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1. Manipulating reflection-type all-dielectric non-local metasurfaces via parity of particle number

Author

Song, Hao, Zhang, Xuelian, Sun, Yanming, and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Parity of particle number is a new degree of freedom for manipulating metasurface, while its influence on controlling non-local metasurfaces remains an unresolved and intriguing question. We propose a metasurface consisting of periodically arranged infinite-long cylinders made from multiple layers of SiO2 and WS2. The cylinder exhibits strong backward scattering due to the overlapping magnetic dipole and electric quadrupole resonances. Without non-local coupling in unit cells, the infinite-size metasurface manifests high reflection across all instances. However, parity-dependent reflectivity diverges with non-local coupling in supercells, exhibiting either increased logarithmic or decreased exponential behavior, with significant distinctions at small particle numbers. Interestingly, equal magnitude reflection and transmission reversals are achievable through alternation between adjacent odd and even particle numbers. The finite-size non-local metasurfaces behave similarly to the infinite-size counterparts, yet high reflection disappears at small particle numbers due to energy leakage. Essentially, high reflection arises from strong backward scattering and effective suppression of lateral multiple scatterings. Our work aids in the actual metasurface design and sheds new light on photonic integrated circuits and on-chip optical communication., Comment: 24 pages, 13 figures

Published
2024

2. Bound state in the continuum and polarization-insensitive electric mirror in low-contrast metasurface

Author

Song, Hao, Zhang, Xuelian, Wang, Jian, Sun, Yanming, and Wang, Guo Ping

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

High-contrast refractive indexes are pivotal in dielectric metasurfaces for inducing various exotic phenomena, such as the bound state in the continuum (BIC) and electric mirror (EM). However, the limitations of high-index materials are adverse to the practical applications, thus low-contrast metasurfaces with comparable performance are highly desired. Here we present a low-contrast dielectric metasurface comprising radially anisotropic cylinders, which are SiO2 cylinders doped with a small amount of WS2. The cylinder exhibits unidirectional forward superscattering originating from the overlapping of the electric and magnetic dipole resonances. When normal illumination by a near-infrared plane wave, the metasurface consisting of the superscattering constituents manifests a polarization-insensitive EM. Conversely, when subjected to an in-plane incoming wave, the metasurface generates a symmetry-protected BIC characterized by an ultrahigh Q factor and nearly negligible out-of-plane energy radiation. Our work highlights the doping approach as an efficient strategy for designing low-contrast functional metasurfaces and sheds new light on the potential applications in photonic integrated circuits and on-chip optical communication.

Published
2024

6. Kerker-Type Positional Disorder Immune Metasurfaces

Author

Song, Hao, Hong, Binbin, Wang, Neng, and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Metasurfaces that can work without the rigorous periodic arrangement of meta-atoms are highly desired by practical optical micro-nano devices. In this work, we proposed two kinds of Kerker-type metasurfaces possessing positional disorder immunity. The metasurfaces are composed of two different core-shell cylinders satisfying the first and second Kerker conditions, respectively. Even with large positional disorder perturbation of the meta-atoms, the metasurfaces can still maintain the same excellent performances as periodic ones, such as the total transmission and magnetic mirror responses. This disorder immunity is due to the unidirectional forward and backward scatterings of a single core-shell cylinder leading to very weak lateral couplings between neighboring cylinders thus rarely affecting the multiple scatterings in the forward or backward direction. In contrast, the dominant response of the disordered non-Kerker-type metasurface decreases significantly. Our findings provide a new idea for designing robust metasurfaces and extend the scope of metasurface applications in sensing and communication under complex practical circumstances., Comment: 18 pages, 9 figures

Published
2023
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7. Preparation Method and Simulation Analysis of a Novel High Temperature Resistant Magnetorheological Fluidier Fluids

Author

Chen, Xing Cheng, Han, Wen Jiao, Wang, Guo Ping, Wang, Shun, Wang, Xin, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Rui, Xiaoting, editor, and Liu, Caishan, editor

Published
2024
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8. Preparation and Rheological Response of Dual-Coated Carbonyl Iron Based Magnetorheological Fluid

Author

Han, Wen Jiao, Wang, Xin, Wang, Guo Ping, Yang, Fu Feng, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Rui, Xiaoting, editor, and Liu, Caishan, editor

Published
2024
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9. Efficient free-space to chip coupling of ultrafast sub-ps THz pulse for biomolecule fingerprint sensing

Author

Qiu, Yanbing, Meng, Kun, Wang, Wanling, Chen, Jing, Cunningham, John, Robertson, Ian, Hong, Binbin, and Wang, Guo Ping

