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1. MXene saturable absorber enabled hybrid mode-locking technology: a new routine of advancing femtosecond fiber lasers performance

Author

Ma Chunyang, Huang Weichun, Wang Yunzheng, Adams Jordan, Wang Zhenhong, Liu Jun, Song Yufeng, Ge Yanqi, Guo Zhongyi, Hu Lanping, and Zhang Han

Subjects
mxene, v2ctx, layered materials, nonlinear photonics, ultrafast fiber lasers, Physics, QC1-999
Abstract

MXene is a promising two-dimensional (2D) material that is widely used in electro-photonic devices due to its unique properties. In this contribution, V2CTx, a novel MXene, was employed as a saturable absorber (SA) for hybrid passively mode-locked fiber lasers. An ultra-stable and self-starting mode-locked laser system with low threshold can be achieved using V2CTx nanosheets and nonlinear polarization evolution (NPE). Signal to noise ratio increased 13 dB compared with using only NPE SA. A 72 fs pulse duration is easily achieved from this hybrid mode-locked fiber laser system. To the best of our knowledge, this is the shortest pulse duration generated from the Yb-doped mode-locked fiber lasers using a hybrid or 2D SAs. This study proves that MXene V2CTx nanosheets can be developed as suitable SAs and served as potential advanced ultrafast photonic devices in the future.

Published
2020
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2. Phosphorene-assisted silicon photonic modulator with fast response time

Author

Cheng Zhao, Cao Rui, Guo Jia, Yao Yuhan, Wei Kangkang, Gao Shan, Wang Yunzheng, Dong Jianji, and Zhang Han

Subjects
phosphorene, modulators, all-optical devices, integrated optics devices, Physics, QC1-999
Abstract

All-optical modulators avoid the conversion from external electronic signals to optical signals and thus have the potential to achieve an energy-efficient high-speed photonic system. Phosphorene recently debuted as an attractive material that exhibits outstanding high electron mobility, strong light-matter interaction and modifiable bandgap, making it ideal for all-optical modulators. In this paper, by incorporating a phosphorene and silicon-based micro-ring resonator (MRR), we first propose and experimentally demonstrate a unique phosphorene-integrated all-optical modulator in telecommunications. By utilizing a phosphorene thin film with an average thickness of 22 nm as the absorption material, the rise time of only 479 ns and decay time of 113 ns are achieved, which is the fastest reported response time in the family of phosphorene modulators. The corresponding 3 dB bandwidth is larger than 2.5 MHz, and it exhibits a low-loss performance benefited from its finite bandgap. The proposed phosphorene/MRR hybrid modulator may have potential in the applications of all-optical interconnections.

Published
2020
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3. Quantum confinement-induced enhanced nonlinearity and carrier lifetime modulation in two-dimensional tin sulfide

Author

Zhang Feng, Xu Ning, Zhao Jinlai, Wang Yunzheng, Jiang Xiantao, Zhang Ye, Huang Weichun, Hu Lanping, Tang Yanfeng, Xu Shixiang, and Zhang Han

Subjects
third-order nonlinearity, quantum-confinement, carrier dynamics, two-dimensional, tin sulfide (sns), Physics, QC1-999
Abstract

Two-dimensional tin sulfide (SnS), as a black phosphorus-analogue binary semiconductor, has received considerable attention in photonics and optoelectronics. Herein, the third-order nonlinearity susceptibility Im χ3 is enhanced from −(6.88 ± 0.10) × 10−14 esu to −(15.90 ± 0.27) × 10−14 esu by the size-related quantum confinement in layered SnS nanosheets. Due to the energy level alignment, a phonon-bottleneck effect is observed, which leads to a prolonged carrier lifetime. These results provide a platform for actively tuning the linear and nonlinear optics, and pave the way for designing SnS-based tunable and anisotropic optoelectronic devices.

Published
2020
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6. Multi-level Optical Switching by Amorphization in Single- and Multi- Phase Change Material Structures

Author

Wredh, Simon, Wang, Yunzheng, Yang, Joel K. W., and Simpson, Robert E.

