High‐Sensitivity Flexible X‐Ray Detectors based on Printed Perovskite Inks

Ciavatti, Andrea; Sorrentino, R.; Basiricò, Laura; Passarella, Bianca; Caironi, Mario; Petrozza, Annamaria; Fraboni, Beatrice

doi:10.1002/adfm.202009072

Cited by 70 publications

(79 citation statements)

References 56 publications

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“…The latter value is the lowest achieved for perovskite thin film detectors [ 12,13,16,32 ] and is even comparable to the values obtained for high‐quality perovskite single crystals. [ 17,18 ] In fact, to the best of our knowledge, the only superior LoD was found for a 0D perovskite MA 3 Bi 2 I 9 single crystal with a value of 0.62 nGy s −1 . [ 56 ] This excellent LoD is notably permitted by the exceptionally low dark current that grants a signal‐to‐noise‐ratio suitable to detect such a small dose rate (see Figure S8, Supporting Information).…”

Section: Resultsmentioning

confidence: 98%

“…[ 7–9 ] Their most notable asset is however represented by their good processability, which allows to obtain centimetre‐scale single crystal with trap state densities in the order of 10 9 cm −3 using solution‐based techniques at low temperature (<100 °C). [ 10,11 ] On the one hand HOIPs detectors based on polycrystalline morphologies exhibit fairly good performances, [ 12–17 ] however they are limited by lower bulk resistivity, [ 18 ] higher trap states density, [ 9 ] and significant ion migration effects leading to large dark current drift [ 19 ] with respect to HOIPs detectors based on single crystals. [ 11,20,21 ] Briefly, single crystal‐based devices suffer from the difficulty to produce large‐area pixelated detectors directly integrated onto read‐out electronics, and therefore showing a lack of scalability.…”

Section: Introductionmentioning

confidence: 99%

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Ultra‐Stable and Robust Response to X‐Rays in 2D Layered Perovskite Micro‐Crystalline Films Directly Deposited on Flexible Substrate

Lédée

Ciavatti

Verdi

et al. 2021

Advanced Optical Materials

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2D layered hybrid perovskites have recently attracted an increasing interest as active layers in LEDs and UV–Vis photodetectors. 2D perovskites crystallize in a natural self‐assembled quantum well‐like structure and possess several interesting features among which low‐temperature (<100 °C) synthesis and low defect density. Here are presented solid‐state ionizing radiation direct detectors based on the 2D layered hybrid perovskite PEA2PbBr4 (PEA = C6H5C2H4NH3+) deposited from solution using scalable techniques and directly integrated onto a pre‐patterned flexible substrate in the form of micro‐crystalline films displaying crystal‐like behavior, as evidenced by the ultra‐fast (sub‐microsecond) and good detection performances under UV light. The effective detection of X‐rays (up to 150 kVp) is demonstrated with sensitivity values up to 806 µC Gy−1 cm−2 and Limit of Detection of 42 nGy s−1, thus combining the excellent performance for two relevant figures of merit for solid‐state detectors. Additionally, the tested devices exhibit exceptionally stable response under constant irradiation and bias, assessing the material robustness and the intimate electrical contact with the electrodes. PEA2PbBr4 micro‐crystalline films directly grown on flexible pre‐patterned substrate open the way for large‐area solid‐state detectors working at low radiation flux for ultra‐fast X‐ray imaging and dosimetry.

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Section: Resultsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Ultra‐Stable and Robust Response to X‐Rays in 2D Layered Perovskite Micro‐Crystalline Films Directly Deposited on Flexible Substrate

Lédée

Ciavatti

Verdi

et al. 2021

Advanced Optical Materials

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“…In addition to F-PSCs, photodetectors and photomemristors, other perovskite devices have been demonstrated. [105][106][107][108][109] Perovskites are the promising emitters with high color purity and excellent photoluminescence quantum yield. In 2014, Tan et al fabricated perovskite LEDs at room temperature.…”

