Homogeneous and highly controlled deposition of low viscosity inks and application on fully printable perovskite solar cells

Meroni, Simone; Mouhamad, Youmna; Rossi, Francesca De; Pockett, Adam; Baker, Jennifer; Escalante, Renán; Searle, Justin; Carnie, Matthew J.; Jewell, Eifion; Oskam, Gerko; Watson, Trystan

doi:10.1080/14686996.2017.1406777

Cited by 46 publications

(56 citation statements)

References 35 publications

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“…When working on large area substrates, it is important to avoid unnecessary thermal stress which can cause distortion of the substrate making it difficult to get a homogeneous printing of the thin (i.e., 800 nm) m‐TiO 2 across the large area. For this reason, the spraying of the compact TiO 2 blocking layer, both unpatterned and patterned, was carried out at 150 °C, rather than at 300 °C as per our standard fabrication method, before printing the mesoporous TiO 2 and sintering both layers at 550 °C.…”

Section: Resultsmentioning

confidence: 99%

All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency

Rossi

Baker

Beynon

et al. 2018

Adv Materials Technologies

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119

115

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mesoporous stack-titania (m-TiO 2 ), zirconia (ZrO 2 ), carbon (C)-is printable, C-PSCs are ideal for large scale production and, interestingly, some features that prevent degradation, i.e., lack of metal cathode [9] and organic HTM, [10] are also responsible for the simpler manufacturing process, paving the way for C-PSCs to move quickly from the lab to the market. This module architecture not only uses low-cost materials but can be produced by equipment that has a very low-capital cost thus reducing the barrier to commercialization of perovskite modules. Constraining the grain growth of the perovskite completely within the three mesoporous structures enables crystallization of the perovskite over large areas without the need for dynamic drying [11,12] to mimic the spin coating process. [13] There have been some reports demonstrating that C-PSC modules can be produced by screen printing, via registration of the overlapping layers, and can deliver between 10 and 11% power conversion efficiency (PCE) on 10 × 10 cm 2 substrates, with active areas ranging from 47.6 [7,14] to 70 cm 2 , [15] and, in particular, showing over 1 year stability under illumination, as reported by Grancini et al. [7] These results for C-PSC modules are even more remarkable, considering that modules with comparable active areas (>45 cm 2 ) and different device architecture, yielded respectively 12.6% PCE on 50.6 cm 2 (FTO/c-TiO 2 /graphene+m-TiO 2 / GO-Li/perovskite/spiro-OMeTAD/Au), [16] 8.7% PCE on 60 cm 2 (ITO/PEDOT:PSS/perovskite/PCBM/Au), [17] and 4.3% PCE on 100 cm 2 (FTO/c-TiO 2 /m-TiO 2 /perovskite/spiro-OMeTAD/ Au) [11] ; moreover, the record for PSC modules overall is Microquanta's 16% PCE [18,19] on just 16.29 cm 2 aperture area (active area + dead area for interconnections).Upscaling C-PSC manufacture from 10 × 10 cm 2 to larger substrate dimensions, e.g., A4 size as in our case, is far from trivial. Spraying the TiO 2 blocking layer (BL) at temperatures as high as 300 °C causes the large substrates to crack in the worst case or to bend, compromising the thickness homogeneity over the substrate of the printed layers, mostly and more crucially for the thinnest of the three, the sub-micrometric m-TiO 2 . Any change in the layers' thickness across the substrate can affect the performance of individual cells constituting the module Perovskite solar cells based on an all printable mesoporous stack, made of overlapping titania, zirconia, and carbon layers, represent a promising device architecture for both simple, low-cost manufacture, and outstanding stability. Here a breakthrough in the upscaling of this technology is reported: Screen printed modules on A4 sized conductive glass substrates, delivering power conversion efficiency (PCE) ranging from 3 to 5% at 1 sun on an unprecedented 198 cm 2 active area. An increase in the PCE, due to higher V OC and fill factor, is demonstrated by patterning the TiO 2 blocking layer. Furthermore, an unexpected increase of the performance is observed over time, while storing the modules in the dark,...

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Section: Resultsmentioning

confidence: 99%

All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency

Rossi

Baker

Beynon

et al. 2018

Adv Materials Technologies

Self Cite

119

115

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show abstract

“…The samples were prepared by screen‐printing commercially available pastes as described earlier 28,29. The perovskite solutions were drop‐casted on the different architectures, left at room temperature for 10 min, and then annealed at 50 °C for 1 h.…”

Section: Methodsmentioning

confidence: 99%

“…The lack of an expensive organic HTL such as 2,2′,7,7′‐tetrakis[ N , N ‐di(4‐methoxyphenyl)amino]‐9,9′‐spirobifluorene and the absence of a metal back contact, usually thermally evaporated silver or gold, make these devices potentially low cost 27. It has also been demonstrated that it is possible to screen‐print the mesoporous layers over large areas making it suitable for mass production 25,28–30. In the first demonstration, Ku et al obtained a 6.6% PCE device stable over 840 h in the dark using MAPI perovskite.…”