Subjects
Physics - Optics, Condensed Matter - Materials Science
Abstract

The optical properties of phase-change materials (PCM) can be tuned to multiple levels by controlling the transition between their amorphous and crystalline phases. In multi-material PCM structures, the number of discrete reflectance levels can be increased according to the number of PCM layers. However, the effect of increasing number of layers on quenching and reversibility has not been thoroughly studied. In this work, the phase-change physics and thermal conditions required for reversible switching of single and multi-material PCM switches are discussed based on thermo-optical phase-change models and laser switching experiments. By using nanosecond laser pulses, 16 different reflectance levels in Ge2Sb2Te5 are demonstrated via amorphization. Furthermore, a multi-material switch based on Ge2Sb2Te5 and GeTe with four discrete reflectance levels is experimentally proven with a reversible multi-level response. The results and design principles presented herein will impact active photonics applications that rely on dynamic multi-level operation, such as optical computing, beam steering, and next-generation display technologies., Comment: 25 pages, 8 figures

Published
2023

8. Low Thermal Conductivity Phase Change Memory Superlattices

Author

Ning, Jing, Zhou, Xilin, Wang, Yunzheng, Yagi, Takashi, Kalikka, Janne, Teo, Siew Lang, Song, Zhitang, Bosman, Michel, and Simpson, Robert E.

Subjects
Condensed Matter - Materials Science
Abstract

Phase change memory devices are typically reset by melt-quenching a material to radically lower its electrical conductance. The high power and concomitantly high current density required to reset phase change materials is the major issue that limits the access times of 3D phase change memory architectures. Phase change superlattices were developed to lower the reset energy by confining the phase transition to the interface between two different phase change materials. However, the high thermal conductivity of the superlattices means that heat is poorly confined within the phase change material, and most of the thermal energy is wasted to the surrounding materials. Here, we identified Ti as a useful dopant for substantially lowering the thermal conductivity of Sb2Te3-GeTe superlattices whilst also stabilising the layered structure from unwanted disordering. We demonstrate via laser heating that lowering the thermal conductivity by doping the Sb2Te3 layers with Ti halves the switching energy compared to superlattices that only use interfacial phase change transitions and strain engineering. The thermally optimized superlattice has (0 0 l) crystallographic orientation yet a thermal conductivity of just 0.25 W/m.K in the "on" (set) state. Prototype phase change memory devices that incorporate this Ti-doped superlattice switch faster and and at a substantially lower voltage than the undoped superlattice. During switching the Ti-doped Sb2Te3 layers remain stable within the superlattice and only the Ge atoms are active and undergo interfacial phase transitions. In conclusion, we show the potential of thermally optimised Sb2Te3-GeTe superlattices for a new generation of energy-efficient electrical and optical phase change memory., Comment: 4 Figures, 7 Supplementary Figures, 27 pages including a supplement

Published
2022

9. Tunable wavefront control in the visible spectrum using low-loss chalcogenide phase change metasurfaces

Author

Moitra, Parikshit, Wang, Yunzheng, Liang, Xinan, Lu, Li, Poh, Alyssa, Mass, Tobias W. W., Simpson, Robert E., Kuznetsov, Arseniy I., and Paniagua-Dominguez, Ramon

Subjects
Physics - Optics
Abstract

All-dielectric metasurfaces provide unique solutions for advanced wavefront manipulation of light with complete control of amplitude and phase at sub-wavelength scales. One limitation, however, for most of these devices is the lack of any post-fabrication tunability of their response. To break this limit, a promising approach is employing phase-change-materials (PCM), which provide a fast, low energy and non-volatile means to endow metasurfaces with a switching mechanism. In this regard, great advancements have been done in the mid infrared and near infrared spectrum using different chalcogenides. In the visible spectral range, however, very few devices have demonstrated full phase manipulation, high efficiencies, and reversible switching. Here, we experimentally demonstrate a tunable all-dielectric Huygens metasurface made of antimony sulfide (Sb2S3) PCM, a low loss and high-index material in the visible spectral range with a large contrast (nearly 0.5) between its amorphous and crystalline states. We show close to 2pi phase modulation with high associated transmittance and use it to create switchable beam steering and holographic display devices. These novel chalcogenide PCM metasurfaces have the potential to emerge as a platform for next generation spatial light modulators and to impact application areas such as tunable and adaptive flat optics, LiDAR, and many more.

