Determination of the exciton binding energy and effective masses for methylammonium and formamidinium lead tri-halide perovskite semiconductors

Gałkowski, Krzysztof; Mitioglu, Anatolie; Miyata, Atsuhiko; Plochocka, P.; Portugall, O.; Eperon, Giles E.; Wang, Jacob Tse-Wei; Στεργιόπουλος, Θωμάς; Stranks, Samuel D.; Snaith, Henry J.; Nicholas, R.J.

doi:10.1039/c5ee03435c

Cited by 643 publications

(748 citation statements)

References 51 publications

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“…Moreover, the related exciton binding energy Fig. 7 (c), is in agreement with the value of 25 ± 5 meV reported from low-temperature magnetoabsorption [23].…”

Section: E Summary Of Extracted Transition Energiessupporting

confidence: 90%

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Temperature-dependent optical spectra of single-crystal (CH3NH3)PbBr3 cleaved in ultrahigh vacuum

et al. 2017

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We measure temperature-dependent one-photon and two-photon induced photoluminescence from (CH3NH3)PbBr3 single crystals cleaved in ultrahigh vacuum. An approach is presented to extract absorption spectra from a comparison of both measurements. Cleaved crystals exhibit broad photoluminescence spectra. We identify the direct optical band gap of 2.31 eV. Below 200 K the band gap increases with temperature, and it decreases at elevated temperature, as described by the BoseEinstein model. An excitonic transition is found 22 meV below the band gap at temperatures < 200 K. Defect emission occurs at photon energies < 2.16 eV. In addition, we observe a transition at 2.25 eV (2.22 eV) in the orthorhombic (tetragonal and cubic) phase. Below 200 K, the associated exciton binding energy is also 22 meV, and the transition redshifts at higher temperature. The binding energy of the exciton related to the direct band gap, in contrast, decreases in the cubic phase. High-energy emission from free carriers is observed with higher intensity than reported in earlier studies. It disappears after exposing the crystals to air.

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“…Moreover, the related exciton binding energy Fig. 7 (c), is in agreement with the value of 25 ± 5 meV reported from low-temperature magnetoabsorption [23].…”

Section: E Summary Of Extracted Transition Energiessupporting

confidence: 90%

“…For example, exciton binding energies between 15 and 84 meV [23,[37][38][39][40][41][42] have been reported for (CH 3 NH 3 )PbBr 3 . These variations can be expected to be reduced by studying single crystals [43,44], opening the opportunity to approach the intrinsic photophysics of OIPS.…”

Section: Introductionmentioning

confidence: 99%

Temperature-dependent optical spectra of single-crystal (CH3NH3)PbBr3 cleaved in ultrahigh vacuum

et al. 2017

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“…[12][13][14][15][16][17] The vast majority of research conducted in this area has focused on "first generation" MAPbX 3 -based perovskites, [8,18] mainly due to the excellent tunability of their optoelectronic properties. [18,19] Characteristics such as high mobility, [20,21] high bimolecular recombination rate for charge carriers, [10] and low exciton binding energy [22][23][24] have resulted in the demonstration of high-performance films and devices for PV, LED, [9,12,[25][26][27] FET, [21] and lasing applications. [10,28] One potential drawback of the MAPbX 3 semiconductor family, however, is its relatively wide bandgap (3.2-1.6 eV), which dramatically limits its sensitivity in the near-IR (NIR) to mid-IR region of the solar spectrum.…”

Section: Doi: 101002/adma201604744mentioning

confidence: 99%

High Open‐Circuit Voltages in Tin‐Rich Low‐Bandgap Perovskite‐Based Planar Heterojunction Photovoltaics

et al. 2016

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] Of relevance to this work is the binary metal perovskite CH 3 NH 3 (Pb x Sn 1-x )I 3 [0 ≤ x ≤ 1]. [30,31] Interestingly, the bandgap bows and becomes lower when Sn 2+ is substituted by Pb 2+ for samples with 80% and 60% Sn content compared to 100% Sn-based perovskite, in line with previous observations. [30,31] While such tin-based perovskites offer tunable bandgaps down to 1.1 eV, the fabrication of efficient optoelectronic devices has been impeded by factors including poor semiconductor quality and low surface coverage. [30] As a consequence, solar cells made using these perovskites often exhibit very low efficiencies, with typical PCEs < 1% obtained for planar heterojunction devices. [30] To overcome this challenge, we have developed a novel elevated temperature processing method (depicted in Figure 1A), [32] for preparing CH 3 NH 3 (Pb x Sn 1-x )I 3 perovskites on a Poly(3,4-ethylenedioxythiophene):poly(styrenesulf onate) (PEDOT:PSS)/nickel oxide (NiO) bilayer, which results in the formation of large micron-sized grains ( Figure 1B) with almost complete substrate coverage. Our semiconductors not only exhibit relatively low energetic and structural disorder but also impart high PCEs when fabricated into a PV device. For PVs prepared using the lowest bandgap perovskites, open circuit voltages (V OC 's) approaching the prediction of the Shockley-Queisser (S-Q) model are demonstrated. Such promising performance metrics are obtained against a backdrop of fast radiative recombination and low photoluminescence quantum efficiencies (PLQEs), pointing toward the crucial role of high intrinsic charge carrier mobility in these low-bandgap semiconductors.To study the optical properties of the CH 3 NH 3 (Pb x Sn 1-x )I 3 [0 ≤ x ≤ 1] perovskite thin films, linear absorption and photoluminescence (PL) were measured as shown in Figure S1 (Supporting Information). It can be observed in Figure 1C that the bandgap bows as we substitute Pb 2+ in place of Sn 2+ (until 40% Sn 2+ ions are replaced by Pb 2+ ) and results in a nonmonotonic bandgap lowering similar to what was observed previously by Hao etal. [31] Briefly, the bandgap of the 60% and 80% Sn content films exhibit a lower bandgap than the 100% Sn-substituted films. A similar trend can also be traced in the PL spectra (see Figure S1B of the Supporting Information) where the PL spectra of 80% and 60% Sn content thin-film samples are red-shifted compared to the 100% Sn content thinfilm sample, which is consistent with the absorption spectra. Such anomalous bandgap bowing and lack of conformity with Vegard's law [31,33] have been attributed to the competition The performance of organometallic halide (hybrid) perovskite solar cells has improved dramatically in just a few years, with photovoltaic (PV) power conversion efficiencies (PCEs) now exceeding 22% for state-of-the-art devices. [1][2][3][4][5] This remarkable result, coupled with their low cost, tunability, and versatile lowtemperature preparation methods, makes hybrid perovskites one of the most promising semiconduct...

