23 results on '"Mengyu Hong"'
Search Results
2. In situ study of wet chemical etching of ZnO nanowires with different diameters and polar surfaces by LCTEM
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Jiamin Tian, Mei Sun, Mengyu Hong, Bocheng Yu, Menglan Li, Yu Geng, Shuo Li, Yue Zhang, Zhihong Li, and Qing Chen
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General Materials Science - Abstract
Etching behaviors are affected by different polarities at the two ends of ZnO nanowires in the 〈0001〉 axial direction.
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- 2023
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3. Tea Polyphenols as Prospective Natural Attenuators of Brain Aging
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Mengyu Hong, Jing Yu, Xuanpeng Wang, Yanan Liu, Shengnan Zhan, Zufang Wu, and Xin Zhang
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Aging ,Nutrition and Dietetics ,Tea ,Brain ,Humans ,Polyphenols ,Prospective Studies ,Food Science - Abstract
No organism can avoid the process of aging, which is often accompanied by chronic disease. The process of biological aging is driven by a series of interrelated mechanisms through different signal pathways, including oxidative stress, inflammatory states, autophagy and others. In addition, the intestinal microbiota play a key role in regulating oxidative stress of microglia, maintaining homeostasis of microglia and alleviating age-related diseases. Tea polyphenols can effectively regulate the composition of the intestinal microbiota. In recent years, the potential anti-aging benefits of tea polyphenols have attracted increasing attention because they can inhibit neuroinflammation and prevent degenerative effects in the brain. The interaction between human neurological function and the gut microbiota suggests that intervention with tea polyphenols is a possible way to alleviate brain-aging. Studies have been undertaken into the possible mechanisms underpinning the preventative effect of tea polyphenols on brain-aging mediated by the intestinal microbiota. Tea polyphenols may be regarded as potential neuroprotective substances which can act with high efficiency and low toxicity.
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- 2022
4. Oolong tea polyphenols affect the inflammatory response to improve cognitive function by regulating gut microbiota
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Zheyi Song, Xin Zhang, Mengyu Hong, Zufang Wu, Songmei Luo, and Kejun Cheng
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Nutrition and Dietetics ,Medicine (miscellaneous) ,Food Science - Published
- 2023
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5. Dietary strategies may influence human nerves and emotions by regulating intestinal microbiota: an interesting hypothesis
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Ruilin Zhang, Chi-Tang Ho, Mengyu Hong, Xin Zhang, and Yanan Liu
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Intestinal microorganisms ,Immunology ,Gut–brain axis ,Biology ,Industrial and Manufacturing Engineering ,Food Science - Published
- 2021
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6. Ultra-stable ZnO nanobelts in electrochemical environments
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Huihui Yu, Yue Zhang, Zheng Zhang, Qingliang Liao, Yang Ou, Jingjing Meng, Mengyu Hong, Zhuo Kang, and Junli Du
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Materials science ,Doping ,chemistry.chemical_element ,Zinc ,Indium doping ,Electrochemistry ,Corrosion ,Electrical transport ,chemistry ,Chemical engineering ,Materials Chemistry ,General Materials Science ,Layer (electronics) ,Indium - Abstract
Zinc oxide (ZnO) has been widely considered as a promising candidate in electro-chemical devices due to the high electrical transport performance and easy-fabrication. However, the active chemical properties of ZnO nanobelts restrict their application in practical electro-chemical devices. Here, we adopted an indium doping strategy to improve the corrosion resistance of ZnO nanobelts. Compared with other atomic doping methods, the indium doping method not only formed several layers of indium atoms in the body of ZnO nanobelts but also created a ZnxIn1−xO passivated layer on the ZnO nanobelt surface. After doping indium atoms into ZnO nanobelts, the self-corrosion potential increased and the self-corrosion current decreased which greatly reduced its corrosion rate in the electrochemical solution. Furthermore, the electrical transport properties of indium-doped zinc oxide (In–ZnO) nanobelts presented ultrahigh stability even after being soaked in the electrochemical solution for 43 hours. The enhanced anticorrosive quasi-2D ZnO nanobelts offer a promising development of ZnO-based electro-chemical devices.