Published
2022

10. Low energy switching of phase change materials using a 2D thermal boundary layer

Author

Ning, Jing, Wang, Yunzheng, Teo, Ting Yu, Huang, Chung-Che, Zeimpekis, Ioannis, Morgan, Katrina, Teo, Siew Lang, Hewak, Daniel W., Bosman, Michel, and Simpson, Robert E.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

The switchable optical and electrical properties of phase change materials (PCMs) are finding new applications beyond data storage in reconfigurable photonic devices. However, high power heat pulses are needed to melt-quench the material from crystalline to amorphous. This is especially true in silicon photonics, where the high thermal conductivity of the waveguide material makes heating the PCM energy inefficient. Here, we improve the energy efficiency of the laser-induced phase transitions by inserting a layer of two-dimensional (2D) material, either MoS2 or WS2, between the silica or silicon and the PCM. The 2D material reduces the required laser power by at least 40% during the amorphization (RESET) process, depending on the substrate. Thermal simulations confirm that both MoS2 and WS2 2D layers act as a thermal barrier, which efficiently confines energy within the PCM layer. Remarkably, the thermal insulation effect of the 2D layer is equivalent to a ~100 nm layer of SiO2. The high thermal boundary resistance induced by the van der Waals (vdW)-bonded layers limits the thermal diffusion through the layer interfaces. Hence, 2D materials with stable vdW interfaces can be used to improve the thermal efficiency of PCM-tuned Si photonic devices. Furthermore, our waveguide simulations show that the 2D layer does not affect the propagating mode in the Si waveguide, thus this simple additional thin film produces a substantial energy efficiency improvement without degrading the optical performance of the waveguide. Our findings pave the way for energy-efficient laser-induced structural phase transitions in PCM-based reconfigurable photonic devices., Comment: 34 pages, 12 figures

Published
2022

11. Tunable Mie Resonances in the Visible Spectrum

Author

Lu, Li, Dong, Zhaogang, Tijiptoharsono, Febiana, Ng, Ray Jia Hong, Wang, Hongtao, Rezaei, Soroosh Daqiqeh, Wang, Yunzheng, Leong, Hai Sheng, Yang, Joel K. W., and Simpson, Robert E.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Dielectric optical nanoantennas play an important role in color displays, metasurface holograms, and wavefront shaping applications. They usually exploit Mie resonances as supported on nanostructures with high refractive index, such as Si and TiO2. However, these resonances normally cannot be tuned. Although phase change materials, such as the germanium-antimony-tellurium alloys and post transition metal oxides, such as ITO, have been used to tune optical antennas in the near infrared spectrum, tunable dielectric antennae in the visible spectrum remain to be demonstrated. In this paper, we designed and experimentally demonstrated tunable dielectric nanoantenna arrays with Mie resonances in the visible spectrum, exploiting phase transitions in wide-bandgap Sb2S3 nano-resonators. In the amorphous state, Mie resonances in these Sb2S3 nanostructures give rise to a strong structural color in reflection mode. Thermal annealing induced crystallization and laser induced amorphization of the Sb2S3 resonators allow the color to be tuned reversibly. We believe these tunable Sb2S3 nanoantennae arrays will enable a wide variety of tunable nanophotonic applications, such as high-resolution color displays, holographic displays, and miniature LiDAR systems., Comment: 36 pages, 5 figures in main text, 9 figures in supporting information

Published
2021

12. A scheme for simulating multi-level phase change photonics materials

Author

Wang, Yunzheng, Ning, Jing, Lu, Li, Bosman, Michel, and Simpson, Robert E.

Subjects
Physics - Optics, Condensed Matter - Materials Science, Nonlinear Sciences - Cellular Automata and Lattice Gases
Abstract

Chalcogenide phase change materials (PCMs) have been extensively applied in data storage, and they are now being proposed for high resolution displays, holographic displays, reprogrammable photonics, and all-optical neural networks. These wide-ranging applications all exploit the radical property contrast between the PCMs different structural phases, extremely fast switching speed, long-term stability, and low energy consumption. Designing PCM photonic devices requires an accurate model to predict the response of the device during phase transitions. Here, we describe an approach that accurately predicts the microstructure and optical response of phase change materials during laser induced heating. The framework couples the Gillespie Cellular Automata approach for modelling phase transitions with effective medium theory and Fresnel equations. The accuracy of the approach is verified by comparing the PCM optical response and microstructure evolution with the results of nanosecond laser switching experiments. We anticipate that this approach to simulating the switching response of PCMs will become an important component for designing and simulating programmable photonics devices. The method is particularly important for predicting the multi-level optical response of PCMs, which is important for all-optical neural networks and PCM-programmable perceptrons., Comment: 26 pages, 6 figures

Published
2021
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22. Advancements in photophysics research and applications of phosphorene semiconductors.

