Photophysics of Two‐Dimensional Perovskites—Learning from Metal Halide Substitution

Kahmann, Simon; Duim, Herman; Fang, Hong‐Hua; Dyksik, Mateusz; Adjokatse, Sampson; Rivera-Medina, Martha Judith; Pitaro, Matteo; Płochocka, Paulina; Loi, Maria Antonietta

doi:10.1002/adfm.202103778

Cited by 55 publications

(91 citation statements)

References 49 publications

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“…Simultaneously, the two shoulders observed in the room temperature luminescence move closer together, as observed above for PDMAPbI 4 and similarly reported for Ruddlesden-Popper compounds. [25] Following similar observations for RP structures based on PEA + , the temperature-dependent spectral shifts of PDMASnI 4 are more pronounced than for the Pb-based compound: [16] For example, the energy of the higher PL peak decreases from 2.01 to 1.93 eV over the temperature range (approx. 80 vs. 30 meV; Sn vs. Pb).…”

Section: Resultssupporting

confidence: 60%

“…Metal substitution shifts the excitonic peak energy toward the red spectral region when using Sn instead of Pb, as similarly observed for RP or 3D structures. [16,24] In the current case, the absorbance of PDMAPbI 4 has a maximum around 2.41 eV, while that of the Sn-variant lies around 2.08 eV. The luminescence exhibits a relatively small Stokes shift in both cases (emission around 2.39 and 1.85 eV).…”

Section: Resultsmentioning

confidence: 59%

“…The overall band edge luminescence narrows, as expected from the suppression of thermal broadening, but it remains broad when compared to similar compounds based on primary amines. [14,16,19] While the absorbance spectra follow this general trend, cooling also allows for a clear distinction of two peaks at 2.39 and 2.44 eV at 5.4 K. Notably, the low energy shoulder of the PL seems to blue shift at lower temperature-also consider the absolute intensity in Figure S5, Supporting Information. PDMASnI 4 behaves similarly.…”

Section: Resultsmentioning

confidence: 72%

“…We note that the presence of such a pronounced second emission peak in Sn-based 2D perovskite structures seems to be a general observation. [16,26,27] At the same time, we would like to note that the limited intensity increase of PDMAPbI 4 at low temperature is also related to a further broad emission band at significantly lower energy, typical for leadbased 2D perovskites, as discussed further below. Additional data on the dynamics of the PL can be found in Figures S7 to S9, Supporting Information .…”

Section: Resultsmentioning

confidence: 81%

“…However, there is no consensus on the origin of the vibrational modes responsible for the observed spectral features and the actual mechanisms at play. [14][15][16] Slightly Stokes-shifted band edge emission and split sub-peaks have been analyzed in the framework of dark and bright excitons, [17,18] bright doublets, [19] localized defects, [16,20] and have been shown to depend on the angle of detection. [20,21] At even lower energy, broad emission bands are sometimes attributed to self-trapped excitons, but have recently been proposed to be defect-related.…”

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confidence: 99%

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Grain‐Specific Transitions Determine the Band Edge Luminescence in Dion–Jacobson Type 2D Perovskites

Kahmann

Duim

Rommens

et al. 2021

Advanced Optical Materials

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metal halide octahedra.This opens a rich playing field for tuning the photophysical properties of these 2D compounds targeted to a variety of opto-electronic applications. [1] Many studies have considered 2D compounds to increase the stability of 3D perovskites in solar cells and to facilitate charge extraction or to act as efficient emitters in light emitting devices. [2,3] The choice of the spacer cation can affect factors, such as moisture resistivity, [4] or the degree of distortion in the inorganic slabs, which partially governs the band gap energy [5] or the carrier effective masses. [6] Recently, also the imposition of optical chirality [7] or the mixing of states between spacers and inorganic moieties have become important topics of research. [8] Traditionally, most of the organic spacers have been based on primary amines, such as the prototypical butylammonium (BA + ) or phenylethylammonium (PEA + ) giving rise to A 2 MX 4 chemical formulas in so-called Ruddlesden-Popper (RP) compounds, where A is the spacer cation, M the metal cation, and X the halide anion. [1] More recently, diammonium cations, forming AMX 4 Dion-Jacobson (DJ) structures, have moved into the spotlight of research. [9,10] Instead of two spacer cations per unit cell, these compounds possess only one organic molecule with two functional groups to stabilize the layered structure. Although employed in solar cells and characterized for this purpose, [11][12][13] fundamental studies on their photophysics are so far scarce.The photophysics of 2D perovskites exhibits several intensively studied aspects. In particular, low-temperature studies reveal a rich substructure of the excitonic luminescence and absorption. High-energy features are commonly explained through exciton-phonon interactions. However, there is no consensus on the origin of the vibrational modes responsible for the observed spectral features and the actual mechanisms at play. [14][15][16] Slightly Stokes-shifted band edge emission and split sub-peaks have been analyzed in the framework of dark and bright excitons, [17,18] bright doublets, [19] localized defects, [16,20] and have been shown to depend on the angle of detection. [20,21] At even lower energy, broad emission bands are sometimes attributed to self-trapped excitons, but have recently been proposed to be defect-related. [22] Here, we report on the photophysics of the prototypical compounds PDMAPbI 4 and PDMASnI 4 , which are based on the The photophysics of 2D perovskites incorporating 1,4-phenylenedimethanammonium (PDMA) as spacer cations is studied. PDMAPbI 4 and PDMASnI 4 exhibit absorption and luminescence spectra dominated by excitonic transitions and an emission due to two different states. Low-temperature studies reveal a time-dependent red shift of 12 meV that is correlated with grain-specific luminescence spectra observed in optical micrographs. For the Pb-variant, grains of red-shifted and lower intensity band edge emission simultaneously exhibit a more pronounced luminescence from a broad defect-related band...

