Abstract
Organic solar cells are flexible and inexpensive, and expected to have a wide range of applications. Many transparent organic solar cells have been reported and their success hinges on full transparency and high power conversion efficiency. Recently, carbon nanotubes and graphene, which meet these criteria, have been used in transparent conductive electrodes. However, their use in top electrodes has been limited by mechanical difficulties in fabrication and doping. Here, expensive metal top electrodes were replaced with high-performance, easy-to-transfer, aerosol-synthesized carbon nanotubes to produce transparent organic solar cells. The carbon nanotubes were p-doped by two new methods: HNO3 doping via ‘sandwich transfer’, and MoOx thermal doping via ‘bridge transfer’. Although both of the doping methods improved the performance of the carbon nanotubes and the photovoltaic performance of devices, sandwich transfer, which gave a 4.1% power conversion efficiency, was slightly more effective than bridge transfer, which produced a power conversion efficiency of 3.4%. Applying a thinner carbon nanotube film with 90% transparency decreased the efficiency to 3.7%, which was still high. Overall, the transparent solar cells had an efficiency of around 50% that of non-transparent metal-based solar cells (7.8%).
Highlights
Single-walled carbon nanotubes (SWNTs) are expected to address current problems because they are mechanically flexible, made with cheap and abundant carbon, easy to synthesize, and suited to direct roll-to-roll processes[21]
Conductive SWNT films can be used as an electrode to replace indium tin oxide (ITO) in photovoltaics[24,25]
The SWNT films were p-doped with two dopants, HNO3 via sandwich transfer and MoO3 via bridge transfer
Summary
SWNTs are structurally the simplest class of carbon nanotubes with diameters in the range of 0.4–3.0 nm[22]. Li et al.[26] used SWNT films as the top electrode in perovskite solar cells. The HNO3-doped and MoO3-doped 60% transparent SWNT-laminated OSCs showed PCEs of 4.1% and 3.4%, respectively. Using 90% transparent SWNT films, which produced OSCs visually more similar to a window, resulted in PCEs of 3.7% and 3.1% for HNO3-doped and MoO3-doped, respectively, whereas the reference ITO-based OSC showed a PCE of 7.8%. Our transparent OSCs, which are suitable for window applications, were fabricated by doping through direct lamination and dry lamination of SWNT films for the top electrode (Fig. 1). We expect that the methods presented here will pave the way to future multifunctional OSCs
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