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“…Common Requirements [46,208] Copyright 2016, Nature Magneto-optical absorption spectroscopy [69] Polycrystalline 3D 22 Magneto-optical absorption spectroscopy [71] Polycrystalline 3D 2 Spectroscopic ellipsometry [66] Polycrystalline 3D 13 Optical absorption [72] Polycrystalline 3D 7 Electroabsorption Spectroscopy [8] Polycrystalline 3D 12 Magneto-optical absorption spectroscopy [73] CH3NH3PbBr3 Microcrystalline 3D 84 X-ray spectroscopy/Temperature dependent PL [74] Nanoparticle 3D 320 X-ray spectroscopy [74] Polycrystalline 3D 76 Magnetoabsorption [71] Polycrystalline 3D 40 Optical absorption [72] CH3NH3PbI3-xClx Polycrystalline 3D 55 Optical absorption [67] Polycrystalline 3D 10 Magneto-optical absorption spectroscopy [73] CH(NH2)2PbI3 Polycrystalline 3D 10 Magneto-optical absorption spectroscopy [73] CH(NH2)2PbBr3 Polycrystalline 3D 24 Magneto-optical absorption spectroscopy [73] (C9H19NH3)2PbI4 n/a 2D > 330 Temperature dependent PL [75] (C10H21NH3)2PbI4 Single crystal 2D 370 Optical absorption [76] (C6H5C2H4NH3)2PbI4 Polycrystalline 2D 350 Optical absorption [77] (NH2C(I)=NH2)3PbI5 n/a 1D > 410 Optical absorption [75] (CH3NH3)4PbI6•2H2O n/a 0D 545 Optical absorption [75] Eb: Exciton binding energy, PL: Photoluminescence Reproduced with permission. [98] Copyright 2014, Nature Publishing Group.…”

Section: Light Harvester Light Emittermentioning

confidence: 99%

Hybrid Perovskites: Effective Crystal Growth for Optoelectronic Applications

Jeon

Kim

Yoon

et al. 2017

Advanced Energy Materials

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Outstanding material properties of organic-inorganic hybrid perovskites have triggered a new research insight into the next-generation solar cells. Moreover, a wide range of controllable properties of hybrid perovskites particularly depending on crystal growth conditions enables versatile high performance optoelectronic devices such as light-emitting diodes, photodetectors and lasers beyond solar cells. This invited review article highlights recent progress of the crystallization strategies of organic-inorganic hybrid perovskites for effective light harvester or light emitter. In the first part, fundamental background on the perovskite crystalline structures and relevant optoelectronic properties such as optical band-gap, electron-hole behavior and energy band alignment are introduced. In the second part, detailed overview of the effective crystallization methods for perovskites, including thermal treatment, additives, solvent mediator, laser irradiation, nanostructure, crystal dimensionality and so on, is described to offer a comprehensive correlation among perovskite processing conditions, crystalline morphology and relevant device performances. Finally, future research direction is proposed to overcome current practical bottlenecks and move towards reliable high performance perovskite optoelectronic applications.3

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Determination of the exciton binding energy and effective masses for methylammonium and formamidinium lead tri-halide perovskite semiconductors

Cited by 643 publications

References 51 publications

Temperature-dependent optical spectra of single-crystal (CH3NH3)PbBr3 cleaved in ultrahigh vacuum

Temperature-dependent optical spectra of single-crystal (CH3NH3)PbBr3 cleaved in ultrahigh vacuum

High Open‐Circuit Voltages in Tin‐Rich Low‐Bandgap Perovskite‐Based Planar Heterojunction Photovoltaics

Hybrid Perovskites: Effective Crystal Growth for Optoelectronic Applications

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