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Section: Resultssupporting

confidence: 60%

Section: Resultsmentioning

confidence: 59%

Section: Resultsmentioning

confidence: 72%

Section: Resultsmentioning

confidence: 81%

mentioning

confidence: 99%

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Grain‐Specific Transitions Determine the Band Edge Luminescence in Dion–Jacobson Type 2D Perovskites

Kahmann

Duim

Rommens

et al. 2021

Advanced Optical Materials

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Influence of Organic Spacer Cation on Dark Excitons in 2D Perovskites

Bailey,

Gillan,

Lee

et al. 2023

Adv Funct Materials

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The organic spacer cation plays a crucial role in determining the exciton fine structure in 2D perovskites. Here, magneto‐optical spectroscopy is used to gain insight into the influence of the organic spacer on dark excitons in Ruddlesden–Popper (RP) perovskites. Using modest magnetic field strengths (<1.5 T), the optically forbidden dark exciton state can be identified and its emission properties significantly modulated via application of in‐plane magnetic fields, up to temperatures of 15 K. At low temperatures, an increase in collected photoluminescence efficiency of >30% is demonstrated, signifying the critical role of the dark exciton state for light‐emitting applications of 2D perovskites. The exciton fine structure and the degree of magnetic‐field‐induced mixing are significantly impacted by the choice of organic spacer cation, with 4–methoxyphenylethylammonium (MeO‐PEA) showing the largest effect due to larger bright–dark exciton splitting. This study distinguishes between interior (bulk) and surface dark‐exciton emission, showing that bright–dark exciton splitting differs between the interior and surface. The results emphasize the significance of the organic spacer cation in controlling the exciton fine structure in 2D perovskites and have important implications for the development of optoelectronic technology based on 2D perovskites.

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Achieving Inkjet‐Printed 2D Tin Iodide Perovskites: Excitonic and Electro‐Optical Properties

Chirvony,

Muñoz‐Matutano,

Suárez

et al. 2024

Adv Funct Materials

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Currently, there is a great demand for non‐toxic lead‐free halide perovskites as active materials for solar cells, light‐emitting diodes and other optoelectronic devices. Although an essential progress has been made using tin(II) halide perovskites, still greater efforts are needed to improve their stability and manufacture films and devices under a scalable technology. The first goal of the work is to achieve suitable physical properties of 2D Sn(II) polycrystalline perovskite films obtained by the industrially scalable inkjet printing deposition technique. In the present work, inks of 2D tin(II) halide perovskite 2‐thiopheneethylammonium tin(II) iodide, TEA2SnI4, have been successfully formulated in DMF (toxic) and DMSO (non‐toxic) solutions and using appropriate additives (SnF2 and reducing agents) for improving the stability of the inks and the resulting films. Room‐ and low‐temperature excitonic photoluminescence (PL), charge carrier recombination dynamics and µ‐PL is used to explain the observed two excitonic bands, which are associated to the bulk and edges of perovskite grains nanoplatelet‐like composing the polycrystalline films. Promising electro‐optical properties are also obtained in the TEA2SnI4 films inkjet‐printed from DMSO formulations onto ITO‐interdigitated electrodes, such as low dark currents, ≈10 – 20 nA at 10 V of bias voltage, and high responsivities ≈1–20 A/W.

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Photophysics of Two‐Dimensional Perovskites—Learning from Metal Halide Substitution

Cited by 55 publications

References 49 publications

Grain‐Specific Transitions Determine the Band Edge Luminescence in Dion–Jacobson Type 2D Perovskites

Grain‐Specific Transitions Determine the Band Edge Luminescence in Dion–Jacobson Type 2D Perovskites

Influence of Organic Spacer Cation on Dark Excitons in 2D Perovskites

Achieving Inkjet‐Printed 2D Tin Iodide Perovskites: Excitonic and Electro‐Optical Properties

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