posted on 2021-07-19, 16:27authored byDeimante Vaitukaityte, Cristina Momblona, Kasparas Rakstys, Albertus Adrian Sutanto, Bin Ding, Cansu Igci, Vygintas Jankauskas, Alytis Gruodis, Tadas Malinauskas, Abdullah M. Asiri, Paul J. Dyson, Vytautas Getautis, Mohammad Khaja Nazeeruddin
To attain commercial viability, perovskite solar cells (PSCs) have
to be reasonably priced, highly efficient, and stable for a long period
of time. Although a new record of a certified power conversion efficiency
(PCE) value over 25% was achieved, PSC performance is limited by the
lack of hole-transporting materials (HTMs), which extract positive
charges from the light-absorbing perovskite layer and carry them to
the electrode. Here, we report spirobifluorene-based HTMs with finely
tuned energy levels, high glass-transition temperature, and excellent
charge mobility and conductivity enabled by molecularly engineered
enamine arms. HTMs are synthesized using simple condensation chemistry,
which does not require costly catalysts, inert reaction conditions,
and time-consuming product purification procedures. Enamine-derived
HTMs allow the fabrication of PSCs reaching a maximum PCE of 19.2%
and stability comparable to spiro-OMeTAD. This work demonstrates that
simple enamine condensation reactions could be used as a universal
path to obtain HTMs for highly efficient and stable PSCs.