It could be seen that the presence of the AgNPs leads to a considerable improvement in EQE for short-wavelength range, which is consistent with the absorption spectra of P3HT:PCBM [23], as compared to the reference cells. Furthermore, the curves of AgNP-decorated cells decrease slightly in long-wavelength

range. This decrease could be attributed to the low light absorption in the silicon layer reduced by scattering and low absorptivity of the polymer in this wavelength range. However, it seems that there is no obvious difference of EQE among AgNP-decorated samples in the wavelength region of 800 to 1,000 nm. This phenomenon might be closely related to check details the optical confinement effect in the long-wavelength region. It has been reported that a dielectric shell surrounding SiNWs significantly reinforced their optical confinement and caused their resonant wavelength to red shift [28, 29]. In our hybrid structure, the P3HT:PCBM layer surrounding SiNWs could also induce a similar optical confinement. This selleck screening library effect resulted in considerable improvement in light absorption of low-energy photons, which could diminish the difference

of reflectance among AgNP-decorated samples in the wavelength region of 800 to 1,000 nm. Figure 7 EQE spectra of SiNW/organic hybrid solar cell. The black square line, red dot line, and blue up-triangle line represent the EQE of SiNW arrays decorated with AgNPs with diameters of 19, 23, and 26 nm, respectively. The green down-triangle line represents the EQE of bare SiNW array without AgNPs. Although the efficiencies of Carnitine palmitoyltransferase II our devices are much lower than those of commercial silicon solar cells, the results of our experiments proved good effects of AgNPs in the SiNW/organic hybrid solar cell very well. Several other methods may be used to increase the efficiency of this hybrid solar cell. For example, etching the silicon substrate with

an anodic aluminum oxide template could obtain a SiNW array with controlled size and GDC-0068 purchase excellent uniform distribution [30]. If we used a small-sized SiNW array to manufacture hybrid solar cells, the organic layer would become thinner, resulting in the improvement of carrier collection efficiency. On the other hand, a gas-phase polymerization method could be introduced in the polymer coating process to form a uniform thin layer on SiNWs, resulting in a core-shell-structured solar cell with lateral heterojunction [31]. Therefore, further efforts should be focused on these issues to improve the properties of SiNW/organic hybrid solar cells. Conclusions In summary, AgNP-decorated SiNWs were fabricated by metal-assisted chemical etching and electroless deposition. AgNP-decorated SiNW/organic hybrid solar cells were also demonstrated, treating them as double-junction tandem solar cells.