High specific power or power to mass ratio is a critical concern of photovoltaic(PV)for aerospace applications.Organic solar cells(OSCs)have advantages such as high absorption coefficient,compatibility with flexible s...High specific power or power to mass ratio is a critical concern of photovoltaic(PV)for aerospace applications.Organic solar cells(OSCs)have advantages such as high absorption coefficient,compatibility with flexible substrate,light-weight,etc.Moreover,recently OSCs achieved power conversion efficiency(PCE)over 20%with the incorporation of the non-fullerene based small molecule acceptor and high specific power is believed to be obtained.To enter the market,high-altitude platform station(HAPS)is perhaps the first place to start with.In this work,we explore and compare the in-situ performance of two high performing OSCs,using the same donor but different acceptors,in mimic HAPS environment where the pressure,temperature and the illumination conditions are controlled.We found that the use of acceptor can result in substantial difference in the performance at low temperatures.展开更多
Organic solar cells(OSCs)in terms of power conversion efficiency(PCE)and operational lifetime have made remarkable progress during the last decade by improving the active layer materials and introducing new interlayer...Organic solar cells(OSCs)in terms of power conversion efficiency(PCE)and operational lifetime have made remarkable progress during the last decade by improving the active layer materials and introducing new interlayers.The newly developed wide bandgap organic donor and low bandgap acceptor molecules covered the absorption from the visible to the near-infrared region.Whereas the incident high energy region(UV)is not in favor of OSCs.Its absorption causes thermalization losses and photoinduced degradation,which hinders the PCE and lifetime of OSCs.Recently,lanthanide and non-lanthanide-based down-conversion(DC)materials have been introduced,which can effectively convert the high-energy photons(UV)to low-energy photons(visible)and resolve the spectral mismatch losses that limit the absorption of OSCs in high energy incident spectrum.Furthermore,the DC materials also protect the OSCs from UV-induced degradation.The DC materials were also proposed to cross the Shockley-Queisser efficiency limit of the solar cell.In this review,the need for DC materials and their processing method for OSCs have been thoroughly discussed.However,the main emphasis has been given to developing lanthanides and non-lanthanides-based DC materials for OSCs,their applications,and their impact on photovoltaic device performance,stability,and future perspectives.展开更多
基金the SPECIFIC Innovation and Knowledge Centre(EP/N020863/1)and ATIP(EP/T028513/1)grant for providing financial support.Hin-Lap Yip acknowledges the financial support by the Guangdong Major Project of Basic and Applied Basic Research(No.2019B030302007)the Ministry of Science and Technology of China(No.2019YFA0705900)+1 种基金Guichuan Zhang acknowledges the financial support by the Na-tional Natural Science Foundation of China(No.51903095)the Natural Science Foundation of Guangdong Province(No.2021 A1515010959).
文摘High specific power or power to mass ratio is a critical concern of photovoltaic(PV)for aerospace applications.Organic solar cells(OSCs)have advantages such as high absorption coefficient,compatibility with flexible substrate,light-weight,etc.Moreover,recently OSCs achieved power conversion efficiency(PCE)over 20%with the incorporation of the non-fullerene based small molecule acceptor and high specific power is believed to be obtained.To enter the market,high-altitude platform station(HAPS)is perhaps the first place to start with.In this work,we explore and compare the in-situ performance of two high performing OSCs,using the same donor but different acceptors,in mimic HAPS environment where the pressure,temperature and the illumination conditions are controlled.We found that the use of acceptor can result in substantial difference in the performance at low temperatures.
基金SPECIFIC Innovation and Knowledge Centre,Grant/Award Number:EP/N020863/1Council of Scientific&Industrial Research,Grant/Award Number:31/1 (0494)/2018-EMR-1。
文摘Organic solar cells(OSCs)in terms of power conversion efficiency(PCE)and operational lifetime have made remarkable progress during the last decade by improving the active layer materials and introducing new interlayers.The newly developed wide bandgap organic donor and low bandgap acceptor molecules covered the absorption from the visible to the near-infrared region.Whereas the incident high energy region(UV)is not in favor of OSCs.Its absorption causes thermalization losses and photoinduced degradation,which hinders the PCE and lifetime of OSCs.Recently,lanthanide and non-lanthanide-based down-conversion(DC)materials have been introduced,which can effectively convert the high-energy photons(UV)to low-energy photons(visible)and resolve the spectral mismatch losses that limit the absorption of OSCs in high energy incident spectrum.Furthermore,the DC materials also protect the OSCs from UV-induced degradation.The DC materials were also proposed to cross the Shockley-Queisser efficiency limit of the solar cell.In this review,the need for DC materials and their processing method for OSCs have been thoroughly discussed.However,the main emphasis has been given to developing lanthanides and non-lanthanides-based DC materials for OSCs,their applications,and their impact on photovoltaic device performance,stability,and future perspectives.
