High-efficiency formamidinium lead iodide(FAPbI3)-based perovskite solar cells(PSCs)typically involve annealing in humid air during the fabrication process of perovskite films.However,the combined effects of humidity ...High-efficiency formamidinium lead iodide(FAPbI3)-based perovskite solar cells(PSCs)typically involve annealing in humid air during the fabrication process of perovskite films.However,the combined effects of humidity and relatively high temperature often result in the uncontrollable formation of a detrimental PbI_(2)phase in the perovskite films.As a result,the annealing process of perovskite films is highly sensitive to the relative humidity fluctuations of the environment.Under solar illumination,the undesired PbI_(2)tends to decompose,accelerating the degradation of perovskite materials and severely compromising the light stability of PSCs.This issue is particularly critical for the buried interface and bulk of the perovskite films,as these regions absorb the majority of the incident light.Pre-treatment and posttreatment strategies are generally confined to address the PbI_(2)issues at the buried interface and on the surface of the perovskite films,respectively.However,effectively addressing the effects of excess PbI_(2)at buried interface and grain boundaries within bulk in a single step remains challenging.In this study,we propose an intermediate-treatment strategy using phthalylglycyl chloride(PTC),which involves treating the wet films with PTC prior to annealing during the formation process of the perovskite films.This approach protects the grain boundaries of polycrystalline perovskite films in advance,effectively preventing moisture-induced degradation of the perovskites and thus significantly broadening the relative humidity window of annealing process.Our results demonstrate that this strategy can successfully suppress the formation of PbI_(2)at the grain boundaries and buried interface of perovskite films,thereby eliminating the PbI_(2)-induced degradation pathways.Our strategy significantly reduces the sensitivity to humidity fluctuations during annealing for fabricating stable PSCs,ensuring more consistent fabrication of stable PSCs.Consequently,the resulting PSCs achieve a champion power conversion efficiency of 26.1% and demonstrate excellent light stability.展开更多
The vast majority of high-performance perovskite solar cells(PSCs) are based on a formamidinium lead iodide(FAPbI_(3))-dominant composition. Nevertheless, the FA-based perovskite films suffer from undesirable phase tr...The vast majority of high-performance perovskite solar cells(PSCs) are based on a formamidinium lead iodide(FAPbI_(3))-dominant composition. Nevertheless, the FA-based perovskite films suffer from undesirable phase transition and defects-induced non-ideal interfacial recombination, which significantly induces energy loss and hinders the improvement of device performance. Herein, we employed 4-fluorophenylmethylammonium iodide(F-PMAI) to modulate surface structure and energy level alignment of the FA-based perovskite films. The superior optoelectronic films were obtained with reduced trap density, pure α-phase FAPbI_(3) and favorable energy band bending. The lifetime of photogenerated charge carriers increased from 489.3 ns to 1010.6 ns, and a more “p-type” perovskite film was obtained by the post-treatment with F-PMAI. Following this strategy, we demonstrated an improved power conversion efficiency of 22.59% for the FA-based PSCs with an open-circuit voltage loss of 399 m V.展开更多
Ultrathin(thickness less than 10μm)and ultralight flexible perovskite solar cells(FPSCs)have attracted extensive research enthusiasm as power sources for specific potential lightweight applications,such as drones,bli...Ultrathin(thickness less than 10μm)and ultralight flexible perovskite solar cells(FPSCs)have attracted extensive research enthusiasm as power sources for specific potential lightweight applications,such as drones,blimps,weather balloons and avionics.Currently,there is still a certain gap between the power conversion efficiency(PCE)of ultrathin FPSCs and common FPSCs.This study demonstrates ultrathin FPSCs on 3-μm-thick parylene-C substrates via a flip-over transferring process.The Zr,Ti and Ga-doped indium oxide(ITGZO)film is employed as the bottom transparent electrode of ultrathin inverted FPSCs with a remarkable PCE of 20.2%,which is comparable to that based on common FPSCs.Devices on glasses and parylene-F(i.e.,parylene-VT4)substrates were also constructed to verify the advantages of parylene-C.Furthermore,an excellent powerper-weight of 30.3 W g^(-1) is achieved attributed to remarkable PCE and ultrathin-ultralight substrates,demonstrating the great promise of fabricating efficient,ultrathin and ultralight solar cells with parylene-C films.展开更多
