Light trapping in planar ultrathin-film solar cells is limited due to a small number of optical modes available in the thin-film slab. A nanostructured thin-film design could surpass this limit by providing broadband increase in the local density of states in a subwavelength volume and maintaining efficient coupling of light. Here we report a broadband metasurface design, enabling efficient and broadband absorption enhancement by direct coupling of incoming light to resonant modes of subwavelengthscale Mie nanoresonators defined in the thin-film active layer. Absorption was investigated both theoretically and experimentally in prototypes consisting of lithographically patterned, two-dimensional periodic arrays of silicon nanoresonators on silica substrates. A crossed trapezoid resonator shape of rectangular cross section is used to excite broadband Mie resonances across visible and near-IR spectra. Our numerical simulations, optical absorption measurements and photocurrent spectral response measurements demonstrate that crossed trapezoidal Mie resonant structures enable angle-insensitive, broadband absorption. A short circuit current density of 12.0?mA/cm2 is achieved in 210?nm thick patterned Si films, yielding a 4-fold increase compared to planar films of the same thickness. It is suggested that silicon metasurfaces with Mie resonator arrays can provide useful insights to guide future ultrathin-film solar cell designs incorporating nanostructured thin active layers.
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机译:由于薄膜板中可用的少量光学模式,平面超薄薄膜太阳能电池的光捕获是有限的。纳米结构薄膜设计可以通过在亚波长容积中的局部密度的局部密度和保持光的有效耦合来超越该极限。在这里,我们通过直接耦合到薄膜有源层中定义的亚波长度MIE纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米纳米群的谐振模式,实现高效和宽带吸收增强。理论上和实验地研究了吸收的原型,由硅基衬底上的光刻图案化的硅纳米阵列组成的原型。矩形横截面的交叉梯形谐振器形状用于横跨可见和接近IR光谱激发宽带MIE共振。我们的数值模拟,光学吸收测量和光电流光谱响应测量结果表明,交叉的梯形MIE谐振结构使角度不敏感,宽带吸收能够。在210℃厚的图案化Si膜中实现了12.0°Ma / cm 2的短路电流密度,与相同厚度的平面薄膜相比,产生4倍的增加。建议具有MIE谐振器阵列的硅质焊接件可以提供有用的见解,以引导结合纳米结构薄有源层的未来超薄膜太阳能电池设计。
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