Mixed Spacer Cation Stabilization of Blue‐Emitting <i>n</i> = 2 Ruddlesden–Popper Organic–Inorganic Halide Perovskite Films

Leung, Tik Lun; Tam, Ho Won; Liu, Fangzhou; Lin, Jingyang; Ng, Alan Man Ching; Chan, Wai Kin; Chen, Wei; He, Zhubing; Lončarić, Ivor; Grisanti, Luca; Ma, Chao; Wong, Kam Sing; Lau, Ying Suet; Zhu, Fu Rong; Skoko, Željko; Popović, Jasminka; Djurišić, Aleksandra B.

doi:10.1002/adom.201901679

Cited by 48 publications

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“…Substantial efforts have been made in the past several years to obtain blue perovskite emitters, such as perovskite nanocrystals (NCs), [ 19–25 ] 2D perovskite nanoplatelets, [ 26–32 ] and quasi‐2D perovskites. [ 33–39 ] In particular, the quasi‐2D perovskites are rising as efficient luminescent materials for highly performed blue PeLEDs due to the cascade energy landscape for efficient exciton transfer and the subsequent radiative recombination. Typically, the quasi‐2D perovskites have a formula of B 2 (APbBr 3 ) n −1 PbBr 4 , where B is an organic spacer cation, A is a monovalent cation (e.g., Cs + , methylammonium (MA + ) or formamidinium, (FA + )), and n represents the number of lead halide octahedral layers.…”

Section: Figurementioning

confidence: 99%

“…[42] Jin et al reported utilization of phenylbutylamine bromide (PBABr) as the spacer cation to construct PBABr y (Cs 0.7 FA 0.3 PbBr 3 ) with perovskite nanoparticles (NPs) embedded in quasi-2D phases, and obtained an EQE of 9.5% and lifetime of 250 s for the blue PeLEDs. [43] In addition, the joint organic cations, such as PEABr and butylammonium bromide (BABr), [34] PEABr and propylammonium bromide (PABr), [44] PEABr and iso-propylammonium bromide (IPABr), [39,45] and 1,4-Bis(aminomethyl) benzene bromide (P-PDABr 2 ) and PEABr [46] were also employed as the spacer cations to modulate the quasi-2D perovskite phase distribution for high phase purity and thus efficient light emission. Besides optimizing the organic spacer cations in quasi-2D perovskites, the composition of "A-site" has been also tuned to prolong PeLED operational stability, such as rubidium-cesium alloyed quasi-2D PEA 2 (Rb x Cs 1−x ) n−1 PbnBr 3n+1 perovskite, [47] and mixture of monovalent cation perovskite (e.g., PEA 2 (Cs/Rb/ FA/K)Pb n (Cl/Br) 3n+1 [48] ).…”

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High‐Performance Blue Perovskite Light‐Emitting Diodes Enabled by Efficient Energy Transfer between Coupled Quasi‐2D Perovskite Layers

et al. 2020

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Recently, impressive external quantum efficiencies (EQEs) exceeding 20% are obtained for green, red, and near-infrared perovskitebased LEDs (PeLEDs) through the efforts of perovskite material optimization and device architecture design. [8-10] These achievements firmly prompt the potential applications of PeLEDs in display and illumination fields. However, compared with the efficient PeLEDs, there is only moderate performance reported for blue PeLEDs, [11-18] which undoubtedly restrict PeLED applications in full-color displays and white-light illumination. Thus, the breakthroughs of the device performance are urgently required for blue PeLEDs. Substantial efforts have been made in the past several years to obtain blue perovskite emitters, such as perovskite nanocrystals (NCs), [19-25] 2D perovskite nanoplatelets, [26-32] and quasi-2D perovskites. [33-39] In particular, the quasi-2D perovskites are rising as efficient luminescent materials for highly performed blue PeLEDs due to the cascade energy landscape for efficient exciton transfer and the subsequent radiative recombination. Typically, the quasi-2D perovskites have a formula of B 2 (APbBr 3) n−1 PbBr 4 , While there has been extensive investigation into modulating quasi-2D perovskite compositions in light-emitting diodes (LEDs) for promoting their electroluminescence, very few reports have studied approaches involving enhancement of the energy transfer between quasi-2D perovskite layers of the film, which plays very important role for achieving high-performance perovskite LEDs (PeLEDs). In this work, a bifunctional ligand of 4-(2-aminoethyl)benzoic acid (ABA) cation is strategically introduced into the perovskite to diminish the weak van der Waals gap between individual perovskite layers for promoting coupled quasi-2D perovskite layers. In particular, the strengthened interaction between coupled quasi-2D perovskite layers favors an efficient energy transfer in the perovskite films. The introduced ABA can also simultaneously passivate the perovskite defects by reducing metallic Pb for less nonradiative recombination loss. Benefiting from the advanced properties of ABA incorporated perovskites, highly efficient blue PeLEDs with external quantum efficiency of 10.11% and a very long operational stability of 81.3 min, among the best performing blue quasi-2D PeLEDs, are achieved. Consequently, this work contributes an effective approach for high-performance and stable blue PeLEDs toward practical applications. Metal halide perovskites have emerged as competitive candidates for the next-generation light-emitting diodes (LEDs) due to their excellent optical properties, such as tunable light emission color, high color purity, and high photoluminescence The ORCID identification number(s) for the author(s) of this article can be found under

