Unconventional excitonic states with phonon sidebands in layered silicon diphosphide

Zhou, Ling; Huang, Junwei; Windgaetter, Lukas; Ong, Chin Shen; Zhao, Xiuxi; Zhang, Caorong; Tang, Ming; Li, Zeya; Qiu, Caiyu; Latini, Simone; Lu, Yangfan; Wu, Di; Gou, Huiyang; Wee, Andrew T. S.; Hosono, Hideo; Louie, Steven G.; Tang, Peizhe; Rubio, Ángel; Yuan, Huatang

doi:10.1038/s41563-022-01285-3

Cited by 23 publications

(30 citation statements)

References 58 publications

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“…Reduced dielectric screen- electron−hole separation or spatial delocalization, also called exciton Bohr radius) and exciton binding energy, remarkably different from those in bulk materials. 14 Increased Coulomb interaction, as discussed above, significantly hinders the dissociation of photoinduced electron−hole pairs, which in turn can severely limit the photocatalytic activity. Herein, employing GW approximation, we have not only analyzed the behavior of excitons arising in GaTeI and InTeI monolayers in the different dielectric environments but also have shown that the presence of a dielectric environment significantly reduces the exciton binding energy that is desirable for charge separation.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, materials with reduced dimensionality present a new avenue for fundamental exciton physics. − The ultrathin nature of 2D materials, that is, strong geometrical confinement, causes weak dielectric screening, which gives rise to increased Coulomb interaction. Reduced dielectric screening and enhanced Coulomb interaction in 2D materials can cause exciton properties, like exciton extension (bound electron–hole separation or spatial delocalization, also called exciton Bohr radius) and exciton binding energy, remarkably different from those in bulk materials . Increased Coulomb interaction, as discussed above, significantly hinders the dissociation of photoinduced electron–hole pairs, which in turn can severely limit the photocatalytic activity.…”

Section: Introductionmentioning

confidence: 99%

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Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

Kishore¹,

Tripathy²,

Sarkar³

2023

J. Phys. Chem. C

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Two-dimensional materials for efficient visible-light-driven photocatalytic water splitting after the era of TiO2 and other metal oxides are scarce. Recent years have witnessed an upsurge in the research of nonoxide semiconductors for overall photocatalytic water splitting. Herein, XTeI (X = Ga, In) monolayers are demonstrated to be stable water-splitting photocatalysts. Merely 0.1 (0.03) V of additional voltage is required to drive the oxidation evolution reaction by the GaTeI (InTeI) monolayer. As these monolayers exhibit a higher valence band position than traditional metal oxides, implying a narrower band gap, they are suitable as efficient visible-light-driven photocatalysts with an absorption coefficient of ∼10–5 cm–1 in the visible range of the solar spectrum. Anisotropic carrier mobilities favor charge separation and reduce their recombination. Exciton properties have been analyzed in-depth via GW approximation. Exciton spatial extension and exciton binding energy are found to exhibit a highly anisotropic nature. The exciton binding energies of GaTeI and InTeI on different substrates, like SiO2 and h-BN, range from ∼14 meV to ∼0.2 eV, which are even smaller than those in TMDs. These facilitate easier charge separation, making them favorable photocatalysts.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

Kishore¹,

Tripathy²,

Sarkar³

2023

J. Phys. Chem. C

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“…However, most of them are not competent for ultrasensitive photodetection owing to the high dark currents and low detectivity. , Recently, a new family of group IV and group V 2D layered materials such as GeP, GeAs 2 , SiAs 2 , SiP, and SiP 2 have emerged as promising candidate 2D materials for high-performance photoelectric devices. − As an important member of group IV and group V 2D materials, SiP 2 is a new semiconductor with a tunable bandgap (1.99–2.25 eV), strong light absorption ability, and excellent air stability. − In addition, the high carrier mobility of 1.069 × 10 5 cm 2 V –1 s –1 was theoretically predicted for monolayer SiP 2 , which can be comparable to that of graphene . Notably, the intrinsic anisotropic structure induced by zigzag phosphorus–phosphorus chains in 2D SiP 2 directly results in unique physical properties, revealing an unconventionally bright exciton with hybrid dimensionality of band-edge states . However, to date, the field effect transistor (FET) properties and gate-controlled phototransistor of SiP 2 have not yet been explored, not to mention its ultrasensitive phototransistor performance.…”

Section: Introductionmentioning

confidence: 99%

“…16 Notably, the intrinsic anisotropic structure induced by zigzag phosphorus−phosphorus chains in 2D SiP 2 directly results in unique physical properties, revealing an unconventionally bright exciton with hybrid dimensionality of band-edge states. 17 However, to date, the field effect transistor (FET) properties and gate-controlled phototransistor of SiP 2…”

