InSe monolayer: synthesis, structure and ultra-high second-harmonic generation

Zhou, Jiadong; Shi, Jia; Zeng, Qingsheng; Yu, Changlin; Niu, Lin; Liu, Fucai; Yu, Ting; Suenaga, Kazu; Liu, Xinfeng; Lin, Junhao; Liu, Zheng

doi:10.1088/2053-1583/aab390

Cited by 103 publications

(108 citation statements)

References 44 publications

Supporting

Mentioning

106

Contrasting

Order By: Relevance

“…2 with: n sub ≈ 1.45 (fused silica 48 ); n GaSe (ω) = n GaSe (2ω) = 2.8, 8 and n InSe (ω) = 2.86 and n InSe (2ω) = 3. 35,13 . We set F = 1, rather than the value of approximately 20 indicated in Ref.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Second-harmonic generation in single-layer monochalcogenides: A response from first-principles real-time simulations

Attaccalite

Palummo

Cannuccia

et al. 2019

Phys. Rev. Materials

View full text Add to dashboard Cite

Second Harmonic Generation (SHG) of single-layer monochalcogenides, such as GaSe and InSe, has been recently reported [2D Mater. 5 (2018) 025019; J. Am. Chem. Soc. 2015, 137, 79947997] to be extremely strong with respect to bulk and multilayer forms. To clarify the origin of this strong SHG signal, we perform first-principles real-time simulations of linear and non-linear optical properties of these two-dimensional semiconducting materials. The simulations, based on ab-initio many-body theory, accurately treat the electron-hole correlation and capture excitonic effects that are deemed important to correctly predict the optical properties of such systems. We find indeed that, as observed for other 2D systems, the SHG intensity is redistributed at excitonic resonances. The obtained theoretical SHG intensity is an order of magnitude smaller than that reported at the experimental level. This result is in substantial agreement with previously published simulations which neglected the electron-hole correlation, demonstrating that many-body interactions are not at the origin of the strong SHG measured. We then show that the experimental data can be reconciled with the theoretical prediction when a single layer model, rather than a bulk one, is used to extract the SHG coefficient from the experimental data.

show abstract

Section: Discussionmentioning

confidence: 99%

“…IV) that many-body effects do not account for the difference between theoretical predictions 18,19 and experimental estimates. 8,13 We turn then the attention to the experimental results and argue that the extremely large SHG coefficient is an artifact of the model assumed to extract the estimate from the experimental data.…”

Section: Introductionmentioning

confidence: 99%

Second-harmonic generation in single-layer monochalcogenides: A response from first-principles real-time simulations

Attaccalite

Palummo

Cannuccia

et al. 2019

Phys. Rev. Materials

View full text Add to dashboard Cite

show abstract

“…As exfoliation produces crystalline flakes randomly, the geometry and thickness cannot be controlled well and it is the largest barrier toward the development of practical applications. Although great strides have been made in the synthesis of BP and InSe thin films using chemical vapor deposition (CVD) or other methods, these 2D crystals' electronic properties are lacking compared to their exfoliated counterparts, due to their reactivity with ambient conditions. Thus far, the demonstration of the quantum Hall effect in a synthesized 2D semiconductor is crucially missing and impedes high‐performance application development.…”