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High‐Performance Blue Perovskite Light‐Emitting Diodes Enabled by Efficient Energy Transfer between Coupled Quasi‐2D Perovskite Layers

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“…[18][19][20][21] The demand for UV photodetection is currently increasing in various fields, such as medical science, civilian and defense regions, biological detection, UV astronomy, and endoatmospheric sensing. [22][23][24][25][26][27][28] Combining Al plasmonics with GaN is an excellent method for various applications, such as ultrahigh responsivity, detectivity, and visible blind photodetection. Recently, Ahmadivand et al theoretically demonstrated the use of Al oligomers on GaN for ultraviolet photodetection; [29] however, experimental studies of Al plasmonics with GaN have not been performed.…”

Section: Doi: 101002/advs202002274mentioning

confidence: 99%

Aluminum Plasmonics Enriched Ultraviolet GaN Photodetector with Ultrahigh Responsivity, Detectivity, and Broad Bandwidth

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Plasmonics have been well investigated on photodetectors, particularly in IR and visible regimes. However, for a wide range of ultraviolet (UV) applications, plasmonics remain unavailable mainly because of the constrained optical properties of applicable plasmonic materials in the UV regime. Therefore, an epitaxial single-crystalline aluminum (Al) film, an abundant metal with high plasma frequency and low intrinsic loss is fabricated, on a wide bandgap semiconductive gallium nitride (GaN) to form a UV photodetector. By deliberately designing a periodic nanohole array in this Al film, localized surface plasmon resonance and extraordinary transmission are enabled; hence, the maximum responsivity (670 A W −1) and highest detectivity (1.48 × 10 15 cm Hz 1/2 W −1) is obtained at the resonance wavelength of 355 nm. In addition, owing to coupling among nanoholes, the bandwidth expands substantially, encompassing the entire UV range. Finally, a Schottky contact is formed between the single-crystalline Al nanohole array and the GaN substrate, resulting in a fast temporal response with a rise time of 51 ms and a fall time of 197 ms. To the best knowledge, the presented detectivity is the highest compared with those of other reported GaN photodetectors.

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“…[18] Most noteworthy, previous literature in the field already pointed out the importance of structural dynamics and local distortions in affecting the electronic features of hybrid halide perovskites, as related, for instance, to the variation of the optical properties with temperature, [36] as first step toward the formation of point defects, [37] to explain less effective electron-phonon scattering events. [38] We now turn to the collective electrostatic effects of the cations on the energy of the frontier crystalline orbitals. In 2D slabs, an extended monolayer of oriented dipoles produces a jump (ΔE) in electrostatic potential with respect to vacuum, which can be cast in terms of the component of the dipole moment orthogonal to the slab surface (μ z ) per unit area (A) via the Helmholtz relation (1) (where ε 0 is the vacuum dielectric constant).…”

Section: Computational Investigationmentioning

confidence: 99%

Spatial Charge Separation as the Origin of Anomalous Stark Effect in Fluorous 2D Hybrid Perovskites

Queloz

Bouduban

García‐Benito

et al. 2020

Adv Funct Materials

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2D hybrid perovskites (2DP) are versatile materials, whose electronic and optical properties can be tuned through the nature of the organic cations (even when those are seemingly electronically inert). Here, it is demonstrated that fluorination of the organic ligands yields glassy 2DP materials featuring long-lived correlated electron-hole pairs. Such states have a marked chargetransfer character, as revealed by the persistent Stark effect in the form of a second derivative in electroabsorption. Modeling shows that electrostatic effects associated with fluorination, combined with the steric hindrance due to the bulky side groups, drive the formation of spatially dislocated charge pairs with reduced recombination rates. This work enriches and broadens the current knowledge of the photophysics of 2DP, which will hopefully guide synthesis efforts toward novel materials with improved functionalities.

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Mixed Spacer Cation Stabilization of Blue‐Emitting n = 2 Ruddlesden–Popper Organic–Inorganic Halide Perovskite Films

Cited by 48 publications

References 59 publications

High‐Performance Blue Perovskite Light‐Emitting Diodes Enabled by Efficient Energy Transfer between Coupled Quasi‐2D Perovskite Layers

High‐Performance Blue Perovskite Light‐Emitting Diodes Enabled by Efficient Energy Transfer between Coupled Quasi‐2D Perovskite Layers

Aluminum Plasmonics Enriched Ultraviolet GaN Photodetector with Ultrahigh Responsivity, Detectivity, and Broad Bandwidth

Spatial Charge Separation as the Origin of Anomalous Stark Effect in Fluorous 2D Hybrid Perovskites

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