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- 2021
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7. The coupling effect characterization for van der Waals structures based on transition metal dichalcogenides
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Mengyu Hong, Huihui Yu, Baishan Liu, Zhuo Kang, Yue Zhang, Zheng Zhang, and Junli Du
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Coupling ,Van der waals heterostructures ,Materials science ,business.industry ,Heterojunction ,Nanotechnology ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Characterization (materials science) ,symbols.namesake ,Semiconductor ,Coupling effect ,Transition metal ,Physics::Atomic and Molecular Clusters ,symbols ,General Materials Science ,Electrical and Electronic Engineering ,van der Waals force ,0210 nano-technology ,business - Abstract
van der Waals (vdW) heterostructures based on two-dimensional (2D) materials holding design-by-demand features offer astonishing opportunities to construct novel electronics and optoelectronics devices due to the vdW force interaction between their stacked components. At the atomically thin confinement, vdW heterostructure not only exhibits unprecedented properties as an entire counterpart, but also provides unique platforms to manipulate the vdW interfacial behaviors. Therefore, developing characterization techniques to comprehensively understand the coupling effect on structure-property-performance relationship of vdW heterostructures is crucial for fundamental science and practical applications. Here, we focus on the most widely studied 2D semiconductor transition metal dichalcogenides (TMDCs) and systematically review significant advances in characterizing the material and interfacial coupling effect of the related vdW heterostructures. Specially, we will discuss microscopy techniques for unveiling the structure-property relationship of vdW heterostructures and optical spectroscopy measurements for analyzing vdW interfacial coupling effect. Finally, we address some promising strategies to optimize characterization technologies for resolving vdW heterostructures, including coupling multiple characterization technologies, improving temporal and spatial resolution, developing fast, efficient, and non-destructive techniques and introducing artificial intelligence.
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- 2020
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8. All-van-der-Waals Barrier-Free Contacts for High-Mobility Transistors
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Xiankun Zhang, Huihui Yu, Wenhui Tang, Xiaofu Wei, Li Gao, Mengyu Hong, Qingliang Liao, Zhuo Kang, Zheng Zhang, and Yue Zhang
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Mechanics of Materials ,Mechanical Engineering ,General Materials Science - Abstract
Ultrathin 2D semiconductor devices are considered to have beyond-silicon potential but are severely troubled by the high Schottky barriers of the metal-semiconductor contacts, especially for p-type semiconductors. Due to the severe Fermi-level pinning effect and the lack of conventional semimetals with high work functions, their Schottky hole barriers are hardly removed. Here, an all-van-der-Waals barrier-free hole contact between p-type tellurene semiconductor and layered 1T'-WS
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- 2022
9. Mechanisms Underlying the Interaction Between Chronic Neurological Disorders and Microbial Metabolites
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Mengyu, Hong, Lu, Cheng, Yanan, Liu, Zufang, Wu, Peng, Zhang, and Xin, Zhang
- Abstract
The number of hydroxyl groups and existence of characteristic structural groups in tea polyphenols (TP) make them have antioxidant activity, which gives TP anti-inflammatory effects, toward protecting the intestinal flora and brain neurons. Host-associated microbial metabolites are emerging as dominant modifiers of the central nervous system. As yet, the investigations on host-microbiota crosstalking remain challenging, studies focusing on metabolites such as serotonin, short-chain fatty acids, and others have pinpointed multiple actionable signaling pathways relevant to host health. However, there are still complexities and apparent limitations inherent in transforming complex human diseases to corresponding animal models. Here, we choose to discuss several intestinal metabolites with research value, as crucial areas for assessing TP-mediated chronic brain diseases interactions with microbial.
