Ambient fabrication of perovskite solar cells through delay-deposition technique

Fahsyar, Puteri Nor Aznie; Ludin, Norasikin Ahmad; Ramli, Noor Fadhilah; Noh, Mohamad Firdaus Mohamad; Yunus, Rozan Mohamad; Sepeai, Suhaila; Ibrahim, Mohd Adib; Teridi, Mohd Asri Mat; Sopian, Kamaruzzaman

doi:10.1007/s40243-021-00196-8

Cited by 2 publications

(2 citation statements)

References 36 publications

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“…The small peak declines for M1–M4 samples proportionally, which proves that the layer can repel moisture from being captivated into the other layers although the fabrication process is done under high humidity conditions (RH = 40–50%). The other characteristic peaks correspond well to MAPbI 3 (at 2θ = 14.5° and 28.7°) for all samples with crystal size obtained ~ 31.9 nm 42 , 43 . In addition, some miscellaneous peaks were detected, which explained the presence of residual CH 3 NH 3 I will be decomposed and the product of I 2 .…”

Section: Resultssupporting

confidence: 63%

Stabilizing high-humidity perovskite solar cells with MoS2 hybrid HTL

Fahsyar,

Ludin,

Ramli

et al. 2023

Sci Rep

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The obstacle to the industrialization of perovskite solar cells (PSC) technology lies in their stability. This work rationalizes the PSC design with the employment of 2D-MoS2 as the hybrid hole transport layer (HTL). MoS2 was selected due to its unique optoelectronic and mechanical properties that could enhance hole extraction and thus boost the performance and stability of PSC devices. Five concentrations indicated MoS2 nanosheets were directly deposited onto the perovskite layer via the facile spin coating method. The electrochemical exfoliation and liquid exchange methods were demonstrated to obtain the lateral size of MoS2 nanosheets and further discussed their microscopic and spectroscopic characterizations. Remarkably, the optimum thickness and the excellent device increased the stability of the PSC, allowing it to maintain 45% of its degradation percentage ($$\frac{\Delta PCE}{PCE}$$ Δ P C E PCE ) for 120 h with high relative humidity (RH = 40–50%) in its vicinity. We observed that lithium-ion can intercalate into the layered MoS2 structure and reduce the interfacial resistance of perovskite and the HTL. Most importantly, the 2D-MoS2 mechanism’s effect on enabling stable and efficient devices by reducing lithium-ion migration in the HTL is demonstrated in this work to validate the great potential of this hybrid structure in PSC applications.

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Section: Resultssupporting

confidence: 63%

Stabilizing high-humidity perovskite solar cells with MoS2 hybrid HTL

Fahsyar,

Ludin,

Ramli

et al. 2023

Sci Rep

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“…The degradation rate of perovskite top cells can affect the overall tandem module degradation and consequently reduce the module's lifetime energy and cost-effectiveness. Several methods, such as encapsulation [12,13], interfacial engineering [14][15][16][17] and chemical passivation [18,19], are used to improve the long-term stability of sensitive perovskite top cells.…”

Section: Introductionmentioning

confidence: 99%

Influence of graphene dispersion on the photovoltaic performance of tandem solar cells with four-terminal perovskite–polycrystalline silicon configuration

Ramli,

Aznie Fahsyar,

Ahmad Ludin

et al. 2024

Mater. Res. Express

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Silicon's prominence in photovoltaic technology stems from its abundance and safety. While Si-based solar cells demonstrate high energy conversion efficiency and long-term stability, they encounter challenges such as high costs, intricate fabrication processes, and suboptimal efficiency. To address these issues, researchers have developed tandem solar cells that combine silicon with perovskite cells. This research specifically investigates the use of the spin coating technique with graphene dispersion solutions to deposit graphene layers in perovskite solar cells (PSCs), providing a flexible and cost-effective alternative to conventional methods. By employing graphene as a protective sealant for the perovskite interlayer to prevent degradation, the study aims to enhance the overall performance and stability of tandem solar cells. Graphene was applied onto the hole transport layer at varying concentrations (1, 5, and 10 mg/mL) in isopropanol. Notably, the introduction of graphene resulted in decreased power conversion efficiencies (PCEs) in PSC top cells over 60 hours, with efficiency reductions of 43%, 24%, and 17% for different concentrations. Importantly, these efficiency declines were significantly lower compared to cells lacking a graphene layer, which experienced a sharp 93% decrease. This investigation underscores the critical role of graphene layers in improving the stability of PSC top cells while maintaining compatibility with the stability of poly-Si bottom cells.

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Ambient fabrication of perovskite solar cells through delay-deposition technique

Cited by 2 publications

References 36 publications

Stabilizing high-humidity perovskite solar cells with MoS2 hybrid HTL

Stabilizing high-humidity perovskite solar cells with MoS2 hybrid HTL

Influence of graphene dispersion on the photovoltaic performance of tandem solar cells with four-terminal perovskite–polycrystalline silicon configuration

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