Section: Light-emitting Diodesmentioning

confidence: 99%

Flexible and Wearable Optoelectronic Devices Based on Perovskites

Zhao

et al. 2021

Adv Materials Technologies

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PCE) values than the single-junction solar cells. [11,12] In addition, perovskites have shown emerging applications in lightemitting diodes (LEDs), photodetectors and other fields. These devices are fabricated on the rigid substrate initially, which limit their applications in the emerging intelligent devices, such as flexible display and intelligent sensor. [13,14] Flexible devices with stretchability and crumpling durability are capable of realizing portable and wearable application. Kumar et al. reported the first flexible-perovskite solar cells (F-PSCs) with PCE of 2.6%. [15] With the optimization of devices and deep understanding of perovskite materials, the highest PCE of F-PSCs is more than 20%. [16] The artemisinin passivation strategy was used to reduce the trap density through the interaction between artemisinin and the uncoordinated Pb 2+ . The PCE of flexible devices is often limited by their low-temperature manufacturing process. Generally, perovskite optoelectronic devices can be prepared by solution method. [9,10] So far, the flexible devices have been reported by various methods, such as vapor deposition, [17] inkjet printing, [18][19][20] slot-die coating. [21][22][23] These fabrication methods with low-cost and simplicity are suitable for large-scale fabrication of flexible devices. The flexibility of optoelectronic devices is influenced by many aspects, such as the substrates, carrier transport layers, photoactive layers, and electrodes in the structure of F-PSCs. Different from the rigid devices, flexible devices are commonly fabricated on substrate with flexibility, such as polyethylene terephthalate (PET), polyethylene 2,6-naphthalate (PEN), polyimide (PI), [24][25][26] metal foil. [27,28] For substrate of F-PSCs, metal foil has excellent conductivity, flexibility, and thermal stability, but its low light transmittance could limit its application in optoelectronic devices. [29] Indium tin oxide (ITO) is commonly used as electrode material because of its excellent light transmittance and low electrical resistance, [30] while the brittleness limits its application. [31] The metal mesh electrode is a substitute for the flexible electrode with high conductivity and excellent transmittance. [32] The electron transport layer (ETL) is also important component of F-PSCs. TiO 2 is a widely used ETL in perovskite devices because of its suitable energy band position. [33] However, the low heat resistance of PEN and PET polymer substrates limits the processing temperature of TiO 2 in the preparation process. [34] Hence, many low temperature preparation methods about TiO 2 and new ETL materials have been developed. [34,35] Ethoxylated-polyethylenimine is often used for ETL in flexible devices because it is flexible and can improve electronic transport performance. [36] Another Perovskites as promising photovoltaic materials have been widely investigated due to their excellent photoelectric properties. Perovskite optoelectronic devices have been applied in fields of portable energy, light monitors, image ...

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“…Flexible perovskite-based X-ray detectors have been less explored but, in the last years, the number of reports on their feasibility is rapidly growing. [35][36][37] The possibility of conforming ionizing radiation detectors and dosimeters onto a nonflat object is one of the primary desired features needed, for example, when detectors have to be integrated inside specific probes during radiation therapy, [38] or in easy-wearable objects (e.g., bracelets and belt) and for potential vignetting limitation. Recently, Zhao et al [39] proposed a highly sensitive and flexible direct X-ray detector based on a porous nylon membrane with metal halide perovskite loaded by the infiltration method.…”

Section: Introductionmentioning

confidence: 99%

Fully Textile X‐Ray Detectors Based on Fabric‐Embedded Perovskite Crystals

Possanzini

Basiricò

Ciavatti

et al. 2022

Adv Materials Inter

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properties due to an external stimulus, designed to measure biopotential, [6][7][8] temperature, [9] movements as pressure, [10] or strain, [11] sweat content, [12][13][14] or as energy harvesting (thermoelectrics, [15,16] triboelectrics, [17] and biofuel cells [18] ), and storage platforms. [19,20] The flexible, comfortable, and breathable nature of fabrics makes these substrates ideal candidates for developing large-area wearable devices in direct contact with the human body. Despite the high number of different textile sensors realized so far, textile ionizing radiation detectors have not been proposed yet, mostly due to the incompatibility between conventional materials for radiation sensing and fabric substrates. The development of innovative functional materials and low-cost technologies for the detection of ionizing radiations has become an urgent need in the last years due to the relevant increase in the use of ionizing radiation in many aspects of modern society, from medical applications to civil security. In particular, flexible and wearable innovative dosimeters are highly requested in hazardous environments, e.g., for personnel and patients in medical therapy and for space missions' crew. Commercially available personal dosimeters and diagnostic detectors, based on inorganic materials (e.g., silicon-based solid-state devices for dosimeters, a-Si, a-Se, or poly-cadmium zinc telluride for large-area flat panels) are heavy, bulky, rigid, and uncomfortable to be worn. Furthermore, they are difficult to implement in large, pixelated matrices by means of low-cost and low-tech fabrication techniques. In the last years, a new generation of X-ray detectors has been explored, based on organic semiconductors [21][22][23] and perovskites, [24][25][26] two classes of materials that allow for liquid phase deposition methods, enabling an easy device scaling up to large areas and the implementation on unconventional flexible substrates, such as thin plastic foils [27,28] and even fabrics. [29][30][31] Lead halide perovskites are an emerging and promising class of materials for X-ray detection, thanks to their utmost electric transport properties, (i.e., high charge carrier mobilities and long carrier lifetime), excellent optical properties, together with high ionizing radiation stopping power due to the presence of heavy atoms (e.g., Br, Pb, or I) in their molecular structure. The combination of all these features has led to impressive performance of lead halide perovskite devices in the direct detection of X-rays and gamma rays, both in films [31] and single crystal forms. [32][33][34] However, despite their excellent performance, single crystals retain a mechanical stiffness preventing the implementation

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High‐Sensitivity Flexible X‐Ray Detectors based on Printed Perovskite Inks

Cited by 70 publications

References 56 publications

Ultra‐Stable and Robust Response to X‐Rays in 2D Layered Perovskite Micro‐Crystalline Films Directly Deposited on Flexible Substrate

Ultra‐Stable and Robust Response to X‐Rays in 2D Layered Perovskite Micro‐Crystalline Films Directly Deposited on Flexible Substrate

Flexible and Wearable Optoelectronic Devices Based on Perovskites

Fully Textile X‐Ray Detectors Based on Fabric‐Embedded Perovskite Crystals

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