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- 2021
10. Direct Charge Trapping Multilevel Memory with Graphdiyne/MoS2 Van der Waals Heterostructure
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Haonan Si, Qingliang Liao, Xiankun Zhang, Tang Wenhui, Mengyu Hong, Zheng Zhang, Wen Jialing, Huihui Yu, Zhuo Kang, Yue Zhang, and Junli Du
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Materials science ,General Chemical Engineering ,Science ,General Physics and Astronomy ,Medicine (miscellaneous) ,Dielectric ,Biochemistry, Genetics and Molecular Biology (miscellaneous) ,symbols.namesake ,bilayer memory ,General Materials Science ,van der Waals coupling ,Research Articles ,Coupling ,Plasma etching ,business.industry ,General Engineering ,multilevel memory ,Heterojunction ,Charge (physics) ,direct charge trapping ,Modulation ,Computer data storage ,symbols ,Optoelectronics ,van der Waals force ,business ,graphdiyne ,Research Article - Abstract
Direct charge trapping memory, a new concept memory without any dielectric, has begun to attract attention. However, such memory is still at the incipient stage, of which the charge‐trapping capability depends on localized electronic states that originated from the limited surface functional groups. To further advance such memory, a material with rich hybrid states is highly desired. Here, a van der Waals heterostructure design is proposed utilizing the 2D graphdiyne (GDY) which possesses abundant hybrid states with different chemical groups. In order to form the desirable van der Waals coupling, the plasma etching method is used to rapidly achieve the ultrathin 2D GDY with smooth surface for the first time. With the plasma‐treated 2D GDY as charge‐trapping layer, a direct charge‐trapping memory based on GDY/MoS2 is constructed. This bilayer memory is featured with large memory window (90 V) and high degree of modulation (on/off ratio around 8 × 107). Two operating mode can be achieved and data storage capability of 9 and 10 current levels can be obtained, respectively, in electronic and opto‐electronic mode. This GDY/MoS2 memory introduces a novel application of GDY as rich states charge‐trapping center and offers a new strategy of realizing high performance dielectric‐free electronics, such as optical memories and artificial synaptic., A graphdiyne (GDY)/MoS2 bilayer memory without any blocking layer is constructed. Through controllable oxygen plasma treatment, relatively large‐area and smooth 2D GDY with additionally introduced C—O and C═O is obtained, which enables excellent van der Waals coupling with MoS2 and allows for constructing the bilayer memory. With more introduced states, multilevel and dual operating mode is achieved.
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- 2021
11. Piezotronic effect on interfacial charge modulation in mixed-dimensional Van der Waals heterostructure for ultrasensitive flexible photodetectors
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Baishan Liu, Mengyu Hong, Huihui Yu, Qingliang Liao, Junli Du, Fangfang Gao, Xiankun Zhang, Zhuo Kang, Yue Zhang, Jiankun Xiao, Gao Li, and Zheng Zhang
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Photocurrent ,Materials science ,Renewable Energy, Sustainability and the Environment ,business.industry ,Photodetector ,Heterojunction ,02 engineering and technology ,Photodetection ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,symbols.namesake ,Modulation ,Electric field ,Electrode ,symbols ,Optoelectronics ,General Materials Science ,Electrical and Electronic Engineering ,van der Waals force ,0210 nano-technology ,business - Abstract
Van der Waals (vdWs) heterostructure is emerging as one of the most interesting systems in next-generation flexible optoelectronics. Furthermore, the gate-tunability of vdWs heterostructure is widely applied to enhance the performance of various devices, which is generally achieved by external electric field. However, in-plane cracking and slippage of gate electrode restricted this external electric field modulation in flexible devices. Here, we propose a distinctive strain-gating method to manipulate 2D WSe2-1D ZnO vdWs interfacial charge and modulate its photosensing performance by tuning electronic states of WSe2. With increasing tensile strain, the device shows obvious enhancing photocurrent and the corresponding photoresponsivity reaches up to 394 mA W−1 under white light illumination. Such performance enhancement can be attributed to strain-induced piezopolarization charges on ZnO nanobelt polar surface, which function as "gate" to tune the local transport of photogenerated carriers at the WSe2-ZnO vdWs interface. This work provides a new strategy to achieve interaction between vdWs interface and strain stimuli, which broadens applications of functional vdWs heterostructure for next-generation photodetection or imaging.
