For many years, it has been recognized that potential organic photovoltaic cells must be integrated into elements requiring high transparency. In most of such elements, sunlight is likely to be incident at large angles. Here it is demonstrated that light transmission can be largely decoupled from harvesting by optically tailoring an infrared shifted nonfullerene acceptor based organic cell architecture. A 9.67% power conversion efficiency at 50° incidence is achieved together with an average visual transmission above 50% at normal incidence. The deconstruction of a 1D nanophotonic structure is implemented to conclude that just two λ/4 thick layers are essential to reach, for a wide incidence angle range, a higher than 50% efficiency increase relative to the standard configuration reference. In an outdoor measurement of vertically positioned 50% visible transparent cells, it is demonstrated that 9.80% of sunlight energy can be converted into electricity during the course of 1 day.
The performance of
nonfullerene-acceptor-(NFA)-based organic solar
cells is rapidly approaching the efficiency of inorganic cells. The
chemical versatility of NFAs extends the light-harvesting range to
the infrared, while preserving a considerably high open-circuit-voltage,
crucial to achieve power-conversion efficiencies >17%. Such low
voltage
losses in the charge separation process have been attributed to a
low-driving-force and efficient exciton dissociation. Here, we address
the nature of the subpicosecond dynamics of electron/hole transfer
in PM6/Y6 solar cells. While previous reports focused on active layers
only, we developed a photocurrent-detected two-dimensional spectroscopy
to follow the charge transfer in fully operating devices. Our measurements
reveal an efficient hole-transfer from the Y6-acceptor to the PM6-donor
on the subpicosecond time scale. On the contrary, at the same time
scale, no electron-transfer is seen from the donor to the acceptor.
These findings, putting ultrafast spectroscopy in action on operating
optoelectronic devices, provide insight for further enhancing NFA
solar cell performance.
Understanding the spatial dynamics of nanoscale exciton
transport
beyond the temporal decay is essential for further improvements of
nanostructured optoelectronic devices, such as solar cells. The diffusion
coefficient (
D
) of the nonfullerene electron acceptor
Y6 has so far only been determined indirectly, from singlet–singlet
annihilation (SSA) experiments. Here, we present the full picture
of the exciton dynamics, adding the spatial domain to the temporal
one, by spatiotemporally resolved photoluminescence microscopy. In
this way, we directly track diffusion and we are able to decouple
the real spatial broadening from its overestimation given by SSA.
We measured the diffusion coefficient,
D
= 0.017
± 0.003 cm
2
/s, which gives a Y6 film diffusion length
of
nm. Thus, we provide an essential tool
that enables a direct and free-of-artifacts determination of diffusion
coefficients, which we expect to be pivotal for further studies on
exciton dynamics in energy materials.
In article number 1904196, Xiaowei Zhan, Jordi Martorell and co‐workers design a building‐integrated transparent photovoltaic window based on an optically tailored organic solar cell, where enhanced sunlight harvesting at large oblique angles is largely decoupled from visual transmission at normal incidence, setting a new performance standard in the field.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.