研究目的
Investigating the synergistic enhancements in the performances of dye-sensitized solar cells by the scattering and plasmon resonance of Au-nanoparticle multi-shell hollow nanospheres.
研究成果
The incorporation of HSAT nanospheres into DSSCs significantly enhances their performance due to the synergistic effects of LSPR and strong light scattering. The optimal DSSC with 3.0% HSAT achieved a maximal Jsc of 15.83 mA cm?2 and PCE of 7.21%, representing improvements of 21.0% and 20.4%, respectively, over pure TiO2-based DSSCs. These enhancements are attributed to improved light absorption and utilization, reduced interface transmission resistance, and increased electron lifetime.
研究不足
The study focuses on the synergistic effects of scattering and plasmon resonance in DSSCs, but the underlying mechanisms and potential for further optimization are not fully explored. Future research may need to investigate the synergistic and complementary effects of different functions more thoroughly.
1:Experimental Design and Method Selection:
Multi-shell hollow SiO2@Au@TiO2 (HSAT) nanospheres were synthesized by a multi-step method. Composite photoanodes and DSSCs with different amounts of HSAT nanospheres were studied.
2:Sample Selection and Data Sources:
PS@SiO2@Au@TiO2 (PSAT) nanospheres were synthesized and annealed to form HSAT nanospheres.
3:List of Experimental Equipment and Materials:
Transmission electron microscope (TEM), Energy-dispersive X-ray spectroscopy (EDXS), UV-vis-NIR spectrophotometer, electrochemical station CHI660C.
4:0C. Experimental Procedures and Operational Workflow:
4. Experimental Procedures and Operational Workflow: Synthesis of HSAT nanospheres, preparation of photoanodes and DSSCs, characterization of microstructures and chemical elements, measurement of J-V curves, IPCE, EIS, and OCVD.
5:Data Analysis Methods:
Analysis of light absorption, reflection, and transmission characteristics, dye loading, J-V curves, IPCE spectra, EIS spectra, and OCVD curves.
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