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Ultrafast sub-ps THz pulse conveys rich distinctive spectral fingerprints related to the vibrational or rotational modes of biomolecules and can be used to resolve the time-dependent dynamics of the motions. Thus, an efficient platform for enhancing the THz light-matter interaction is strongly demanded. Waveguides, owing to their tightly spatial confinement of the electromagnetic fields and the longer interaction distance, are promising platforms. However, the efficient feeding of the sub-ps THz pulse to the waveguides remains challenging due to the ultra-wide bandwidth property of the ultrafast signal. We propose a sensing chip comprised of a pair of back-to-back Vivaldi antennas and a 90{\deg} bent slotline waveguide to overcome the challenge. The effective operating bandwidth of the sensing chip ranges from 0.2 to 1.15 THz, with the free-space to chip coupling efficiency up to 50%. Over the entire band, the THz signal is 42.44 dB above the noise level with a peak of 73.40 dB. To take advantages of the efficient sensing chip, we have measured the characteristic fingerprint of {\alpha}-lactose monohydrate, and a sharp absorption dip at near 0.53 THz has been successfully observed demonstrating the accuracy of the proposed solution. The proposed sensing chip has the advantages of efficient in-plane coupling, ultra-wide bandwidth, easy integration and fabrication, large-scale manufacturing capability, and cost-effective, and can be a strong candidate for THz light-matter interaction platform., Comment: Corresponding authors: Binbin Hong's E-mail: b.hong@szu.edu.cn; Guo Ping Wang's E-mail: gpwang@szu.edu.cn

Published
2022
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11. Five-channel frequency-division multiplexing using low-loss epsilon-near-zero metamaterial waveguide

Author

Hong, Binbin, Sun, Lei, Wang, Wanlin, Qiu, Yanbing, Feng, Naixing, Su, Dong, Somjit, Nutapong, Robertson, Ian, and Wang, Guo Ping

Subjects
Physics - Applied Physics, Physics - Optics
Abstract

The rapidly growing global data usage has demanded more efficient ways to utilize the scarce electromagnetic spectrum resource. Recent research has focused on the development of efficient multiplexing techniques in the millimeter-wave band (1-10 mm, or 30-300 GHz) due to the promise of large available bandwidth for future wireless networks. Frequency-division multiplexing is still one of the most commonly-used techniques to maximize the transmission capacity of a wireless network. Based on the frequency-selective tunnelling effect of the low-loss epsilon-near-zero metamaterial waveguide, we numerically and experimentally demonstrate five-channel frequency-division multiplexing and demultiplexing in the millimeter-wave range. We show that this device architecture offers great flexibility to manipulate the filter Q-factors and the transmission spectra of different channels, by changing of the epsilon-near-zero metamaterial waveguide topology and by adding a standard waveguide between two epsilon-near-zero channels. This strategy of frequency-division multiplexing may pave a way for efficiently allocating the spectrum for future communication networks., Comment: 10 pages, 7 figures

Published
2022
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12. Tunable bilayer dielectric metasurface via stacking magnetic mirrors

Author

Song, Hao, Hong, Binbin, Qiu, Yanbing, Yu, Kuai, Pei, Jihong, and Wang, Guo Ping

Subjects
Physics - Applied Physics, Physics - Optics
Abstract

Functional tunability, environmental adaptability, and easy fabrication are highly desired properties in metasurfaces. Here we provide a tunable bilayer metasurface composed of two stacked identical dielectric magnetic mirrors, which are excited by the dominant electric dipole and other magnetic multipoles, exhibiting nonlocal electric field enhancement near the interface and high reflection. Differ from the tunability through the direct superposition of two structures with different functionalities, we achieve the reversible conversion between high reflection and high transmission by manipulating the interlayer coupling near the interface between the two magnetic mirrors. The magnetic mirror effect boosts the interlayer coupling when the interlayer spacing is small. Decreasing the interlayer spacing of the bilayer metasurface leads to stronger interlayer coupling and scattering suppression of the meta-atom, which results in high transmission. On the contrary, increasing the spacing leads to weaker interlayer coupling and scattering enhancement, which results in high reflection. The high transmission of the bilayer metasurface has good robustness due to that the meta-atom with interlayer coupling can maintain the scattering suppression against adjacent meta-atom movement and disordered position perturbation. This work provides a straightforward method (i.e. stacking magnetic mirrors) to design tunable metasurface, shed new light on high-performance optical switches applied in communication and sensing.