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- 2019
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12. The interaction effect between tea polyphenols and intestinal microbiota: Role in ameliorating neurological diseases
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Zufang Wu, Yanan Liu, Ruilin Zhang, Peifang Weng, and Mengyu Hong
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Pharmacology ,Tea ,business.industry ,Biophysics ,Polyphenols ,Cell Biology ,Gastrointestinal Microbiome ,Intestines ,Immunity ,Polyphenol ,Sleep Initiation and Maintenance Disorders ,Immunology ,Medicine ,Humans ,Intestinal bacteria ,business ,Food Science ,Stable state - Abstract
Tea polyphenols (TP) are one of the most functional and bioactive substances in tea. The interactions between TP and intestinal microbiota suggest that probiotics intervention is a useful method to ameliorate neurological diseases. Now, numerous researches have suggested that TP plays a significant role in modulating intestinal bacteria, especially in the area of sustaining a stable state of intestinal microbial function and abundance. Furthermore, homeostatic intestinal bacteria can enhance the immunity of the host. The close reciprocity between intestinal microbiota and the central nervous system provides a new chance for TP to modulate neural-related diseases depending on intestinal microbiota. Therefore, based on the bidirectional relationship between the brain and the intestines, this review provides a new clue to solve insomnia symptoms and related neurological diseases that will enable us to better study the bidirectional effects of TP and intestinal microbiota on the improvement of host health. PRACTICAL APPLICATIONS: This review provides a new clue to solve insomnia symptoms and related neurological diseases that will enable us to better study bidirectional effects of TP and intestinal microbiota on the improvement of host health.
- Published
- 2021
13. Author response for 'Dietary strategies may influence human nerves and emotions by regulating intestinal microbiota: an interesting hypothesis'
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Xin Zhang, Ruilin Zhang, Yanan Liu, Mengyu Hong, and Chi‐Tang Ho
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- 2021
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14. Strain Engineering in 2D Material-Based Flexible Optoelectronics
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Mengyu Hong, Huihui Yu, Junli Du, Zheng Zhang, Yue Zhang, Baishan Liu, and Qingliang Liao
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Materials science ,Strain engineering ,General Materials Science ,Nanotechnology ,General Chemistry - Abstract
Flexible optoelectronics, as promising components hold shape-adaptive features and dynamic strain response under strain engineering for various intelligent applications. 2D materials with atomically thin layers are ideal for flexible optoelectronics because of their high flexibility and strain sensitivity. However, how the strain affects the performance of 2D materials-based flexible optoelectronics is confused due to their hypersensitive features to external strain changes. It is necessary to establish an evaluation system to comprehend the influence of the external strain on the intrinsic properties of 2D materials and the photoresponse performance of their flexible optoelectronics. Here, a focused review of strain engineering in 2D materials-based flexible optoelectronics is provided. The first attention is on the mechanical properties and the strain-engineered electronic properties of 2D semiconductors. An evaluation system with relatively comprehensive parameters in functionality and service capability is summarized to develop 2D materials-based flexible optoelectronics in practical application. Based on the parameters, some strategies to improve the functionality and service capability are proposed. Finally, combining with strain engineering in future intelligence devices, the challenges and future perspective developing 2D materials-based flexible optoelectronics are expounded.
