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Researchers propose and numerically analyze a solar-pumped laser system using an ytterbium-doped thin-disk gain medium combined with dome and spherical concentrators to enable multipass solar pumping. The ytterbium-based design achieves comparable lasing thresholds to conventional neodymium systems while offering up to three times higher output power and superior scalability. Critically, a spherical concentrator configuration enables radiation-balanced lasing, meaning the gain medium is self-cooled through anti-Stokes fluorescence emission, with dual-wavelength pumping extending this capability to significantly lower solar pump intensities than previously feasible.
Why it matters
Self-cooled, solar-pumped lasers could reduce the thermal management burden in space-based and terrestrial laser systems, making renewable laser-energy conversion more practical and scalable. This work opens a path toward compact, thermally stable laser platforms powered directly by sunlight without reliance on conventional electrical infrastructure.
arXiv:2601.00649v2 Announce Type: replace
Abstract: Solar-pumped lasers, predominantly based on neodymium gain media, offer a promising route to renewable laser-energy conversion and space-based photonics; however, their performance has been constrained by thermal loading and limited power scalability. Here, we propose and numerically investigate a solar-pumped ytterbium thin-disk gain medium combined with a dome concentrator, which enables multipass solar pumping and enhanced absorption. The design yields comparably low lasing thresholds for neodymium- and ytterbium-doped media, while ytterbium provides superior power scalability, enabling up to threefold higher output power. We further identify ytterbium-doped medium combined with a spherical concentrator as a viable solar-pumped, radiation-balanced configuration, achieving self-cooled lasing at solar pump intensities of 28.5 kW cm-2 within the 1020-1033 nm window of the solar spectrum. We further demonstrate that dual-wavelength pumping overcomes the limitations imposed by low solar intensity and concentration constraints, enabling radiation-balanced lasing at orders-of-magnitude lower solar pump intensities. The proposed spherical-concentrator-based design enhances pump absorption while allowing efficient escape of anti-Stokes fluorescence. These results establish multi-pass, solar-pumped ytterbium lasers as a compact, scalable, and sustainable platform for high-performance solar-pumped lasers.