Author

HUANG Weichun, ZI You, WANG Mengke, HU Lanping, WANG Yunzheng, XIE Zhongjian, QIU Meng, and ZHANG Han

Abstract

Compared with other two-dimensional materials, two-dimensional black phosphorus (BP) has attracted extensive attention across various fields including transistors, photonics, optoelectronics, sensors, batteries and catalysis in recent years owing to its high carrier mobility, wide adjustable band gap, and in-plane anisotropy. However, the instability of black phosphorus in natural environmental conditions and the chanllenges in the fabrication of large-area, high-quality semiconducting black phosphorus nanostructures seriously have hampered its rapid development in the field of nanodevices, catalysis and biophotonics. In this work, we summarize the controlled fabrication and optical properties of highly stable BP nanostructures in recent years. The research advances in photoresponse applications, including photodetectors, nonlinear and linear photonics, photocatalysis and biophotonics, are highlighted. Additionally, the challenges and opportunities of BP nanostructures in future optoelectronic devices, photocatalysis and biophotonics are discussed. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Optimization of a Ge 2 Sb 2 Te 5 -Based Electrically Tunable Phase-Change Thermal Emitter for Dynamic Thermal Camouflage.

Author

Xiong, Yufeng, Zhang, Guoxu, Tian, Yaolan, Wang, Jun-Lei, Wang, Yunzheng, Zhuo, Zhuang, and Zhao, Xian

Subjects
PHASE change materials, REVERSIBLE phase transitions, INFRARED radiation, HEAT radiation & absorption
Abstract

Controlling infrared thermal radiations can significantly improve the environmental adaptability of targets and has attracted increasing attention in the field of thermal camouflage. Thermal emitters based on Ge2Sb2Te5 (GST) can flexibly change their radiation energy by controlling the reversible phase transition of GST, which possesses fast switching speed and low power consumption. However, the feasibility of the dynamic regulation of GST emitters lacks experimental and simulation verification. In this paper, we propose an electrically tunable thermal emitter consisting of a metal–insulator–metal plasmonic metasurface based on GST. Both optical and thermal simulations are conducted to optimize the structural parameters of the GST emitter. The results indicate that this emitter possesses large emissivity tunability, wide incident angle, polarization insensitivity, phase-transition feasibility, and dynamic thermal camouflage capability. Therefore, this work proposes a reliable optimization method to design viable GST-based thermal emitters. Moreover, it provides theoretical support for the practical application of phase-change materials in dynamic infrared thermal camouflage technology. [ABSTRACT FROM AUTHOR]

Published
2024
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26. Multi‐Level Optical Switching by Amorphization in Single‐ and Multi‐Phase Change Material Structures.

Author

Wredh, Simon, Wang, Yunzheng, Yang, Joel K.W., and Simpson, Robert E.

Subjects
*OPTICAL computing, *AMORPHIZATION, *OPTICAL properties, *PHASE change materials, *BEAM steering, *OPTICAL switching, *LASER pulses
Abstract

The optical properties of phase‐change materials (PCMs) can be tuned to multiple levels by controlling the transition between their amorphous and crystalline phases. In multi‐material PCM structures, the number of discrete reflectance levels can be increased according to the number of PCM layers. However, the effect of increasing the number of layers on quenching and reversibility has not been thoroughly studied. In this work, the phase‐change physics and thermal conditions required for reversible switching of single and multi‐material PCM switches are discussed based on thermo‐optical phase‐change models and laser switching experiments. By using nanosecond laser pulses, 16 different reflectance levels in Ge2Sb2Te5 are demonstrated via amorphization. Furthermore, a multi‐material switch based on Ge2Sb2Te5 and GeTe with four discrete reflectance levels is experimentally proven with a reversible multi‐level response. The results and design principles presented herein will impact active photonics applications that rely on dynamic multi‐level operation, such as optical computing, beam steering, and next‐generation display technologies. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Antimony trisulfide programmable photonics

Author

Simpson, Robert E., primary, Teo, Tingyu, additional, Poh, Alyssa, additional, Lu, Li, additional, Wang, Yunzheng, additional, Ning, Jing, additional, Paniagua Dominguez, Ramon J., additional, Dong, Zhao Gang, additional, Kuznetsov, Arseniy, additional, and Yang, Joel, additional

Published
2022
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41. Activity Enhancement of Ferrierite in Dimethyl Ether Carbonylation Reactions through Recrystallization with Sodium Oleate.