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- 2020
15. A van der Waals Ferroelectric Tunnel Junction for Ultrahigh‐Temperature Operation Memory
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Wenhui Tang, Xiankun Zhang, Huihui Yu, Li Gao, Qinghua Zhang, Xiaofu Wei, Mengyu Hong, Lin Gu, Qingliang Liao, Zhuo Kang, Zheng Zhang, and Yue Zhang
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General Materials Science ,General Chemistry - Abstract
Facing the constant scaling down and thus increasingly severe self-heating effect, developing ultrathin and heat-insensitive ferroelectric devices is essential for future electronics. However, conventional ultrathin ferroelectrics and most 2D ferroelectric materials (2DFMs) are not suitable for high-temperature operation due to their low Curie temperature. Here, by using few-layer α-In
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- 2022
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16. A Natural Plant Source-Tea Polyphenols, a Potential Drug for Improving Immunity and Combating Virus
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Mengyu Hong, Lu Cheng, Yanan Liu, Zufang Wu, Peng Zhang, and Xin Zhang
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Nutrition and Dietetics ,Tea ,Nutrition. Foods and food supply ,SARS-CoV-2 ,COVID-19 ,Polyphenols ,antiviral effect ,immunity ,tea polyphenols ,Gastrointestinal Microbiome ,COVID-19 Drug Treatment ,gut-lung axis ,Humans ,TX341-641 ,Food Science - Abstract
The coronavirus disease 2019 (COVID-19) is still in a global epidemic, which has profoundly affected people’s lives. Tea polyphenols (TP) has been reported to enhance the immunity of the body to COVID-19 and other viral infectious diseases. The inhibitory effect of TP on COVID-19 may be achieved through a series of mechanisms, including the inhibition of multiple viral targets, the blocking of cellular receptors, and the activation of transcription factors. Emerging evidence shows gastrointestinal tract is closely related to respiratory tract, therefore, the relationship between the state of the gut–lung axis microflora and immune homeostasis of the host needs further research. This article summarized that TP can improve the disorder of flora, reduce the occurrence of cytokine storm, improve immunity, and prevent COVID-19 infection. TP may be regarded as a potential and valuable source for the design of new antiviral drugs with high efficiency and low toxicity.
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- 2022
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17. Strain modulation on graphene/ZnO nanowire mixed-dimensional van der Waals heterostructure for high-performance photosensor
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Qingliang Liao, Shuo Liu, Xiankun Zhang, Mengyu Hong, Zhuo Kang, Lixin Zhou, Yue Zhang, Shengnan Lu, and Zheng Zhang
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Materials science ,Nanowire ,Photodetector ,02 engineering and technology ,010402 general chemistry ,01 natural sciences ,law.invention ,symbols.namesake ,Responsivity ,law ,General Materials Science ,Electrical and Electronic Engineering ,business.industry ,Graphene ,Heterojunction ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,Piezoelectricity ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Modulation ,symbols ,Optoelectronics ,van der Waals force ,0210 nano-technology ,business - Abstract
The mixed-dimensional van der Waals (vdW) heterostructure is a promising building block for strained electronics and optoelectronics because it avoids the bond fracture and atomic reconstruction under strain. We propose a novel mixed-dimensional vdW heterostructure between two-dimensional graphene and a one-dimensional ZnO nanowire for high-performance photosensing. By utilizing the piezoelectric properties of ZnO, strain modulation was accomplished in the mixed-dimensional vdW heterostructure to optimize the device performance. By combining the ultrahigh electrons transfer speed in graphene and the extremely long life time of holes in ZnO, an outstanding responsivity of 1.87 × 105 A/W was achieved. Under a tensile strain of only 0.44% on the ZnO nanowire, the responsivity was enhanced by 26%. A competitive model was proposed, in which the performance enhancement is due to the efficient promotion of the injection of photogenerated electrons from the ZnO into the graphene caused by the strain-induced positive piezopotential. Our study provides a strain-engineering strategy for controlling the behavior of the photocarriers in the mixed-dimensional vdW heterostructure, which can be also applied to other similar systems in the future.
