Modulation of photocarrier relaxation dynamics in two-dimensional semiconductors

Wang, Yuhan; Nie, Zhonghui; Wang, Frank

doi:10.1038/s41377-020-00430-4

Cited by 57 publications

(41 citation statements)

References 110 publications

(147 reference statements)

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“…It is well-known that the exciton binding energy in a 2D system is larger than that in 3D counterpart due to enhanced Coulomb interactions. [56] Here, the introduction of fluorine leads to the subtle changes of the dielectric constant, denoted ε 1 for PEPI and ε 2 for FPEPI, shown in the left panel of Figure 2b. In the linear, nonmagnetic, and phenomenological framework, the dielectric constant can be expressed as ε r = 1+Nα e /ε 0 , where N is atomic density, α e is atomic/molecular polarizability, and ε 0 is dielectric constant in vacuum.…”

Section: Preparation and Properties Of Pepi And Fpepimentioning

confidence: 99%

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Zhuang

Shi

et al. 2021

Adv Materials Inter

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much attention due to excitonic property in physics and devices. [18] Stability is the largest obstacle to hinder further development of HOIP materials and devices. [19][20][21] The soft-lattice nature of perovskite directly contributes to the excellent performances of the material by the large high-density defects toleration, [22] however, becomes a serious reason of degradation in turn. The degradation could be caused by internal factors, for example, lattice strain, [23] atomic vacancies, etc., [24] and also could be by external factors, such as light-illumination, [25,26] temperature, [27,28] humidity, [29,30] oxygen in ambient condition, etc. Considerable efforts are focusing on the internal factors of degradation from view of molecule design, for example, doping [23] and lattice-anchoring [31] to release internal strain, ligands engineering [24,32,33] for surface passivation, interfacial engineering to enhance moisture stability, [34] and even redox strategy [35] to recover materials. For external factors, an intuitive strategy is physically isolating perovskites from ambient environments, such as encapsulation with polymers, [36] silica, [37,38] or low penetrative 2D shields [39] such as graphene [40] and hexagonal boron nitride, etc. [41] Although the stability of 2D perovskite possesses some advantages in comparison with that of 3D counterpart due to the hydrophobic nature of organic ligands, there is an obvious yawning gap to commercial requirements. To date, the protocols were limited to improve the stability of 2D perovskites, such as deposition strategy to reduce crystal defects for optical stability, insulator selection for better hydrophobicity, [42] composite strategy with other monolayer materials, [40,41] supramolecular engineering, and so on. [43] It is known that carbon-fluorine is the strongest bond in organic chemistry. [44] The high polarity of carbon-fluorine directly affects the interfacial properties, chemical activity, dielectric constant, surface tension, and so on. One of the results is the hydrophobic interface, which can prevent the adsorption of water molecules on the surface. Additionally, they can passivate surfaces and serve as physiochemical barriers to reactive infiltrating species. In fact, some fluorinated organic compounds have been reported as surface passivation agent to improve the performances of perovskites. [45][46][47] However, researches about stabilizing optical properties by directly utilizing fluorinated organic-ligand as a 2D-HOIP insulating layer are rare. [48,49] In this work, in order to enhance the stabilities of 2D-HOIP, fluorinated cation (2-(4-fluorophenyl) ethylamine [F-PEA]) was chosen as the organic ligand to replace the phenyl ethylamine (PEA) in (PEA) 2 PbI 4 (PEPI), as the schematic diagram shown In this study, the interface of 2D hybrid organic-inorganic perovskites L 2 PbI 4 (here L stands for phenylethylamine, PEA) is engineered by fluorine substitution in its organic insulator layers, and the stability of the perovskite is investigated. For the ...

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Section: Preparation and Properties Of Pepi And Fpepimentioning

confidence: 99%

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Zhuang

Shi

et al. 2021

Adv Materials Inter

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“…Исследование графеноподобных полупроводниковых кристаллов является одним из актуальных направлений в области современных материалов электронной техники [1][2][3][4][5]. К числу таких полупроводников относится моноселенид галлия (GaSe), состоящий из тетраслоев, внутри которых атомные слои в порядке Se-Ga-Ga-Se связаны ковалентно, в то время как отдельные тетраслои между собой связаны слабыми силами ван-дер-Ваальса.…”

Section: Introductionunclassified

Исследование ван-дер-ваальсовых кристаллов GaSe и GaS-=SUB=-x-=/SUB=-Se-=SUB=-1-x-=/SUB=- методом фотоотражения

Хахулин¹,

Кох²,

Комков³

2022

Физика И Техника Полупроводников

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Photoreflectance spectra of layered undoped GaSe and GaSxSe1-x crystals present Franz — Keldysh oscillations indicating the near-surface built-in electric field, that can participate in the separation of photoinduced charge carriers in ultrahigh-sensitive photodetectors based on these materials. The measured value of the field strength in GaSxSe1-x turned out to be almost 1.5 times less than in GaSe, that may indicate a smaller number of free charge carriers in the solid solution. The broadening parameter of GaSxSe1-x spectral lines is also significantly lower than in the case of GaSe. This is due to the fact that isovalent atoms, being added into the GaSe, fill Ga vacancies, reducing the number of defects and the concentration of intrinsic charge carriers. The high-field modulation mode observed in the photoreflectance spectrum of GaSxSe1-x doped with an Al donor impurity indicates a relatively small thickness of the depletion region due to the presence of a large number of free electrons.