Author

Lv, Jiangang, Chen, Long, Chen, Chong, Wang, Yunzheng, Wang, Di, Sun, Huaqian, and Yang, Weimin

Subjects
CARBONYLATION, FERRIERITE, RECRYSTALLIZATION (Metallurgy), METHYL ether, FOURIER transform infrared spectroscopy, ALKALI metals, SODIUM
Abstract

Methyl acetate (MA) has a wide range of applications as an important industrial chemical. Traditional MOR zeolite for carbonylation of DME to MA accumulated carbon easily because of a 12-membered ring (12 MR) channel. In this work, we innovatively developed the method of recrystallization ferrierite (FER) zeolite using special chelating ligand sodium oleate which can affect ions other than alkali metals. The characterization results of N2 adsorption, transmission electron microscopy (TEM), and Fourier transform infrared spectroscopy (FT-IR) show that hydrothermal recrystallization of ferrierite using sodium oleate resulted in a higher Si/Al ratio, a bigger specific surface area and a larger number of Brønsted acid sites in the eight MR channels, which was more efficient in the reaction of carbonylation of dimethyl ether than ordinary alkali treatment. [ABSTRACT FROM AUTHOR]

Published
2023
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46. Two-Dimensional Cationic Aluminoborate as a New Paradigm for Highly Selective and Efficient Cr(VI) Capture from Aqueous Solution

Author

Wang, Shuang, Bai, Pu, Cichocka, Magdalena Ola, Cho, Jung, Willhammar, Tom, Wang, Yunzheng, Yan, Wenfu, Zou, Xiaodong, Yu, Jihong, Wang, Shuang, Bai, Pu, Cichocka, Magdalena Ola, Cho, Jung, Willhammar, Tom, Wang, Yunzheng, Yan, Wenfu, Zou, Xiaodong, and Yu, Jihong

Abstract

Water pollutants existing in their oxyanion forms have high solubility and environmental mobility. To capture these anionic pollutants, cost-effective inorganic materials with cationic frameworks and outstanding removal performance are ideal adsorbents. Herein, we report that two-dimensional (2D) cationic aluminoborate BAC(10) sets a new paradigm for highly selective and efficient capture of Cr(VI) and other oxyanions from aqueous solution. The structure of Cr(VI)-exchanged BAC(10) sample (Cr(VI)@BAC(10), H0.22·Al2BO4.3·(HCrO4)0.22·2.64H2O) has been successfully solved by continuous rotation electron diffraction. The crystallographic data show that the 2D cationic layer of BAC(10) is built by AlO6 octahedra, BO4 tetrahedra, and BO3 triangles. Partial chromate ions exchanged with Cl– ions are located within the interlayer region, which are chemically bonded to the aluminoborate layer. BAC(10) shows faster adsorption kinetics compared to the commercial anion exchange resin (AER) and layered double hydroxides (LDHs), a higher maximum adsorption capacity of 139.1 mg/g than that of AER (62.77 mg/g), LDHs (81.43 mg/g), and a vast majority of cationic MOFs, and a much broader working pH range (2–10.5) than LDHs. Moreover, BAC(10) also shows excellent Cr(VI) oxyanion removal performance for a solution with a low concentration (1–10 mg/L), and the residual concentration can be reduced to below 0.05 mg/L of the WHO drinking water criterion. These superior properties indicate that BAC(10) is a promising material for remediation of Cr(VI) and other harmful oxyanions from wastewater.

Published
2022
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47. Reconfigurable InP waveguide components using the Sb2S3 phase change material

Author

Lu, Li, Reniers, Sander, Wang, Yunzheng, Jiao, Yuqing, Simpson, Robert, Lu, Li, Reniers, Sander, Wang, Yunzheng, Jiao, Yuqing, and Simpson, Robert

Abstract

Reconfigurable waveguide components are promising building blocks for photonic neural networks and as an optical analogue to field-programmable gate arrays. By changing the effective index of the waveguide, reconfigurable waveguide components can achieve on-chip light routing and modulation. In this paper, we design and demonstrate an Sb2S3-reconfigurable InP membrane Mach–Zehnder interferometer (MZI) on a silicon substrate. Sb2S3, which has tunable refractive index and low absorption in the near-infrared spectrum, was patterned on the InP waveguide MZIs to make an optical switch in the telecoms conventional-band. By laser induced crystallisation of the Sb2S3, it was possible to control interference in the MZI and achieve 18 dB on/off switching at 1540 nm. Laser reamorphisation and reversible switching of the Sb2S3 layer resulted in damage to the waveguide structure. However, simulations show that transition metal di-chalcogenide two-dimensional crystal layers can act as efficient thermal barriers that prevent thermal damage to the waveguide during laser amorphisation. Therefore, combining Sb2S3 with InP waveguides seems to be a feasible approach to achieve low-loss reprogrammable waveguide components for on-chip photonics routing and neural networks.

Published
2022

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