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▫$C_{60}$▫ is a widely used electron selective material for p–i–n perovskite cells, however, its energy level does not match well with that of a wide-bandgap perovskite, resulting in low open-circuit voltage ▫$(V_{OC})$▫ and fill factor (FF). To overcome this issue, ultra-thin LiF has been widely used as an interlayer between ▫$C_{60}$▫ and perovskite layers facilitating efficient electron extraction but resulting in instability. In this work, the use of a piperidinium bromide (PpBr) is reported as an interlayer between ▫$C_{60}$▫ and perovskite, and the interlayer further is optimized by introducing an additional oxygen atom on the opposite side of the ▫$NH_{2}+$▫. This results in morpholinium bromide (MLBr) with increased dipole moment. Because of this, MLBr is highly effective in minimizing the energy band mismatch between perovskite and ▫$C_{60}$▫ layer for electron extraction while at the same time passivating defects. The champion single junction 1.67 eV MLBr solar cell produced a PCE of 21.9% and the champion monolithic MLBr perovskite-Si tandem cell produced a PCE of 28.8%. Most importantly, both encapsulated MLBr and PpBr devices retain over 97% of their initial efficiency after 400 thermal cycles (between −40 and 85 °C), twice the number of cycles specified by the International Electrotechnical Commission (IEC) 61215 photovoltaic module standard.