Section: Introductionmentioning

confidence: 99%

Investigating the Superoxide Formation and Stability in Mesoporous Carbon Perovskite Solar Cells with an Aminovaleric Acid Additive

Péan

Castro

Dimitrov

et al. 2020

Adv Funct Materials

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Perovskite solar cells have attracted a great deal of attention thanks to their high efficiency, ease of manufacturing, and potential low cost. However, the stability of these devices is considered their main drawback and needs to be addressed. Mesoporous carbon perovskite solar cells (m‐CPSC), consisting of three mesoporous layers (TiO2/ZrO2/C) infiltrated with CH3NH3PbI3 (MAPI) perovskite, have presented excellent lifetimes of more than 10 000 h when the additive NH2(CH2)4CO2HI (5‐ aminovaleric acid iodide; 5‐AVAI) is used to modify the perovskite structure. Yet, the role of 5‐AVAI in enhancing the stability has yet to be determined. Here, superoxide‐mediated degradation of MAPI m‐CPSC with and without the 5‐AVAI additive is studied using the fluorescence probe dihydroethidium for superoxide detection. In situ X‐ray diffractometry shows that aminovaleric acid methylammonium lead iodide (AVA‐MAPI) perovskite infiltrated in mesoporous layers presents higher stability in an ambient environment under illumination, evidenced by a slower decrease of the MAPI/PbI2 peak ratio. Superoxide yield measurements demonstrate that AVA‐MAPI generates more superoxide than regular MAPI when deposited on glass but generates significantly less when infiltrated in mesoporous layers. It is believed that superoxide formation in m‐CPSC is dependent on a combination of competitive factors including oxygen diffusion, sample morphology, grain size, and defect concentration.

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“…The AVA‐MAPI precursors solution was prepared with 439.0, 151.4, and 6.7 mg of, respectively PbI 2 , MAI, and 5‐AVAI in 1 mL of γ‐Butyrolactone. The solution was then deposited with the so‐called Robotic Mesh method . In this Robotic Mesh method, a robotic dispenser moves a syringe to continuously deliver the precursor solution at 12 m s −1 to a mesh which is on the top of the device to homogeneously spread the liquid on the surface.…”

Section: Methodsmentioning

confidence: 99%

Outstanding Indoor Performance of Perovskite Photovoltaic Cells – Effect of Device Architectures and Interlayers

et al. 2018

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Indoor photovoltaics is one of the best sustainable and reliable energy source for low power consumption electronics such as the rapidly growing Internet of Things. Perovskite photovoltaic (PPV) cells with three benchmark device architectures – mesoporous PPV (mPPV) and inverted PPV (iPPV) with alternative hole transporting layers (HTLs), and carbon‐based PPV (cPPV) are studied under a simulated indoor environment. The mPPV cell using typical Spiro‐OMeTAD as the HTL shows the highest maximum power density (Pmax) of 19.9 μW cm−2 under 200 lux and 115.6 μW cm−2 under 1000 lux (without masking), which is among the best of the indoor PV. Interestingly, when PTAA is used as the HTL in the mPPV cell, the Pmax drops to almost zero under indoor light environment while its performance under one sun remains similar. On the other hand, when PEDOT:PSS is replaced by Poly‐TPD as HTL in the iPPV cell, the Pmax under indoor light improves significantly and is comparable to that of the best mPPV cell. This significant difference in indoor performance correlates well with their leakage current. The HTL‐free cPPV cell, prepared by fully up‐scalable techniques, shows a promising Pmax of 16.3 and 89.4 μW cm−2 under 200 and 1000 lux, respectively. A practical scale 5 × 5cm2 cPPV module is fabricated as a demonstration for real applications.

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Homogeneous and highly controlled deposition of low viscosity inks and application on fully printable perovskite solar cells

Cited by 46 publications

References 35 publications

All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency

All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency

Investigating the Superoxide Formation and Stability in Mesoporous Carbon Perovskite Solar Cells with an Aminovaleric Acid Additive

Outstanding Indoor Performance of Perovskite Photovoltaic Cells – Effect of Device Architectures and Interlayers

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Homogeneous and highly controlled deposition of low viscosity inks and application on fully printable perovskite solar cells

Cited by 46 publications

References 35 publications

All Printable Perovskite Solar Modules with 198 cm2 Active Area and Over 6% Efficiency

All Printable Perovskite Solar Modules with 198 cm2 Active Area and Over 6% Efficiency

Investigating the Superoxide Formation and Stability in Mesoporous Carbon Perovskite Solar Cells with an Aminovaleric Acid Additive

Outstanding Indoor Performance of Perovskite Photovoltaic Cells – Effect of Device Architectures and Interlayers

Contact Info

Product

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All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency

All Printable Perovskite Solar Modules with 198 cm² Active Area and Over 6% Efficiency