Two challenging problems still remain for optical absorbers consisting of an ultrathin planar semiconductor film on top of an opaque metallic substrate. One is the angle-insensitive mechanism and the other is the system design needed for broadband solar energy harvesting. Here, first we theoretically demonstrates that the high refractive index, instead of the ultrathin feature as reported in previous studies, is the physical origin of the angle insensitivity for ultrathin planar optical absorbers. They exhibit omnidirectional resonance for TE polarization due to the high complex refractive index difference between the semiconductor and the air, while for TM polarization the angle insensitivity persists up to an incident angle related to the semiconductor refractive index. These findings were validated by fabricating and characterizing an 18 nm Ge/Ag absorber sample (representative of small band gap semiconductors for photovoltaic applications) and a 22 nm hematite/Ag sample (representative of large band gap semiconductors for photoelectrochemical applications). Then, we took advantage of angle insensitivity and designed a spectrum splitting configuration for broadband solar energy harvesting. The cascaded solar cell and unassisted solar water splitting systems have photovoltaic and photoelectrochemical cells that are also spectrum splitters, so an external spectrum splitting element is not needed.
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机译:对于由在不透明金属衬底顶部上的超薄平面半导体膜组成的光吸收器,仍然存在两个具有挑战性的问题。一种是角度不敏感的机制,另一种是宽带太阳能收集所需的系统设计。在这里,首先我们从理论上证明高折射率,而不是先前研究中报道的超薄特征,是超薄平面光吸收器对角度不敏感的物理原因。由于半导体和空气之间的高复数折射率差异,它们对TE极化表现出全向共振,而对于TM极化,角度不敏感性一直持续到与半导体折射率相关的入射角。这些发现通过制造和表征18 nm Ge / Ag吸收体样品(用于光伏应用的小带隙半导体)和22 nm赤铁矿/ Ag样品(用于光电化学应用的大带隙半导体)进行了验证。然后,我们利用角度不敏感度的优势,设计了用于宽带太阳能收集的频谱分割配置。级联太阳能电池和非辅助太阳能水分解系统的光电和光电化学电池也是光谱分离器,因此不需要外部光谱分离元件。
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