Metal oxide charge transport materials are preferable for realizing long-term stable and potentially low-cost perovskite solar cells(PSCs).However,due to some technical difficulties(e.g.,intricate fabrication protocol...Metal oxide charge transport materials are preferable for realizing long-term stable and potentially low-cost perovskite solar cells(PSCs).However,due to some technical difficulties(e.g.,intricate fabrication protocols,high-temperature heating process,incompatible solvents,etc.),it is still challenging to achieve efficient and reliable all-metal-oxide-based devices.Here,we developed efficient inverted PSCs(IPSCs)based on solution-processed nickel oxide(NiO_(x))and tin oxide(SnO_(2))nanoparticles,working as hole and electron transport materials respectively,enabling a fast and balanced charge transfer for photogenerated charge carriers.Through further understanding and optimizing the perovskite/metal oxide interfaces,we have realized an outstanding power conversion efficiency(PCE)of 23.5%(the bandgap of the perovskite is 1.62 eV),which is the highest efficiency among IPSCs based on all-metal-oxide charge transport materials.Thanks to these stable metal oxides and improved interface properties,ambient stability(retaining 95%of initial PCE after 1 month),thermal stability(retaining 80%of initial PCE after 2 weeks)and light stability(retaining 90%of initial PCE after 1000 hours aging)of resultant devices are enhanced significantly.In addition,owing to the low-temperature fabrication procedures of the entire device,we have obtained a PCE of over 21%for flexible IPSCs with enhanced operational stability.展开更多
All-inorganic CsPbBr_(3)-based perovskite solar cells(PSCs)have attracted great attention because of their high chemical and thermal stabilities in ambient air.However,the short-circuit current density(J_(sc))of CsPbB...All-inorganic CsPbBr_(3)-based perovskite solar cells(PSCs)have attracted great attention because of their high chemical and thermal stabilities in ambient air.However,the short-circuit current density(J_(sc))of CsPbBr_(3)-based PSCs is inadequate under solar illumination because of the wide bandgap,inefficient charge extraction and recombination loss,leading to lower power-conversion efficiencies(PCEs).It is envisaged that in addition to narrowing the bandgap by alloying,J_(sc)of the PSCs could be enhanced by effective improvement of electron transportation,suppression of charge recombination at the interface between the perovskite and electron transporting layer(ETL),and tuning of the space charge field in the device.In this work,Nb-doped SnO_(2)films as ETLs in the CsPbBr_(3)-based PSCs have been deposited at room temperature by high target utilization sputtering(Hi TUS).Through optimizing the Nb doping level alone,the J_(sc)was increased by nearly 19%,from 7.51 to 8.92 mA·cm^(-2)and the PCE was enhanced by 27%from 6.73%to 8.54%.The overall benefit by replacing the spin-coated SnO_(2)with sputtered SnO_(2)with Nb doping was up to 39%increase in J_(sc)and 62%increase in PCE.Moreover,the PCE of the optimized device showed negligible degradation over exposure to ambient environment(T~25°C,RH~45%),with 95.4%of the original PCE being maintained after storing the device for 1200 h.展开更多
Metal halide perovskite solar cells are emerging candidates for nextgeneration thin-film photovoltaic devices with the potential for extremely low fabrication cost and high power conversion efficiency.Perovskite solar...Metal halide perovskite solar cells are emerging candidates for nextgeneration thin-film photovoltaic devices with the potential for extremely low fabrication cost and high power conversion efficiency.Perovskite solar cells have demonstrated a rapid development in device performance over the last decade,from an initial 3.81%to a most recently certified 24.2%,though the challenges of long-term stability and lead toxicity still remain.Carbon materials,ranging from zero-dimensional carbon quantum dots to threedimensional carbon black materials,are promising candidates for the enhancement of both efficiency and stability of perovskite solar cells,offering unique advantages for incorporation into various device architectures.In this review article,we present a concise overview of important and exciting advancements of perovskite solar cells that incorporate different dimensions of carbon material in their device architectures in an effort to simultaneously improve device performance and long-term stability.We also discuss the major advantages and potential challenges of each technique that has been developed in the most recent work.Finally,we outline the future opportunities toward more efficient and stable perovskite solar cells utilizing carbon materials.展开更多
基金UK Engineering and Physical Sciences Research Council(EPSRC)New Investigator Award(2018,EP/R043272/1)Newton Advanced Fellowship(192097)for financial support+3 种基金the Royal Society,the Engineering and Physical Sciences Research Council(EPSRC,EP/R023980/1,EP/V027131/1)the European Research Council(ERC)under the European Union's Horizon 2020 research and innovation program(HYPERION,Grant Agreement Number 756962)the Royal Society and Tata Group(UF150033)EPSRC SPECIFIC IKC(EP/N020863/1)