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- 2017
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18. Controlling the Facet of ZnO during Wet Chemical Etching Its (000
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Mei, Sun, Bocheng, Yu, Mengyu, Hong, Zhiwei, Li, Fengjiao, Lyu, Xing, Li, Zhihong, Li, Xianlong, Wei, Zheng, Zhang, Yue, Zhang, and Qing, Chen
- Abstract
Special surface plays a crucial role in nature as well as in industry. Here, the surface morphology evolution of ZnO during wet etching is studied by in situ liquid cell transmission electron microscopy and ex situ wet chemical etching. Many hillocks are observed on the (000
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- 2019
19. Hidden Vacancy Benefit in Monolayer 2D Semiconductors
- Author
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Jiankun Xiao, Yang Ou, Qingliang Liao, Gao Li, Baishan Liu, Zheng Zhang, Yihe Liu, Xiaozhi Liu, Lin Gu, Junli Du, Xiangfeng Duan, Zhuo Kang, Xiankun Zhang, Mengyu Hong, Huihui Yu, and Yue Zhang
- Subjects
Electron mobility ,Materials science ,business.industry ,Mechanical Engineering ,Transistor ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,law.invention ,Semiconductor ,Mechanics of Materials ,law ,Vacancy defect ,Monolayer ,Optoelectronics ,General Materials Science ,Field-effect transistor ,0210 nano-technology ,business ,Current density ,Voltage - Abstract
Monolayer 2D semiconductors (e.g., MoS2 ) are of considerable interest for atomically thin transistors but generally limited by insufficient carrier mobility or driving current. Minimizing the lattice defects in 2D semiconductors represents a common strategy to improve their electronic properties, but has met with limited success to date. Herein, a hidden benefit of the atomic vacancies in monolayer 2D semiconductors to push their performance limit is reported. By purposely tailoring the sulfur vacancies (SVs) to an optimum density of 4.7% in monolayer MoS2 , an unusual mobility enhancement is obtained and a record-high carrier mobility (>115 cm2 V-1 s-1 ) is achieved, realizing monolayer MoS2 transistors with an exceptional current density (>0.60 mA µm-1 ) and a record-high on/off ratio >1010 , and enabling a logic inverter with an ultrahigh voltage gain >100. The systematic transport studies reveal that the counterintuitive vacancy-enhanced transport originates from a nearest-neighbor hopping conduction model, in which an optimum SV density is essential for maximizing the charge hopping probability. Lastly, the vacancy benefit into other monolayer 2D semiconductors is further generalized; thus, a general strategy for tailoring the charge transport properties of monolayer materials is defined.
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- 2021
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20. Atomic‐Thin ZnO Sheet for Visible‐Blind Ultraviolet Photodetection
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Baishan Liu, Junli Du, Mengyu Hong, Zhuo Kang, Huihui Yu, Yue Zhang, Zheng Zhang, Jiankun Xiao, Qingliang Liao, Zhenyu Wang, Yang Ou, and Xiankun Zhang
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Carbon chain ,Materials science ,business.industry ,Annealing (metallurgy) ,Photodetector ,02 engineering and technology ,General Chemistry ,Photodetection ,010402 general chemistry ,021001 nanoscience & nanotechnology ,medicine.disease_cause ,01 natural sciences ,0104 chemical sciences ,Biomaterials ,Responsivity ,Wavelength ,Semiconductor ,medicine ,Optoelectronics ,General Materials Science ,0210 nano-technology ,business ,Ultraviolet ,Biotechnology - Abstract
The atomic-thin 2D semiconductors have emerged as plausible candidates for future optoelectronics with higher performance in terms of the scaling process. However, currently reported 2D photodetectors still have huge shortcomings in ultraviolet and especially visible-blind wavelengths. Here, a simple and nontoxic surfactant-assisted synthesis strategy is reported for the controllable growth of atomically thin (1.5 to 4 nm) ZnO nanosheets with size ranging from 3 to 30 µm. Benefit from the short carbon chains and the water-soluble ability of sodium dodecyl sulfate (SDS), the synthesized ZnO nanosheets possess high crystal quality and clean surface, leading to good compatibility with traditional micromanufacturing technology and high sensitivity to UV light. The photodetectors constructed with ZnO demonstrate the highest responsivity (up to 2.0 × 104 A W-1 ) and detectivity (D* = 6.83 × 1014 Jones) at a visible-blind wavelength of 254 nm, and the photoresponse speed is optimized by the 400 °C annealing treatment (τR = 3.97 s, τD = 5.32 s), thus the 2D ZnO can serve as a promising material to fill in the gap for deep-UV photodetection. The method developed here opens a new avenue to controllably synthesize 2D nonlayered materials and accelerates their applications in high-performance optoelectronic devices.
