Triple-Mesoscopic Carbon Perovskite Solar Cells: Materials, Processing and Applications

Meroni, Simone; Worsley, Carys; Raptis, Dimitrios; Watson, Trystan

doi:10.3390/en14020386

Cited by 35 publications

(36 citation statements)

References 161 publications

(289 reference statements)

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“…[ 240 ] Moreover, mesoscopic PPVs perform better in the early morning and late evening, but their PCE gets lower around. [ 241 ] Consequently, mesoscopic PPVs had been thought in the past to work better for lower illumination levels and ‐practically‐ indoor low light, be it either from a bulb or outdoor light through the window. They were thus considered suitable candidates for indoor applications and the IoT.…”

Section: Critical Parameters Under Low Light Environmentmentioning

confidence: 99%

“…They were thus considered suitable candidates for indoor applications and the IoT. [ 45,241 ] Recent advances, however in literature indicate a record output power density of 56.43 µWcm −2 for a planar inverted architecture (year 2020) [ 43 ] with a layer structure glass/ITO/NiO X /MAPbI 3 /PCBM/BCP/Ag, at a small active area (<1 cm 2 ) and 200 Lux halogen lighting. Larger areas of 5.68 cm 2 still hold a record output power density of 13.8 µW cm −2 since 2019 with repeatable results for a planar normal architecture with a layer structure of glass/ITO/MoO 3 /TPTPA/µΑPI/C 60 /TmPyPB/spiro‐MeOTAD/Au (all layers evaporated) and 200 Lux halogen lighting.…”

Section: Critical Parameters Under Low Light Environmentmentioning

confidence: 99%

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Indoor Perovskite Photovoltaics for the Internet of Things—Challenges and Opportunities toward Market Uptake

Polyzoidis

Rogdakis

Kymakis

2021

Advanced Energy Materials

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The high‐power conversion efficiency of flexible perovskite photovoltaics (PPV) at low light environment and their low‐cost manufacturing processes, render PPV superior to conventional rigid photovoltaics targeting indoor applications. However, various parameters related to materials, architecture, processing, and indoor characterization need to be optimized further toward improving indoor PPV (iPPV) efficiency, stability, and ecotoxicity. This work provides an overview of the recent progress, trends, and challenges in the field and suggests a holistic approach toward a viable design and integration of iPPVs into Internet of Things (IoT) platforms without any compromise on safety and cost effectiveness. The key impact of selecting proper materials and fabrication techniques, as well as optimizing the active area and architecture is described. Certain peculiarities of the indoor lighting conditions are discussed that can be addressed by proper simulation tools, including the understanding of the charge‐transfer mechanism, the diversification of the lamp types, as well as identifying the requirements for the production, standardization, and installation of iPPVs associated with IoT devices. A multidimensional engineering approach that considers aspects of architecture, light technology, load specifications, materials, processing, safety and cost, is proposed as a path toward accelerating iPPV market uptake for households, businesses, wearables and Industry 4.0 applications.

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Section: Critical Parameters Under Low Light Environmentmentioning

confidence: 99%

Section: Critical Parameters Under Low Light Environmentmentioning

confidence: 99%

Indoor Perovskite Photovoltaics for the Internet of Things—Challenges and Opportunities toward Market Uptake

Polyzoidis

Rogdakis

Kymakis

2021

Advanced Energy Materials

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“…Precursor infiltration can be influenced by several factors, including viscosity, wetting, colloidal diameters and crystallisation dynamics. 8,27,32,33 The following section will therefore examine the impact of MeOH addition on precursor viscosity, wetting, colloidal composition, and the resultant MAPbI 3 crystal properties.…”

Section: Resultsmentioning

confidence: 99%

“…5,6 Mesoscopic carbon-based perovskite solar cells (CPSCs) are frequently described as a potential frontrunner for PSC commercialization, as they are fabricated using easily scaled manufacturing processes and use stable, low-cost carbon electrodes in place of costly and unstable organic hole transport materials such as SPIRO-OMe-TAD. 7,8 Cell and modules are fabricated via sequential screen printing of thick mesoporous TiO 2 , ZrO 2 and carbon layers, before drop casting of the perovskite precursor. [9][10][11][12] Modules of up to 198 cm 2 are already present in the literature, as well as examples applying common industrial techniques such as Near-infra-red (NIR) annealing and inkjet printing.…”

Section: Introductionmentioning

confidence: 99%

Green solvent engineering for enhanced performance and reproducibility in printed carbon-based mesoscopic perovskite solar cells and modules

et al. 2022

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“…As a reference, the current record PCE of mesoporous carbon electrode cells is 17.02%, however, compared to our work, their devices utilize a NiO HTL and they used a two‐step deposition method to infiltrate a triple cation perovskite. [ 37 ] From here onward, we will concentrate on the AM0 performance as this is more appropriate when considering the aerospace applications of these m‐CPSCs. At 1 sun AM0, the champion cell has PCE > 10%, and the J sc is higher than that at 1 sun AM1.5G, as the light intensity of 1 sun AM0 is about 1.36 times higher than that at 1 sun AM1.5G (while the V OC and FF are similar to that under 1 sun AM1.5G).…”

Section: Resultsmentioning

confidence: 99%

Proton Radiation Hardness of Perovskite Solar Cells Utilizing a Mesoporous Carbon Electrode

et al. 2021

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When designing spacefaring vehicles and orbital instrumentation, the onboard systems such as microelectronics and solar cells require shielding to protect them from degradation brought on by collisions with high‐energy particles. Perovskite solar cells (PSCs) have been shown to be much more radiation stable than Si and GaAs devices, while also providing the ability to be fabricated on flexible substrates. However, even PSCs have their limits, with higher fluences being a cause of degradation. Herein, a novel solution utilizing a screen‐printed, mesoporous carbon electrode to act bi‐functionally as an encapsulate and the electrode is presented. It is demonstrated that the carbon electrode PSCs can withstand proton irradiation up to 1 × 1015 protons cm−2 at 150 KeV with negligible losses (<0.07%) in power conversion efficiency. The 12 μm thick electrode acts as efficient shielding for the perovskite embedded in the mesoporous TiO2. Through Raman and photoluminescence spectroscopy, results suggest that the structural properties of the perovskite and carbon remain intact. Simulations of the device structure show that superior radiation protection comes in conjunction with good device performance. This work highlights the potential of using a carbon electrode for future space electronics which is not limited to only solar cells.

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Triple-Mesoscopic Carbon Perovskite Solar Cells: Materials, Processing and Applications

Cited by 35 publications

References 161 publications

Indoor Perovskite Photovoltaics for the Internet of Things—Challenges and Opportunities toward Market Uptake

Indoor Perovskite Photovoltaics for the Internet of Things—Challenges and Opportunities toward Market Uptake

Green solvent engineering for enhanced performance and reproducibility in printed carbon-based mesoscopic perovskite solar cells and modules

Proton Radiation Hardness of Perovskite Solar Cells Utilizing a Mesoporous Carbon Electrode

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