文摘Metal oxide charge transport materials are preferable for realizing long-term stable and potentially low-cost perovskite solar cells(PSCs).However,due to some technical difficulties(e.g.,intricate fabrication protocols,high-temperature heating process,incompatible solvents,etc.),it is still challenging to achieve efficient and reliable all-metal-oxide-based devices.Here,we developed efficient inverted PSCs(IPSCs)based on solution-processed nickel oxide(NiO_(x))and tin oxide(SnO_(2))nanoparticles,working as hole and electron transport materials respectively,enabling a fast and balanced charge transfer for photogenerated charge carriers.Through further understanding and optimizing the perovskite/metal oxide interfaces,we have realized an outstanding power conversion efficiency(PCE)of 23.5%(the bandgap of the perovskite is 1.62 eV),which is the highest efficiency among IPSCs based on all-metal-oxide charge transport materials.Thanks to these stable metal oxides and improved interface properties,ambient stability(retaining 95%of initial PCE after 1 month),thermal stability(retaining 80%of initial PCE after 2 weeks)and light stability(retaining 90%of initial PCE after 1000 hours aging)of resultant devices are enhanced significantly.In addition,owing to the low-temperature fabrication procedures of the entire device,we have obtained a PCE of over 21%for flexible IPSCs with enhanced operational stability.
基金supported by the National Natural Science Foundation of China(Nos.51602290,91233101,11174256)the Fundamental Research Program from the Ministry of Science and Technology of China(No.2014CB31704)+4 种基金Project funded by China Postdoctoral Science Foundation(No.2016M592310)the financial support from EPSRC New Investigator Award(2018EP/R043272/1)H2020-EU grant(2018CORNET 760949)
文摘All-inorganic CsPbBr_(3)-based perovskite solar cells(PSCs)have attracted great attention because of their high chemical and thermal stabilities in ambient air.However,the short-circuit current density(J_(sc))of CsPbBr_(3)-based PSCs is inadequate under solar illumination because of the wide bandgap,inefficient charge extraction and recombination loss,leading to lower power-conversion efficiencies(PCEs).It is envisaged that in addition to narrowing the bandgap by alloying,J_(sc)of the PSCs could be enhanced by effective improvement of electron transportation,suppression of charge recombination at the interface between the perovskite and electron transporting layer(ETL),and tuning of the space charge field in the device.In this work,Nb-doped SnO_(2)films as ETLs in the CsPbBr_(3)-based PSCs have been deposited at room temperature by high target utilization sputtering(Hi TUS).Through optimizing the Nb doping level alone,the J_(sc)was increased by nearly 19%,from 7.51 to 8.92 mA·cm^(-2)and the PCE was enhanced by 27%from 6.73%to 8.54%.The overall benefit by replacing the spin-coated SnO_(2)with sputtered SnO_(2)with Nb doping was up to 39%increase in J_(sc)and 62%increase in PCE.Moreover,the PCE of the optimized device showed negligible degradation over exposure to ambient environment(T~25°C,RH~45%),with 95.4%of the original PCE being maintained after storing the device for 1200 h.
基金financial support provided by the doctoral col ege studentship at the University of Surreyfinancial support from EPSRC New Investigator Award(2018,EP/R043272/1)+2 种基金the Royal Society International Exchanges Scheme(2016,IE160511)H2020-EU grant(2018,CORNET760949)financial support provided by the Nano-OPS Printer for High Rate Nano-Manufacturing and Support Equipment grant(2018,EP/R025304/1)
文摘Metal halide perovskite solar cells are emerging candidates for nextgeneration thin-film photovoltaic devices with the potential for extremely low fabrication cost and high power conversion efficiency.Perovskite solar cells have demonstrated a rapid development in device performance over the last decade,from an initial 3.81%to a most recently certified 24.2%,though the challenges of long-term stability and lead toxicity still remain.Carbon materials,ranging from zero-dimensional carbon quantum dots to threedimensional carbon black materials,are promising candidates for the enhancement of both efficiency and stability of perovskite solar cells,offering unique advantages for incorporation into various device architectures.In this review article,we present a concise overview of important and exciting advancements of perovskite solar cells that incorporate different dimensions of carbon material in their device architectures in an effort to simultaneously improve device performance and long-term stability.We also discuss the major advantages and potential challenges of each technique that has been developed in the most recent work.Finally,we outline the future opportunities toward more efficient and stable perovskite solar cells utilizing carbon materials.