Section: ■ Introductionmentioning

confidence: 99%

2D SiP₂/h-BN for a Gate-Controlled Phototransistor with Ultrahigh Sensitivity

Wang

Wei

Wang

et al. 2023

ACS Appl. Mater. Interfaces

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Two-dimensional (2D) materials are extremely attractive for the construction of highly sensitive photodetectors due to their unique electronic and optical properties. However, developing 2D photodetectors with ultrahigh sensitivity for extremely low-light-level detection is still a challenge owing to the limitation of high dark current and low detectivity. Herein, a gate-controlled phototransistor based on 2D SiP2/hexagonal boron nitride (h-BN) was rationally designed and demonstrated ultrahigh sensitivity for the first time. With a back-gate device geometry, the SiP2/h-BN phototransistor exhibits an ultrahigh detectivity of 3.4 × 1013 Jones, which is one of the highest values among 2D material-based photodetectors. In addition, the phototransistor also shows a gate tunable responsivity of ≤43.5 A/W at a gate voltage of 30 V due to the photogating effect. The ultrahigh sensitivity of the SiP2-based phototransistor is attributed to the extremely low dark current suppressed by the phototransistor configuration and the improved photocurrent by using h-BN as a substrate to reduce charge scattering. This work provides a facile strategy for improving the detectivity of photodetectors and validates the great potential of 2D SiP2 phototransistors for ultrasensitive optoelectronic applications.

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“…[6,7] Overall our results highlight the general importance of exciton coupling to optical phonons in this class of materials and they further suggest that also the peculiar spatial symmetry of the excitonic states and phonon modes needs to be accounted for in a proper treatment of exciton−phonon coupling. [21]…”

Section: Introductionmentioning

confidence: 99%

Anharmonic Exciton‐Phonon Coupling in Metal‐Organic Chalcogenides Hybrid Quantum Wells

Kastl

Bonfà

Maserati

2023

Advanced Optical Materials

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conditions, and recent improvements in their synthesis approaches allow producing high-quality samples suitable both for spectroscopic investigation and device fabrication. [3][4][5] In particular, the excitonic behavior of [AgSePh] ∞ , a prototypical MOC, has just been investigated by us, [6,7] and two other groups, [8][9][10] highlighting strongly bound anisotropic resonances with blue, direct gap emission and very short lifetime. This short exciton lifetime is peculiar and could be potentially leveraged for ultrafast optical applications. As we recently reported, the [AgSePh] ∞ ultrafast de-excitation appears to be dominated potentially by intrinsic selftrapping of excitons. [6,7] Such self-trapping of carriers often occurs in semiconductors with a large electron-phonon coupling. [11] In the latter case, a proper description of optical excitations needs to consider the dressing of excitons with lattice phonons, which ultimately gives rise to a new quasiparticle, the exciton-polaron, in the strong interaction limit. While the subfield of 2D MHPs already reported several experiments highlighting the important role of phonons and lattice distortions in the optical transitions and carrier dynamics, [12][13][14][15][16][17] the HQWs based on MOCs still lack an understanding of such interplay between excitons and phonons.Here, we study exciton-phonon coupling in the prototypical MOC [AgSePh] ∞ by a combination of time-resolved and time-integrated optical spectroscopies. Impulsive stimulated Raman scattering (ISRS) [18,19] via resonant transient absorption In contrast to inorganic quantum wells, hybrid quantum wells (HQWs) based on metal-organic semiconductors are characterized by relatively soft lattices, in which excitonic states can strongly couple to lattice phonons. Therefore, understanding the lattice's impact on exciton dynamics is essential for harnessing the optoelectronic potential of HQWs. Beyond 2D metal halide perovskites, layered metal-organic chalcogenides (MOCs), which are an airstable, underexplored material class hosting room-temperature excitons, can be exploited as photodetectors, light emitting devices, and ultrafast photoswitches. Here, the role of phonons in the optical transitions of the prototypical MOC [AgSePh] ∞ is elucidated. Impulsive stimulated Raman scattering (ISRS) allows the detection of coherent exciton oscillations driven by Fröhlich interaction with low-energy optical phonons. Steady state absorption and Raman spectroscopies reveal a strong exciton-phonon coupling (Huang-Rhys parameter ≈1.7) and its anharmonicity, manifested as a nontrivial temperaturedependent Stokes shift. The ab initio calculations support these observations, hinting at an anharmonic behavior of the low-energy phonons <200 cm −1 . These results untangle complex exciton-phonon interactions in MOCs, establishing an ideal testbed for room-temperature many-body phenomena.

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Unconventional excitonic states with phonon sidebands in layered silicon diphosphide

Cited by 23 publications

References 58 publications

Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

2D SiP₂/h-BN for a Gate-Controlled Phototransistor with Ultrahigh Sensitivity

Anharmonic Exciton‐Phonon Coupling in Metal‐Organic Chalcogenides Hybrid Quantum Wells

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Unconventional excitonic states with phonon sidebands in layered silicon diphosphide

Cited by 23 publications

References 58 publications

Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

Unconventional Anisotropy in Excitonic Properties and Carrier Mobility in Iodine-Based XTeI (X = Ga, In) Monolayers for Visible-Light Photocatalytic Water Splitting

2D SiP2/h-BN for a Gate-Controlled Phototransistor with Ultrahigh Sensitivity

Anharmonic Exciton‐Phonon Coupling in Metal‐Organic Chalcogenides Hybrid Quantum Wells

Contact Info

Product

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2D SiP₂/h-BN for a Gate-Controlled Phototransistor with Ultrahigh Sensitivity