Section: Introductionmentioning

confidence: 99%

Realization of Quantum Hall Effect in Chemically Synthesized InSe

Yuan

Yin

et al. 2019

Adv Funct Materials

View full text Add to dashboard Cite

Recently, 2D electron gases have been observed in atomically thin semiconducting crystals, enabling the observation of rich physical phenomena at the quantum level within the ultimate thickness limit. However, the observation of 2D electron gases and subsequent quantum Hall effect require exceptionally high crystalline quality, rendering mechanical exfoliation as the only method to produce high-quality 2D semiconductors of black phosphorus and indium selenide (InSe), which hinder large-scale device applications. Here, the controlled one-step synthesis of high-quality 2D InSe thin films via chemical vapor transport method is reported. The carrier Hall mobility of hexagonal boron nitride (hBN) encapsulated InSe flakes can be up to 5000 cm 2 V −1 s −1 at 1.5 K, enabling to observe the quantum Hall effect in a synthesized van der Waals semiconductor. The existence of the quantum Hall effect in directly synthesized 2D semiconductors indicates a high quality of the chemically synthesized 2D semiconductors, which hold promise in quantum devices and applications with high mobility.sufficiently large, i.e., ω c τ >> 1. However, the experimental magnetic field strength is typically limited, and the quantization condition subsequently requires long scattering time τ, or equivalently a high carrier mobility µ = eτ/m. Due to the high mobility requirement, the quantum Hall effect has only been observed in a handful of materials, most notably in epitaxially grown quantum wells. Apart from semimetal graphene, the quantum Hall effect recently has been observed in van der Waals (vdWs) semiconducting crystals which confine carriers within one to a few crystalline layers, e.g., 2D semiconductors of black phosphorus (BP) and InSe. [3][4][5] While the thickness of these vdWs semiconductors can technically be controlled within one layer, the production of such high-quality 2D semiconductors has been limited to mechanically exfoliated samples. As exfoliation produces crystalline flakes randomly, the geometry and thickness cannot be controlled well and it is the largest barrier toward the development of practical applications. Although great strides have been made in the synthesis of BP and InSe thin films using chemical vapor deposition (CVD) or other methods, [6][7][8][9][10][11] these 2D crystals' electronic properties are lacking compared to their exfoliated counterparts, due to their reactivity with ambient conditions. Thus far, the demonstration of the quantum Hall effect in a synthesized 2D semiconductor 2D Semiconductors

show abstract

“…In addition, due to difficulties in exfoliation and lack of thickness‐controlled synthesis methods, previous reports were unable to study layered‐dependent properties of the 2D layered material, and to our knowledge, characterization or properties of GaS less than 3 layers (3L) are missing. Furthermore, although other members in the group‐III monochalcogenide‐layered materials with similar structures (GaSe, GaTe, InSe) have attracted intense attention as they have demonstrated superior optical properties, including ultra‐high second‐harmonic generation, giant piezo‐phototronic response, polarization‐dependent absorption, etc., properties of GaS with wide potential remain unexplored as a result of unanswered stability issues and unsatisfying samples. Recently, our group has developed a simple and atmospheric pressure chemical vapor deposition (CVD) method for the growth of 2D GaS crystals, which paved way for further study of the material's stability and layer‐dependent properties.…”

mentioning

confidence: 99%

Controlling Defects in Continuous 2D GaS Films for High‐Performance Wavelength‐Tunable UV‐Discriminating Photodetectors

Yang

Chen

et al. 2020

Advanced Materials

View full text Add to dashboard Cite

A chemical vapor deposition method is developed for thickness‐controlled (one to four layers), uniform, and continuous films of both defective gallium(II) sulfide (GaS): GaS0.87 and stoichiometric GaS. The unique degradation mechanism of GaS0.87 with X‐ray photoelectron spectroscopy and annular dark‐field scanning transmission electron microscopy is studied, and it is found that the poor stability and weak optical signal from GaS are strongly related to photo‐induced oxidation at defects. An enhanced stability of the stoichiometric GaS is demonstrated under laser and strong UV light, and by controlling defects in GaS, the photoresponse range can be changed from vis‐to‐UV to UV‐discriminating. The stoichiometric GaS is suitable for large‐scale, UV‐sensitive, high‐performance photodetector arrays for information encoding under large vis‐light noise, with short response time (<66 ms), excellent UV photoresponsivity (4.7 A W–1 for trilayer GaS), and 26‐times increase of signal‐to‐noise ratio compared with small‐bandgap 2D semiconductors. By comprehensive characterizations from atomic‐scale structures to large‐scale device performances in 2D semiconductors, the study provides insights into the role of defects, the importance of neglected material‐quality control, and how to enhance device performance, and both layer‐controlled defective GaS0.87 and stoichiometric GaS prove to be promising platforms for study of novel phenomena and new applications.

show abstract

InSe monolayer: synthesis, structure and ultra-high second-harmonic generation

Cited by 103 publications

References 44 publications

Second-harmonic generation in single-layer monochalcogenides: A response from first-principles real-time simulations

Second-harmonic generation in single-layer monochalcogenides: A response from first-principles real-time simulations

Realization of Quantum Hall Effect in Chemically Synthesized InSe

Controlling Defects in Continuous 2D GaS Films for High‐Performance Wavelength‐Tunable UV‐Discriminating Photodetectors

Contact Info

Product

Resources

About