2021
DOI: 10.1039/d1ta01180d
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Charge-transfer induced multifunctional BCP:Ag complexes for semi-transparent perovskite solar cells with a record fill factor of 80.1%

Abstract: For semi-transparent perovskite solar cells (PSCs), the bombardment during the deposition of transparent conductive oxide can inevitably damage the underlying soft materials, thereby inducing a high density of defects and...

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Cited by 36 publications
(29 citation statements)
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“…Figure 6e shows that there is a large increase in the N 1s binding energy upon Cu deposition, which is indicative of a strong interaction between Cu and the N atoms in the bay area of the phenanthroline ring, similar to that reported to occur between evaporated Ag and BCP. [49] Small angle X-ray scattering measurements (Figure 6f) show that the mean crystallite radius for Cu deposited on BCP is 7.9 ± 0.2 nm which is ≈40% smaller than that of Ag, 13.3 ± 0.2 nm, consistent with a higher density of nucleation sites for Cu than Ag and/or a lower mobility of Cu atoms over the BCP surface during film growth. Both possibilities are consistent with a stronger interaction between Cu and BCP than between Ag and BCP.…”
Section: Resultsmentioning
confidence: 76%
“…Figure 6e shows that there is a large increase in the N 1s binding energy upon Cu deposition, which is indicative of a strong interaction between Cu and the N atoms in the bay area of the phenanthroline ring, similar to that reported to occur between evaporated Ag and BCP. [49] Small angle X-ray scattering measurements (Figure 6f) show that the mean crystallite radius for Cu deposited on BCP is 7.9 ± 0.2 nm which is ≈40% smaller than that of Ag, 13.3 ± 0.2 nm, consistent with a higher density of nucleation sites for Cu than Ag and/or a lower mobility of Cu atoms over the BCP surface during film growth. Both possibilities are consistent with a stronger interaction between Cu and BCP than between Ag and BCP.…”
Section: Resultsmentioning
confidence: 76%
“…Since the LUMO levels of the prevailing electron transport materials in organic solar cells (OSCs) mostly range from −4 to −3 eV 9 , the CAN-modified electrodes with a low work function of approximately 3.0 eV can also facilitate electron extraction in view of energy alignment. In addition, a 2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline (BCP):Ag complex has been successfully employed to reduce the electron extraction barrier between a C 60 electron transport layer and indium-zinc oxide top electrode in high-performance perovskite solar cells 36 . Thus, the CAN technique possessing high WF tunability, good thermal stability, and a wide processing window is anticipated to be applicable to cathode modification in OLEDs, OSCs, and other optoelectronic devices.…”
Section: Resultsmentioning
confidence: 99%
“…Moreover, because of the thermal instability of the perovskite layer, the annealing process for the TCO rear electrode that deposited on the perovskite absorber layer is generally omitted, leading to inferior optical transparency than high-temperatureprocessed TCOs. To mitigate the parasitic light-absorption issues, TCOs with relatively high electron mobility and a low carrier density, such as hydrogen-doped indium oxide, [80,133] indium-doped zinc oxide, [133,134] and combined TCOs, [135] are employed as the rear electrode. Alternatively, some ultrathin metal/dielectric film stacks, [136][137][138] metallic nanostructures (e.g., Ag nanowires), [139,140] carbon nanostructures (e.g., graphene, nanotubes) [141][142][143] a have also been explored for metal-oxide-free transparent electrodes.…”
Section: Optical Lossesmentioning
confidence: 99%