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“…33−36 The understanding of carrier dynamics is essential for laying a foundation for the development of optoelectronic devices. 25,37,38 Compared with individual 2D-TMDs, out-of-plane charge separation adds the degree of freedom of photocarrier dynamics in vertically stacked TMDs heterostructures. [23][24][25][26][27]39,40 Because of the difference of band alignment between different components, the electrons in the conduction band or the holes in the valence band will transfer to another conduction (valence) band with lower energy, and therefore the interlayer excitons can be formed.…”

Section: Introductionmentioning

confidence: 99%

“…39−47 Since the ultrafast time scale (∼50 fs) of charge transfer (CT) in MoS 2 /WS 2 heterostructures has been experimentally revealed, 39 the CT and interlayer exciton dynamics in vdW heterostructures, such as MoS 2 /WS 2 and MoS 2 /MoSe 2 systems, have been extensively investigated with time-resolved optical spectroscopy. 25,32,37,38,40,41 The obtained consensus is that the CT generally takes place with high efficiency and a high rate within a subpicosecond time scale, 38,40,41,48−53 although it stands as a puzzle considering the large mismatch of parallel momentum of electron immigrating between the adjacent layers. 53,54 Accordingly, different CT mechanisms, including the collective motion of excitons, 55 donor−acceptor delocalization, 56 phonon excitation and assistance, 57−59 energy band couplings, 60 interlayer hopping, 61 and adiabatic transfer, 62 have been proposed theoretically.…”

Section: Introductionmentioning

confidence: 99%

“…The understanding of carrier dynamics is essential for laying a foundation for the development of optoelectronic devices. ,, Compared with individual 2D-TMDs, out-of-plane charge separation adds the degree of freedom of photocarrier dynamics in vertically stacked TMDs heterostructures. − ,, Because of the difference of band alignment between different components, the electrons in the conduction band or the holes in the valence band will transfer to another conduction (valence) band with lower energy, and therefore the interlayer excitons can be formed. − Since the ultrafast time scale (∼50 fs) of charge transfer (CT) in MoS 2 /WS 2 heterostructures has been experimentally revealed, the CT and interlayer exciton dynamics in vdW heterostructures, such as MoS 2 /WS 2 and MoS 2 /MoSe 2 systems, have been extensively investigated with time-resolved optical spectroscopy. ,,,,, The obtained consensus is that the CT generally takes place with high efficiency and a high rate within a subpicosecond time scale, ,,,− although it stands as a puzzle considering the large mismatch of parallel momentum of electron immigrating between the adjacent layers. , Accordingly, different CT mechanisms, including the collective motion of excitons, donor–acceptor delocalization, phonon excitation and assistance, − energy band couplings, interlayer hopping, and adiabatic transfer, have been proposed theoretically. The identifications for different excitation species or intermediate states, such as intralayer excitons, interlayer excitons, free electron–hole plasmas, and delocalized states, as well as the corresponding formation and relaxation, are prerequisites for the establishment of a complete photocarrier dynamics scenario.…”

Section: Introductionmentioning

confidence: 99%

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Identifying the Intermediate Free-Carrier Dynamics Across the Charge Separation in Monolayer MoS₂/ReSe₂ Heterostructures

et al. 2021

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Van der Waals heterostructures composed of different two-dimensional films offer a unique platform for engineering and promoting photoelectric performances, which highly demands the understanding of photocarrier dynamics. Herein, large-scale vertically stacked heterostructures with MoS2 and ReSe2 monolayers are fabricated. Correspondingly, the carrier dynamics have been thoroughly investigated using different ultrafast spectroscopies, including Terahertz (THz) emission spectroscopy, time-resolved THz spectroscopy (TRTS), and near-infrared optical pump–probe spectroscopy (OPPS), providing complementary dynamic information for the out-of-plane charge separation and in-plane charge transport at different stages. The initial charge transfer (CT) within the first 170 fs, generating a transient directional current, is directly demonstrated by the THz emissions. Furthermore, the TRTS explicitly unveils an intermediate free-carrier relaxation pathway, featuring a pronounced augmentation of THz photoconductivity compared to the isolated ReSe2 layer, which likely contains the evolution from immigrant hot charged free carriers to bounded interlayer excitons (∼0.7 ps) and the surface defect trapping (∼13 ps). In addition, the OPPS reveals a distinct enhancement in the saturable absorption along with long-lived dynamics (∼365 ps), which originated from the CT and interlayer exciton recombination. Our work provides comprehensive insight into the photocarrier dynamics across the charge separation and will help with the development of optoelectronic devices based on ReSe2–MoS2 heterostructures.

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Modulation of photocarrier relaxation dynamics in two-dimensional semiconductors

Cited by 57 publications

References 110 publications

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Исследование ван-дер-ваальсовых кристаллов GaSe и GaS-=SUB=-x-=/SUB=-Se-=SUB=-1-x-=/SUB=- методом фотоотражения

Identifying the Intermediate Free-Carrier Dynamics Across the Charge Separation in Monolayer MoS₂/ReSe₂ Heterostructures

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Modulation of photocarrier relaxation dynamics in two-dimensional semiconductors

Cited by 57 publications

References 110 publications

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Stability Improvement of 2D Perovskite by Fluorinated‐Insulator

Исследование ван-дер-ваальсовых кристаллов GaSe и GaS-=SUB=-x-=/SUB=-Se-=SUB=-1-x-=/SUB=- методом фотоотражения

Identifying the Intermediate Free-Carrier Dynamics Across the Charge Separation in Monolayer MoS2/ReSe2 Heterostructures

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Identifying the Intermediate Free-Carrier Dynamics Across the Charge Separation in Monolayer MoS₂/ReSe₂ Heterostructures