Conspectus
Perovskite
semiconductors are regarded as next-generation photovoltaic
materials owing to their superb optoelectronic properties, including
an excellent carrier diffusion length, strong light absorbption, low
defect density, and solution processability. The PCE of lead perovskite
solar cells (LPSC) rapidly increased from 3.8 to 25.5% in the past
decade. However, the inclusion of soluble, toxic lead shadows its
application due to environmental concerns. Furthermore, on the basis
of the Shockley–Quisser (S–Q) limit, the efficiency
of lead perovskite is limited to 32% since its band gap is >1.5
eV.
To increase the efficiency of perovskite solar cells further, perovskite
materials with a smaller band gap are required.
Tin halide perovskite
is currently the most promising alternative
candidate that can address the above challenges due to its potentially
less toxic character and electronic configuration analogous to that
of lead. Its band gap (sub-1.4 eV) is lower than that of lead perovskite,
approaching the ideal band gap with a theoretical efficiency of up
to 33.4% based on the S–Q equation. However, tin perovskite
is extremely easy to oxidize due to its unique electronic structure.
Early works focus on the development of methods to reduce tin oxidation
such as the addition of antioxidant additives or using low-dimensional
structures. On the basis of these strategies, the reproducibility
and efficiency of TPSCs have been significantly improved. In recent
years, many works including composition engineering, functional additives,
and device structure engineering have been used to improve the performance
of TPSCs. On the basis of these strategies, the open-circuit voltage
is improved to 0.94 V and the PCE certified by an independent laboratory
is up to 12.4%. Meanwhile, the stability of TPSCs is significantly
improved, and the stabilized power output time is up to 1000 h. Therefore,
tin perovskite is emerging as a new generation of low-cost thin-film
photovoltaic technology.
This Account summarizes the properties
of tin halide perovskites
and the material and device engineering strategies toward more efficient
and stable TPSCs. We highlight the unique properties of tin perovskites
that distinguish them from lead perovskites, including their electronic
structure, band structure, chemical properties, and so on. We discuss
the critical challenges for the further development of TPSCs such
as oxidation, high background carriers, uncontrollable crystallization,
interface recombination, band alignment, and instability. In the end,
we introduce potential directions for the future development of TPSCs
including probing the formation mechanisms of tin perovskite, revealing
the basic properties of Sn perovskite, overcoming the stability issue
of TPSCs, and understanding TPSC device physics and structure engineering.