Published
2022
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14. One-dimensional time-Floquet photonic crystal

Author

Wang, Neng and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Using the Floquet Hamiltonian derived based on the time-dependent perturbation theory, we investigated the quasienergy bands of a one-dimensional time-Floquet photonic crystal. The time-Floquet photonic crystal contains two alternating layers labeled as A and B, and the permittivity of A layer is modulated periodically in time. We showed that the quasienergy bands are reciprocal when the modulation function is a function of time only, while the quasienergy bands could be nonreciprocal when the permittivity is modulated in both time and space through an unique combination. In the former case, the coupling between the positive (negative) and positive (negative) bands results in quasienergy gaps, while the coupling between the positive and negative bands leads to pairs of exception points, when the modulation is on the real part of the permittivity. In the latter case, the coupling between the positive (negative) and positive (negative) bands still results in quasienergy gaps. However, the coupling between the positive and negative bands leads to quasienergy gaps at a small modulation speed and pairs of exceptional points at a high modulation speed., Comment: 22 pages, 8 figures

Published
2021
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15. Disorder-immune metasurfaces with constituents exhibiting the anapole mode

Author

Song, Hao, Wang, Neng, Yu, Kuai, Pei, Jihong, and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Common optical metasurfaces are 2-dimensional functional devices composed of periodically arranged subwavelength constituents. Here, we achieved the positional-disorder-immune metasurfaces composed of core-shell cylinders which successively exhibit the magnetic dipole (MD) resonant, non-radiating anapole, and electric dipole (ED) resonant modes when their outer radii are fixed and the inner radii changes continuously in a range. The performances of the metasurfaces under a periodically structural design are not degraded even when the positions of the cylinders are subjected to random and considerable displacements. The positional-disorder-immunity is due to the weak non-local effect of the metasurfaces. Because the multiple scattering among cylinders is weak and insensitive to the spacing among the cylinders around the ED and MD resonant modes and vanishing irrespective of the spacing at the non-radiating anapole mode, the reflection properties including the reflection phase and reflectivity of the metasurfaces are insensitive to the spacing between neighboring cylinders for this entire variation range of the inner radius. The positional-disorder-immunity make the metasurface to be adapted to some unstable and harsh environments., Comment: 20 pages, 8 figures

Published
2020
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16. Effective medium theory for photonic pseudospin-1/2 system

Author

Wang, Neng, Zhang, Ruo-Yang, Chan, C. T., and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Photonic pseudospin-1/2 systems, which exhibit Dirac cone dispersion at Brillouin zone corners in analogy to graphene, have been extensively studied in recent years. However, it is known that a linear band crossing of two bands cannot emerge at the center of Brillouin zone in a two-dimensional photonic system respecting time reversal symmetry. Using a square lattice of elliptical magneto-optical cylinders, we constructed an unpaired Dirac point at the Brillouin zone center as the intersection of the second and third bands corresponding to the monopole and dipole excitations. Effective medium theory can be applied to the two linearly crossed bands with the effective constitutive parameters numerically calculated using the boundary effective medium approach. It is shown that only the effective permittivity approaches zero while the determinant of the nonzero effective permeability vanishes at the Dirac point frequency, showing a different behavior from the double-zero index metamaterials obtained from the pseudospin-1 triply degenerate points for time reversal symmetric systems. Exotic phenomena, such as the Klein tunneling and Zitterbewegung, in the pseudospin-1/2 system can be well understood from the effective medium description. When the Dirac point is lifted, the edge state dispersion near the $\Gamma$ point can be accurately predicted by the effective constitutive parameters. We also further realized magneto-optical complex conjugate metamaterials for a wide frequency range by introducing a particular type of non-Hermittian perturbations which make the two linear bands coalescence to form exceptional points at the real frequency., Comment: 48 pages, 14 figures

Published
2020
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17. Transmissive Metagrating for Arbitrary Wavefront Shaping Over the Full Visible Spectrum

Author

Deng, Zi-Lan, Ye, Xuan, Qiu, Hao-Yang, Tu, Qing-An, Shi, Tan, Zhuang, Ze-Peng, Cao, Yaoyu, Guan, Bai-Ou, Feng, Naixing, Wang, Guo Ping, Alù, Andrea, Dong, Jian-Wen, and Li, Xiangping

