Abstract
The production of cost-effective novel materials for PV solar cells with long-term stability, high energy conversion efficiency, enhanced photon absorption, and easy electron transport has stimulated great interest in the research community over the last decades. In the presented work, Cu/Cu(2)S-MWCNTs nanocomposites were produced and analyzed in the framework of potential applications for PV solar cells. Firstly, the surface of the produced one-dimensional Cu was covered by Cu(2)S nanoflake. XRD data prove the formation of both Cu and Cu(2)S structures. The length and diameter of the one-dimensional Cu wire were 5-15 µm and 80-200 nm, respectively. The thickness of the Cu(2)S nanoflake layer on the surface of the Cu was up to 100 nm. In addition, the Cu/Cu(2)S system was enriched with MWCNTs. MWCNs with a diameter of 50 nm interact by forming a conductive network around the Cu/Cu(2)S system and facilitate quick electron transport. Raman spectra also prove good interfacial coupling between the Cu/Cu(2)S system and MWCNTs, which is crucial for charge separation and electron transfer in PV solar cells. Furthermore, UV studies show that Cu/Cu(2)S-MWCNTs nanocomposites have a wide absorption band. Thus, MWCNTs, Cu, and Cu(2)S exhibit an intense absorption spectrum at 260 nm, 590 nm, and 972 nm, respectively. With a broad absorption band spanning the visible-infrared spectrum, the Cu/Cu(2)S-MWCNTs combination can significantly boost PV solar cells' power conversion efficiency. Furthermore, UV research demonstrates that the plasmonic character of the material is altered fundamentally when CuS covers the Cu surface. Additionally, MWCN-Cu/Cu2S nanocomposite exhibits hybrid plasmonic phenomena. The bandgap of Cu/Cu(2)S NWs was found to be approximately 1.3 eV. Regarding electron transfer and electromagnetic radiation absorption, the collective oscillations in plasmonic metal-p-type semiconductor-conductor MWCNT contacts can thus greatly increase energy conversion efficiency. The Cu/Cu(2)S-MWCNTs nanocomposite is therefore a promising new material for PV solar cell application.