the first system. Applying a learning curve metric already shows cost reduction potential in the setup of the first 10 SPS station deployments, leading to an estimated VALCoE of 49 EUR/MWh. This means that SBSP has the potential to even become a cost-competitive renewable technology https://www.rolandberger.com/en/Insights/Publications/Space-based-solar-power.html
π 2025 : The simulations show that if the swarm design can deliver #electricity at six to nine times the projected 2050 cost of ground PV, system #costs fall by 7%β15% π. At that price, #space -based #solar βοΈ can displace up to 80% of wind-plus-solar capacity and cut #battery needs by more than 70% https://www.sciencedirect.com/science/article/pii/S2542435125002557
Growing efficiencies of near-infrared #lasers make them preferable over #microwaves, allowing the transmission antenna on the spacecraft to be scaled down from hundreds of meters across to about half a meter π. #OverviewEnergy successfully tested a system that transmitted βmultiple thousands of wattsβ of power using a near-infrared laser from an aircraft flying at an altitude of 5,000 meters to a receiver on the ground https://spacenews.com/overview-energy-demonstrates-technologies-for-space-solar-power/
Space-based #solar βοΈ power : #ScienceFiction author Isaac #Asimov popularised the idea in π 1941. Advances in #robotics, wireless power transmission and sharply falling #LaunchCost are narrowing the gap between concept and reality https://www.scmp.com/opinion/china-opinion/article/3347692/why-chinas-space-based-solar-power-next-frontier-green-energy
With a fraction of the investment directed at other technologies, 90% of the barriers to #SBSP could be de-risked within five years, preparing it to scale π. The intensity of sunlight in space π is significantly higher, meaning space-based panels generate far more #energy π per square metre than their terrestrial counterparts, freeing up valuable land.
This superior energy density also translates into a dramatic reduction in material usage https://www.weforum.org/stories/2025/10/space-based-solar-power-energy-transition/
β’ Current international state of the art of #SBSP
β’ #ESA activities related to SBSP
http://large.stanford.edu/courses/2024/ph240/ferretti1/docs/esa-may22.pdf
2022, #ESA awarded two parallel cost-benefit analysis studies, which will evaluate the βbusiness caseβ for space-based solar power in #Europe πͺπΊ https://www.esa.int/Enabling_Support/Preparing_for_the_Future/Discovery_and_Preparation/ESA_reignites_space-based_solar_power_research
The_SunKeep dreaming