Directed high-energy infrared laser beams for photovoltaic generation of electric power at remote locations

APL Energy Pub Date : 2024-04-02 DOI:10.1063/5.0197277

R. Soref, Francesco De Leonardis, G. Daligou, O. Moutanabbir

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Abstract

Transferring energy without transferring mass is a powerful paradigm to address the challenges faced when the access to, or the deployment of, the infrastructure for energy conversion is locally impossible or impractical. Laser beaming holds the promise of effectively implementing this paradigm. With this perspective, this work evaluates the optical-to-electrical power conversion that is created when a collimated laser beam illuminates a silicon photovoltaic solar cell that is located kilometers away from the laser. The laser is a CW high-energy Yb-doped fiber laser emitting at a center wavelength of 1075 nm with ∼1 m2 of effective beam area. For 20 kW illumination of a solar panel having 0.6 m2 of area, optical simulations and thermal simulations indicate an electrical output power of 3000 W at a panel temperature of 550 K. Our investigations show that thermo-radiative cells are rather inefficient. In contrast, an optimized approach to harvest laser energy is achieved by using a hybrid module consisting of a photovoltaic cell and a thermoelectric generator. Finally, practical considerations related to infrared power beaming are discussed and its potential applications are outlined.

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用于偏远地区光伏发电的定向高能红外激光束

在不转移质量的情况下转移能量是一种强大的范例，可用于应对在当地无法或不可能获得或部署能量转换基础设施时所面临的挑战。激光束有望有效实现这一范例。从这个角度出发，本研究评估了准直激光束照射距离激光器数公里之外的硅光电太阳能电池时产生的光电转换。激光器是一种 CW 高能掺镱光纤激光器，中心波长为 1075 nm，有效光束面积为 1 m2。我们的研究表明，热辐射电池的效率很低。与此相反，通过使用由光伏电池和热电发电机组成的混合模块，可以优化激光能量收集方法。最后，我们还讨论了与红外功率传输相关的实际考虑因素，并概述了其潜在应用。

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APL Energy

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