Subjects
Physics - Optics
Abstract

Metagratings have been shown to form an agile and efficient platform for extreme wavefront manipulation, going beyond the limitations of gradient metasurfaces. Previous approaches for transmissive metagratings have resorted on compound asymmetric inclusions to achieve single-channel near-perfect diffraction. However, such complex inclusions are sensitive to geometric parameters and lack the flexibility for arbitrary phase modulation, restricting applications to beam deflection. Here, we show perfect unitary diffraction in all-dielectric transmissive metagratings using rectangular inclusions by tailoring their multipole interferences. Using this principle, we experimentally demonstrate analog phase profile encoding of a hologram through displacement modulation of CMOS-compatible silicon nitride nanobars, manifesting broadband and wide-angle high diffraction efficiencies for both polarizations and across the entire visible range. Featured with extreme angle/wavelength/polarization tolerance and alleviated structural complexity for both design and fabrication, our demonstration unlocks the full potential of metagrating-based wavefront manipulation for a variety of practical applications.

Published
2020

21. Substrate Integrated Bragg Waveguide: an Octave-bandwidth Single-mode Functional Transmission-Line for Millimeter-Wave and Terahertz Applications

Author

Hong, Binbin, Feng, Naixing, Chen, Jing, Wang, Guo Ping, Doychinov, Viktor, Clarke, Roland, Somjit, Nutapong, Cunningham, John, and Robertson, Ian

Subjects
Physics - Applied Physics, Physics - Optics
Abstract

We demonstrate an air-core single-mode hollow waveguide that uses Bragg reflector structures in place of the vertical metal walls of the standard rectangular waveguide or via holes of the so-called substrate integrated waveguide. The high-order modes in the waveguide are substantially suppressed by a modal-filtering effect, making the waveguide operate in the fundamental mode over more than one octave. Numerical simulations show that the propagation loss of the proposed waveguide can be lower than that of classic hollow metallic rectangular waveguides at terahertz frequencies, benefiting from a significant reduction in Ohmic loss. To facilitate fabrication and characterization, a proof-of-concept 20 to 45 GHz waveguide is demonstrated, which verifies the properties and advantages of the proposed waveguide. A zero group-velocity dispersion point is observed at near the middle of the operating band. This work offers a step towards a novel hybrid transmission-line medium that can be used in a variety of functional components for broadband millimeter-wave and terahertz applications., Comment: 11 pages, 9 figures, journal article

Published
2019
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22. Strong Vibrational Coupling in Room Temperature Plasmonic Resonators

Author

Wang, Junzhong, Yu, Kuai, Yang, Yang, Hartland, Gregory V., Sader, John E., and Wang, Guo Ping

Subjects
Physics - Applied Physics
Abstract

Strong vibrational coupling has been realized in a variety of mechanical systems from cavity optomechanics to electromechanics.$^{1, 2, 3, 4, 5}$ It is an essential requirement for enabling quantum control over the vibrational states.$^{6, 7, 8, 9, 10, 11}$ The majority of the mechanical systems that have been studied to date are vibrational resonances of dielectric or semiconductor nanomaterials coupled to optical modes.$^{12, 13, 14, 15}$ While there are fewer studies of coupling between two mechanical modes,$^{3, 9}$ particularly, there have been no experimental observation of strong coupling of the ultra-high frequency acoustic modes of plasmonic nanostructures, due to the rapid energy dissipation in these systems. Here we realized strong vibrational coupling in ultra-high frequency plasmonic nanoresonators by increasing the vibrational quality factors by an order of magnitude. This is achieved through blocking an energy dissipation pathway in the form of out-going acoustic waves. We achieved the highest frequency quality factor products of $\mathbf{f}\times\mathbf{Q}=1.0\times10^{13}$ Hz for the fundamental mechanical modes in room temperature plasmonic nanoresonators reported to date, which exceeds the value of $0.1\times10^{13}$ Hz required for ground state cooling. Avoided crossing were observed between the vibrational modes of two plasmonic nanoresonators with a coupling rate of $\mathbf{g}=7.5\pm 1.2$ GHz, an order of magnitude larger than the dissipation rates. The intermodal strong coupling was consistent with theoretical calculations using a coupled oscillator model. Our results expanded the strong coupling systems for mechanical resonators and enabled a platform for future observation and control of the quantum behavior of phonon modes in metallic nanoparticles., Comment: 29 pages, 4 figures

Published
2019
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29. A multifunctional metasurface: from extraordinary optical transmission to extraordinary optical diffraction in a single structure

Author

Deng, Zi-Lan, Li, Xiangping, and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

