Room-temperature deposited fluorine-doped tantalum pentoxide for stable organic solar cells

Abstract

Earth-abundant transition metal oxides deposited at room temperature with low-cost methods suitable for large area manufacturing can offer advances in many fields of energy related devices. Here we report the room-temperature deposition of a fluorine-doped tantalum pentoxide using a home-made, low-cost hot-wire deposition system. This novel tantalum oxyfluoride material is super hydrophobic, ultra-transparent within the visible spectrum, and possesses adequate conductivity and suitable valence band and conduction band extrema for acting as efficient hole extraction and electron blocking layer in organic solar cells with the forward architecture. By inserting this material in the form of nanoparticles deposited on top of the commonly used as hole transport layer poly(3,4-ethylenedioxythiophene) polystyrene sulfonate, higher efficiencies compared to the reference cells without the nanoparticles were demonstrated in solar cells based on blends of polymer donors with either a fullerene (where maximum achieved efficiency was improved from 6.07% to 7.90%) or a non-fullerene acceptor (reaching values of 13.48% compared to 11.32% of the reference cell). Moreover, significant improvement in device stability was achievd in unencapsulated devices continuously exposed in a humid environment for 500 h. This work demonstrates the unambiguous potential of well-designed metal oxide materials as charge transport and blocking interlayers and protective buffers in organic solar cells and beyond. Home-grown fluorine-doped tantalum pentoxide nanoparticles deposited on top of PEDOT:PSS hole transport layer results in around 19% improved power conversion efficiency and an improved stability in organic solar cells. • Room-temperature deposition of fluorine-doped tantalum pentoxide. • Improved hole extraction and electron blocking properties. • Ta 2 O 5 :F - an inorganic protective buffer layer. • A 19% improved efficiency in organic solar cells. • Improved stability of fullerene and non-fullerene acceptor.