Enhancing the environmental stability of perovskite thin films via PMMA and AZ5214-photoresist coatings
Enhancing the environmental stability of perovskite thin films via PMMA and AZ5214-photoresist coatings
We introduce a pioneering strategy to enhance the environmental stability of perovskite thin films, a critical step forward in advancing their application in optoelectronics. Through the innovative application of matrix encapsulation techniques, we focus on the stabilization of methylammonium lead iodide (MAPbI3) and methylammonium lead bromide (MAPbBr3) films. These films are meticulously prepared via a two-step solution deposition method under controlled ambient conditions. Our approach involves the application of poly(methyl methacrylate) (PMMA) and AZ5214 photoresist layers through spin-coating, aimed at singularly encapsulating the perovskite films. This encapsulation acts as a robust hydrophobic barrier, significantly mitigating moisture ingress and simultaneously addressing the challenge of pinhole presence within the perovskite structure. Through a series of detailed characterizations-spanning scanning electron microscopy (SEM), X-ray diffraction (XRD), and photoluminescence (PL) spectroscopy-we demonstrate that, despite the thicker nature of the AZ5214 photoresist compared to the PMMA layer, it exhibits markedly enhanced stability. Notably, the integrity and optical properties of the perovskite films are preserved for extended periods of up to 960 hours under environmental exposure. This breakthrough highlights the superior performance of AZ5214 photoresist over PMMA in prolonging the operational life of perovskite thin films, thereby offering a promising avenue for their deployment in a wide range of optoelectronic devices.
physics.app-ph, physics.optics
FallaH, Kimya
e5f59e99-2444-4242-8104-54adda2639d0
Alam, Shahab Norouzian
286e3770-19e1-4ffb-a2cc-d2faf35902c6
Ghomi, Bijan Ghafari
aa95ce23-152f-47c3-b9de-512e11b66bc9
Yekekar, Farzane
c100497d-d95c-439b-ab7c-75f10177b337
Taghian, Shima
ba249c66-af61-4829-b5a2-a1b91937f830
Taravati, Sajjad
0026f25d-c919-4273-b956-8fe9795b31ce
25 February 2024
FallaH, Kimya
e5f59e99-2444-4242-8104-54adda2639d0
Alam, Shahab Norouzian
286e3770-19e1-4ffb-a2cc-d2faf35902c6
Ghomi, Bijan Ghafari
aa95ce23-152f-47c3-b9de-512e11b66bc9
Yekekar, Farzane
c100497d-d95c-439b-ab7c-75f10177b337
Taghian, Shima
ba249c66-af61-4829-b5a2-a1b91937f830
Taravati, Sajjad
0026f25d-c919-4273-b956-8fe9795b31ce
[Unknown type: UNSPECIFIED]
Abstract
We introduce a pioneering strategy to enhance the environmental stability of perovskite thin films, a critical step forward in advancing their application in optoelectronics. Through the innovative application of matrix encapsulation techniques, we focus on the stabilization of methylammonium lead iodide (MAPbI3) and methylammonium lead bromide (MAPbBr3) films. These films are meticulously prepared via a two-step solution deposition method under controlled ambient conditions. Our approach involves the application of poly(methyl methacrylate) (PMMA) and AZ5214 photoresist layers through spin-coating, aimed at singularly encapsulating the perovskite films. This encapsulation acts as a robust hydrophobic barrier, significantly mitigating moisture ingress and simultaneously addressing the challenge of pinhole presence within the perovskite structure. Through a series of detailed characterizations-spanning scanning electron microscopy (SEM), X-ray diffraction (XRD), and photoluminescence (PL) spectroscopy-we demonstrate that, despite the thicker nature of the AZ5214 photoresist compared to the PMMA layer, it exhibits markedly enhanced stability. Notably, the integrity and optical properties of the perovskite films are preserved for extended periods of up to 960 hours under environmental exposure. This breakthrough highlights the superior performance of AZ5214 photoresist over PMMA in prolonging the operational life of perovskite thin films, thereby offering a promising avenue for their deployment in a wide range of optoelectronic devices.
Text
2402.16177v2
- Author's Original
More information
Published date: 25 February 2024
Keywords:
physics.app-ph, physics.optics
Identifiers
Local EPrints ID: 487777
URI: http://eprints.soton.ac.uk/id/eprint/487777
PURE UUID: c5646f4c-e9ca-4bc9-bd73-d0c041841b60
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Date deposited: 05 Mar 2024 18:05
Last modified: 29 Apr 2024 02:04
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Contributors
Author:
Kimya FallaH
Author:
Shahab Norouzian Alam
Author:
Bijan Ghafari Ghomi
Author:
Farzane Yekekar
Author:
Shima Taghian
Author:
Sajjad Taravati
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