Van der Waals Integrated LiNbO<sub>3</sub>/WS<sub>2</sub> for High‐Performance UV–Vis–NIR Photodetection

Liang, Xiaoyan; Guan, Heyuan; Luo, Kaiwen; He, Zhigang; Liang, Aijie; Zhang, Weina; Lin, Qijing; Yang, Zuoxin; Zhang, H.; Chen, Xu; Xie, Hongyun; Liu, Fengli; Ma, Fengkai; Yang, Tiefeng; Lu, Huihui

doi:10.1002/lpor.202300286

Cited by 9 publications

(1 citation statement)

References 82 publications

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“…At the same time, Si and its oxide SiO 2 both have good light absorption ability, which makes their performance in the bandwidth of the visible and near-infrared regions tend toward perfection [28]. On the other hand, Surface Plasmon Resonance (SPR) due to shape structure has a significant impact on the absorber's performance [29][30][31][32][33]. In previous studies, the emergence of equal-width arranged structures of discs of different sizes [34], stacked structures of complex trapezoidal shapes [35], and regularly arranged structures of elliptic and disc arrays [36] showed that highly absorbing physical properties are the result of both SPR and multiple resonance modes [37].…”

Section: Introductionmentioning

confidence: 99%

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Chen,

Yi,

Song

et al. 2024

Photonics

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The main development direction for current solar technology is to improve absorption efficiency and stability. To bridge this gap, we design in this paper a structure consisting of two multilayer disc stacks of different radii, one topped by a TiO2 disc and the other by a cascade disc stack composed of SiO2-Ti, for use in thermal emitters and solar absorbers. The innovation of our work is the exploitation of multiple Fabry–Perot resonances in SiO2-Ti cascade optical cavities to develop absorber bandwidths while investigating it in the field of thermal emission and many aspects affecting the efficiency of the absorber. The finite difference time domain method (FDTD) results show absorption averages as high as 96.68% with an absorption bandwidth of 2445 nm (A > 90%) at 280 nm–3000 nm solar incidence and even higher weighted averages as high as 98.48% at 1.5 solar air mass (AM) illumination. In order to investigate the physical mechanisms of our designed absorber in a high absorption state, we analyzed the electric field distributions of its four absorption peaks and concluded that its high absorption is mainly caused by the coupling of multiple Fabry–Perot resonance modes in the cascaded optical cavity. While considering this high efficiency, we also investigated the effect of complex environments such as extreme high temperatures and changes in the angle of incidence of the absorber, and the results show that the thermal radiation efficiency of the emitter is 96.79% at an operating temperature of 1700 K, which is higher than its thermal radiation efficiency of 96.38% at an operating temperature of 1500 K, which is a perfect result. On the other hand, we conclude that the designed structure is independent of polarization, while the absorber still has 88.22% absorption at incidence angles of up to 60°, both in transverse electric (TE) and transverse magnetic (TM) modes. The results of this study can help improve the performance of future solar absorbers and expand their application areas.

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Section: Introductionmentioning

confidence: 99%

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Chen,

Yi,

Song

et al. 2024

Photonics

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Broadband, Plasmon‐Modified SnSe₂ Photodetector Based on LNOI Thin‐Film Platform

Liu,

Sun,

et al. 2024

Adv Materials Inter

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Lithium niobate on insulator (LNOI) is widely recognized as an essential optoelectronic integration platform due to its unique ferroelectric properties and photorefractive effect. However, the wide bandgap and weak absorption of lithium niobate limit its further application in integrated photodetection field. To address this issue, encapsulating silver nanoparticles within the LNOI structure are proposed to manipulate the light field distribution of modified lithium niobate through the localized surface plasmon resonance (LSPR) effect and utilize the modified lithium niobate thin film as a functional substrate to tailor the optoelectronic properties of surface SnSe2 nanosheets, significantly enhancing their photodetection capabilities. The photocurrent of the SnSe2 photodetector based on LNOI with embedded Ag nanoparticles is enhanced by up to 1912 times compared to that on the original LNOI under the same conditions, which represents the highest reported plasmonic‐induced photodetection enhancement. This work deepens the basic research on plasmonic‐modified 2D materials and ferroelectric materials, which promotes the development of on‐chip photodetectors and the realization of fully functional photonic circuits that integrate all essential components on a single chip.

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Light‐Induced Ferroelectric Modulation of p‐n Homojunctions in Monolayer MoS₂

Ramirez,

Fernandez‐Tejedor,

Gallego

et al. 2024

Advanced Optical Materials

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The association of 2D materials and ferroelectrics offers a promising approach to tune the optoelectronic properties of atomically thin Transition Metal Dichalcogenides (TMDs). In this work, the combined effect of ferroelectricity and light on the optoelectronic properties of monolayer (1L)‐MoS2 deposited on periodically poled lithium niobate crystals is explored. Using scanning micro‐photoluminescence, the effect of excitation intensity, scanning direction, and domain walls on the 1L‐MoS2 photoluminescence properties is analyzed, offering insights into charge modulation of MoS2. The findings unveil a photoinduced charging process dependent on the ferroelectric domain orientation, in which light induces charge generation and transfer at the monolayer‐substrate interface. This highlights the substantial role of light excitation in ferroelectrically‐driven electrostatic doping in MoS2. Additionally, the work provides insights into the effect of the strong, nanometrically confined electric fields on LiNbO3 domain wall surfaces, demonstrating precise control over charge carriers in MoS2, and enabling the creation of deterministic p‐n homojunctions with exceptional precision. The results suggest prospects for novel optoelectronic and photonic application involving monolayer TMDs by combining light‐matter interaction processes and the surface selectivity provided by ferroelectric domain structures.

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Van der Waals Integrated LiNbO₃/WS₂ for High‐Performance UV–Vis–NIR Photodetection

Cited by 9 publications

References 82 publications

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Broadband, Plasmon‐Modified SnSe₂ Photodetector Based on LNOI Thin‐Film Platform

Light‐Induced Ferroelectric Modulation of p‐n Homojunctions in Monolayer MoS₂

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Van der Waals Integrated LiNbO3/WS2 for High‐Performance UV–Vis–NIR Photodetection

Cited by 9 publications

References 82 publications

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Simulation and Analysis of a Near-Perfect Solar Absorber Based on SiO2-Ti Cascade Optical Cavity

Broadband, Plasmon‐Modified SnSe2 Photodetector Based on LNOI Thin‐Film Platform

Light‐Induced Ferroelectric Modulation of p‐n Homojunctions in Monolayer MoS2

Contact Info

Product

Resources

About

Van der Waals Integrated LiNbO₃/WS₂ for High‐Performance UV–Vis–NIR Photodetection

Broadband, Plasmon‐Modified SnSe₂ Photodetector Based on LNOI Thin‐Film Platform

Light‐Induced Ferroelectric Modulation of p‐n Homojunctions in Monolayer MoS₂