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- 2020
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21. Controlling the Facet of ZnO during Wet Chemical Etching Its (0001¯) O‐Terminated Surface
- Author
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Zhihong Li, Fengjiao Lyu, Mei Sun, Zheng Zhang, Xing Li, Zhiwei Li, Qing Chen, Mengyu Hong, Yue Zhang, Xianlong Wei, and Yu Bocheng
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Chemical substance ,Materials science ,technology, industry, and agriculture ,Nanoparticle ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Isotropic etching ,0104 chemical sciences ,Biomaterials ,Chemical engineering ,Etching (microfabrication) ,Transmission electron microscopy ,Nano ,General Materials Science ,0210 nano-technology ,Science, technology and society ,Biotechnology ,Hillock - Abstract
Special surface plays a crucial role in nature as well as in industry. Here, the surface morphology evolution of ZnO during wet etching is studied by in situ liquid cell transmission electron microscopy and ex situ wet chemical etching. Many hillocks are observed on the (000 1¯ ) O-terminated surface of ZnO nano/micro belts during in situ etching. Nanoparticles on the apex of the hillocks are observed to be essential for the formation of the hillocks, providing direct experimental evidence of the micromasking mechanism. The surfaces of the hillocks are identified to be {01 1¯3¯ } crystal facets, which is different from the known fact that {01 1¯1¯ } crystal facets appear on the (000 1¯ ) O-terminated surface of ZnO after wet chemical etching. O2 plasma treatment is found to be the key factor for the appearance of {01 1¯3¯ } instead of {01 1¯1¯ } crystal facets after etching for both ZnO nano/micro belts and bulk materials. The synergistic effect of acidic etching and O-rich surface caused by O2 plasma treatment is proposed to be the cause of the appearance of {01 1¯3¯ } crystal facets. This method can be extended to control the surface morphology of other materials during wet chemical etching.
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- 2020
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22. Wet Etching: Controlling the Facet of ZnO during Wet Chemical Etching Its (0001¯) O‐Terminated Surface (Small 14/2020)
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Qing Chen, Zhiwei Li, Bocheng Yu, Mei Sun, Xing Li, Yue Zhang, Zheng Zhang, Xianlong Wei, Fengjiao Lyu, Mengyu Hong, and Zhihong Li
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Biomaterials ,Facet (geometry) ,Materials science ,General Materials Science ,General Chemistry ,Composite material ,Isotropic etching ,Biotechnology - Published
- 2020
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23. Ultrathin strain-gated field effect transistor based on In-doped ZnO nanobelts
- Author
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Mengyu Hong, Bing Li, Yue Zhang, Shuhao Zhang, Xiaomei Zhang, Zheng Zhang, Qingliang Liao, and Junli Du
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Materials science ,Schottky barrier ,lcsh:Biotechnology ,Nanotechnology ,02 engineering and technology ,010402 general chemistry ,01 natural sciences ,law.invention ,law ,lcsh:TP248.13-248.65 ,General Materials Science ,Organic field-effect transistor ,business.industry ,Transistor ,General Engineering ,Wide-bandgap semiconductor ,021001 nanoscience & nanotechnology ,Piezoresistive effect ,Piezoelectricity ,lcsh:QC1-999 ,0104 chemical sciences ,Thin-film transistor ,Optoelectronics ,Field-effect transistor ,0210 nano-technology ,business ,lcsh:Physics - Abstract
In this work, we fabricated a strain-gated piezoelectric transistor based on single In-doped ZnO nanobelt with ±(0001) top/bottom polar surfaces. In the vertical structured transistor, the Pt tip of the AFM and Au film are used as source and drain electrode. The electrical transport performance of the transistor is gated by compressive strains. The working mechanism is attributed to the Schottky barrier height changed under the coupling effect of piezoresistive and piezoelectric. Uniquely, the transistor turns off under the compressive stress of 806 nN. The strain-gated transistor is likely to have important applications in high resolution mapping device and MEMS devices.
- Published
- 2017
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