Can -conjugated polymers be used in organic photovoltaics?

π-Conjugated polymers show promising potential in the application of organic photovoltaics, including organic solar cells (OSCs) and organic photodetectors (OPDs) because of merits of light-weight, flexibility, facilely tuned color, large-scaled solution-processability, etc.

Can conjugated polymers be used in organic-silicon hybrid heterojunction solar cells?

For these reasons, conjugated polymers have found extensive application in organic-silicon hybrid heterojunction solar cells and pure organic solar cells, to afford flexible devices at a lower cost.

Are -conjugated polymers suitable for solar cells?

5. Conclusions π-Conjugated polymers have attracted considerable and significant recognition in the area of solar cells owing to their flexibity, ease of synthesis, light weight, tunability of optical and electrical properties through structural modifications, and solution processability.

Are -conjugated polymers a hole transporting layer?

In this regard, the scope of this review article presents a comprehensive summary of the applications of π-conjugated polymers as hole transporting layers (HTLs) or emitters in both organic solar cells and organic-silicon hybrid heterojunction solar cells.

Which p-type conjugated polymers are used in hybrid organic-silicon heterojunction solar cells?

In this regard, amongst the many p-type conjugated polymers, PEDOT:PSS has found more application as HTL layer in hybrid organic-silicon heterojunction solar cells. This is due to its good film forming properties, excellent transparency, low processing temperature, and high work function (~5.2 eV), which render it an effective HTL [137,138,139].

What are the design strategies of -conjugated polymers?

This review highlights general design strategies of π-conjugated polymers for high-performance OPVs, including conjugated backbone engineering, side-chains engineering, regioregularity engineering, halogen substitution and molecular weight control.