In:
Materials Chemistry Frontiers, Royal Society of Chemistry (RSC), Vol. 6, No. 15 ( 2022), p. 2061-2071
Abstract:
The development of high-quality rear window layers (RWLs) with excellent photoelectric properties is key to achieving a high photovoltaic (PV) output from bifacial perovskite solar cells (b-PSCs). Herein, we propose a novel strategy to improve the photoelectric balance of RWLs by introducing 1T-phase tungsten disulfide (1T-WS 2 ) nanosheets with metallic properties into a traditional organic hole-transporting layer (HTL) to create an organic–inorganic hybrid model. The mechanisms responsible for the synergistic improvement in the photoelectric and physical properties of the hybrid system, particularly the light-trapping capability, interface properties, charge dynamics, and PV parameters of the b-PSCs, are discussed in depth. The decrease in the thickness of the hybrid HTL due to the introduction of 1T-WS 2 not only enhances the optical transmittance, but also accelerates hole transfer in the improved system to a certain extent. Moreover, the decrease in the surface potential of the hybrid HTL driven by 1T-WS 2 improves the work function and brings the valence band closer to that of the perovskite. This energy-level alignment caused by Fermi level reduction effectively promotes hole extraction/transfer/collection and suppresses interface recombination, thus improving the PV parameters of devices. Owing to the fact that 1T-WS 2 doping synchronously enhances the light-harvesting capability and charge behavior of the device, the obtained maximum efficiencies of the optimized hybrid b-PSC under front and rear illuminations are 19.87 and 15.48%, respectively, which are superior to those of conventional organic b-PSCs. Ultimately, the 1T-WS 2 -doped RWL created in this work effectively alleviates the PV degradation caused by water erosion and photo-thermal degradation of b-PSCs during environmental testing. The corresponding unencapsulated devices exhibit excellent irradiation/operational stability. This work provides important insights into the improvement in the photoelectric balance of RWLs in bifacial and tandem devices, and establishes a foundation for the widespread application of two-dimensional transition metal dichalcogenides in high-efficiency PV devices.
Type of Medium:
Online Resource
ISSN:
2052-1537
Language:
English
Publisher:
Royal Society of Chemistry (RSC)
Publication Date:
2022
detail.hit.zdb_id:
2867881-3
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