It is essential to release annealing
induced strain during the
crystallization process to realize efficient and stable perovskite
solar cells (PSCs), which does not seem achievable using the conventional
annealing process. Here we report a novel and facile thermal gradient
assisted crystallization strategy by simply introducing a slant angle
between the preheated hot plate and the substrate. A distinct crystallization
sequence resulted along the in-plane direction pointing from the hot
side to the cool side, which effectively reduced the crystallization
rate, controlled the perovskite grain growth, and released the in-plane
tensile strain. Moreover, this strategy enabled uniform strain distribution
in the vertical direction and assisted in reducing the defects and
aligning the energy bands. The corresponding device demonstrated champion
power conversion efficiencies (PCEs) of 23.70% and 21.04% on the rigid
and flexible substrates, respectively. These highly stable rigid devices
retained 97% of the initial PCE after 1097 h of storage and more than
80% of the initial PCE after 1000 h of continuous operation at the
maximum power point. This novel strategy opens a simple and effective
avenue to improve the quality of perovskite films and photovoltaic
devices via strain modulation and defect passivation.