基金financially supported by the National Natural Science Foundation of China(52203208,52325310,U24A6003,52303335)the National Key R&D Program of China(2021YFB3800101)+3 种基金the Beijing Nova Program(contract no.20230484480)the open research fund of Songshan Lake Materials Laboratory(2022SLABFK07)the Yunnan Provincial Science and Technology Project at Southwest United Graduate School(202302AO370013)the R&D Fruit Fund(20210001)。
文摘High-efficiency formamidinium lead iodide(FAPbI3)-based perovskite solar cells(PSCs)typically involve annealing in humid air during the fabrication process of perovskite films.However,the combined effects of humidity and relatively high temperature often result in the uncontrollable formation of a detrimental PbI_(2)phase in the perovskite films.As a result,the annealing process of perovskite films is highly sensitive to the relative humidity fluctuations of the environment.Under solar illumination,the undesired PbI_(2)tends to decompose,accelerating the degradation of perovskite materials and severely compromising the light stability of PSCs.This issue is particularly critical for the buried interface and bulk of the perovskite films,as these regions absorb the majority of the incident light.Pre-treatment and posttreatment strategies are generally confined to address the PbI_(2)issues at the buried interface and on the surface of the perovskite films,respectively.However,effectively addressing the effects of excess PbI_(2)at buried interface and grain boundaries within bulk in a single step remains challenging.In this study,we propose an intermediate-treatment strategy using phthalylglycyl chloride(PTC),which involves treating the wet films with PTC prior to annealing during the formation process of the perovskite films.This approach protects the grain boundaries of polycrystalline perovskite films in advance,effectively preventing moisture-induced degradation of the perovskites and thus significantly broadening the relative humidity window of annealing process.Our results demonstrate that this strategy can successfully suppress the formation of PbI_(2)at the grain boundaries and buried interface of perovskite films,thereby eliminating the PbI_(2)-induced degradation pathways.Our strategy significantly reduces the sensitivity to humidity fluctuations during annealing for fabricating stable PSCs,ensuring more consistent fabrication of stable PSCs.Consequently,the resulting PSCs achieve a champion power conversion efficiency of 26.1% and demonstrate excellent light stability.
基金funded by the National Natural Science Foundation of China(62004165)the China Postdoctoral Science Foundation(2020M670036)+2 种基金the Natural Science Foundation of Shaanxi Province,China(2020JQ195)the Joint Research Funds of Department of Science&Technology of Shaanxi Province and Northwestern Polytechnical University(2020GXLH-Z-007,2020GXLH-Z-025)the Fundamental Research Funds for the Central Universities。
文摘The vast majority of high-performance perovskite solar cells(PSCs) are based on a formamidinium lead iodide(FAPbI_(3))-dominant composition. Nevertheless, the FA-based perovskite films suffer from undesirable phase transition and defects-induced non-ideal interfacial recombination, which significantly induces energy loss and hinders the improvement of device performance. Herein, we employed 4-fluorophenylmethylammonium iodide(F-PMAI) to modulate surface structure and energy level alignment of the FA-based perovskite films. The superior optoelectronic films were obtained with reduced trap density, pure α-phase FAPbI_(3) and favorable energy band bending. The lifetime of photogenerated charge carriers increased from 489.3 ns to 1010.6 ns, and a more “p-type” perovskite film was obtained by the post-treatment with F-PMAI. Following this strategy, we demonstrated an improved power conversion efficiency of 22.59% for the FA-based PSCs with an open-circuit voltage loss of 399 m V.
基金financially supported by Beijing Natural Science Foundation(JQ21005)the National Key R&D Program of China(2021YFB3800100 and 2021YFB3800101)+1 种基金China Postdoctoral Science Foundation(2020M670036)the R&D Fruit Fund(20210001)。
文摘Ultrathin(thickness less than 10μm)and ultralight flexible perovskite solar cells(FPSCs)have attracted extensive research enthusiasm as power sources for specific potential lightweight applications,such as drones,blimps,weather balloons and avionics.Currently,there is still a certain gap between the power conversion efficiency(PCE)of ultrathin FPSCs and common FPSCs.This study demonstrates ultrathin FPSCs on 3-μm-thick parylene-C substrates via a flip-over transferring process.The Zr,Ti and Ga-doped indium oxide(ITGZO)film is employed as the bottom transparent electrode of ultrathin inverted FPSCs with a remarkable PCE of 20.2%,which is comparable to that based on common FPSCs.Devices on glasses and parylene-F(i.e.,parylene-VT4)substrates were also constructed to verify the advantages of parylene-C.Furthermore,an excellent powerper-weight of 30.3 W g^(-1) is achieved attributed to remarkable PCE and ultrathin-ultralight substrates,demonstrating the great promise of fabricating efficient,ultrathin and ultralight solar cells with parylene-C films.