We show that, a metasurface composed of subwavelength metallic slit array embedded in an asymmetric environment can exhibit either extraordinary optical transmission (EOT) or extraordinary optical diffraction (EOD). By employing an analytical model expansion method and the diffraction order chart in k-vector space, we found that the resonance decaying pathway of the local slit cavity mode can be tuned to either 0th or -1st diffraction order by changing the parallel wavevector, which gives rise to enhanced 0th transmission (EOT) of the structure for small incident angles, and enhanced -1st diffraction (EOD) for large incident angles. Based on this appealing feature, a multifunctional metasurface that can switch its functionality between transmission filter, mirror and off-axis lens is demonstrated. Our findings provide a convenient way to construct multifunctional integrated optical devices on a single planar device., Comment: 18 Pages, 5 figures

Published
2017
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36. Observation of elastic heterogeneity and phase evolution in 2D layered perovskites using coherent acoustic phonons

Author

Wang Junzhong, Zhu Jiaqi, Jiang Yiqi, Li Mengying, Yu Kuai, and Wang Guo Ping

Subjects
acoustic phonon, elastic heterogeneity, perovskite, time-domain brillouin spectroscopy, Physics, QC1-999
Abstract

Two-dimensional (2D) organic–inorganic perovskites have shown interesting optical properties due to the natural quantum-well structures. The repetition of soft organic and hard inorganic intercalations also renders 2D perovskites rich phonon dynamics. Here, we investigated the coherent acoustic phonons in (PEA)2PbI4 perovskite films by time-resolved Brillouin spectroscopy. The coherent acoustic phonons were launched indirectly in perovskite films by exciting Au nanoplates which were used as optoacoustic transducers. A longitudinal sound velocity ν = 1937 ± 31 m/s, and an elastic modulus E = 9.84 GPa along the cross-plane direction of perovskites were obtained from analysis of the Brillouin oscillation frequency. Following a bead-spring model, we calculated a spring constant k ≈ 1.709 N m−1 for PEA cations which is comparably small for perovskites. We also demonstrated that coherent acoustic phonons are sensitive to differentiate structural heterogeneity and monitor dynamic phase evolution in perovskite films. Domains of PbI2-rich and PbI2-poor phases were identified. Under light stimulus, PbI2-poor phases were gradually disappearing and PbI2-rich phases became crystallized. The observations of structural and elastic heterogeneity and dynamic phase evolution using coherent acoustic phonons provide a toolbox for submicroscale elastic characterization of perovskites.

Published
2021
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37. All-optical modulation based on MoS2-Plasmonic nanoslit hybrid structures

Author

Sun Feiying, Nie Changbin, Wei Xingzhan, Mao Hu, Zhang Yupeng, and Wang Guo Ping

Subjects
all-optical modulator, intraband transition, mos2, plasmonic nanoslit, waveguide, Physics, QC1-999
Abstract

Two-dimensional (2D) materials with excellent optical properties and complementary metal-oxide-semiconductor (CMOS) compatibility have promising application prospects for developing highly efficient, small-scale all-optical modulators. However, due to the weak nonlinear light-material interaction, high power density and large contact area are usually required, resulting in low light modulation efficiency. In addition, the use of such large-band-gap materials limits the modulation wavelength. In this study, we propose an all-optical modulator integrated Si waveguide and single-layer MoS2 with a plasmonic nanoslit, wherein modulation and signal light beams are converted into plasmon through nanoslit confinement and together are strongly coupled to 2D MoS2. This enables MoS2 to absorb signal light with photon energies less than the bandgap, thereby achieving high-efficiency amplitude modulation at 1550 nm. As a result, the modulation efficiency of the device is up to 0.41 dB μm−1, and the effective size is only 9.7 µm. Compared with other 2D material-based all-optical modulators, this fabricated device exhibits excellent light modulation efficiency with a micron-level size, which is potential in small-scale optical modulators and chip-integration applications. Moreover, the MoS2-plasmonic nanoslit modulator also provides an opportunity for TMDs in the application of infrared optoelectronics.

Published
2021
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38. Wide-angle and high-efficiency achromatic metasurfaces for visible light

Author

Deng, Zi-Lan, Zhang, Shuang, and Wang, Guo Ping

Subjects
Physics - Optics
Abstract

Recently, an achromatic metasurface was successfully demonstrated to deflect light of multiple wavelengths in the same direction and it was further applied to the design of planar lenses without chromatic aberrations [Science, 347, 1342(2015)]. However, such metasurface can only work for normal incidence and exhibit low conversion efficiency. Here, we present an ultrawide-angle and high-efficiency metasurface without chromatic aberration for wavefront shaping in visible range. The metasurface is constructed by multiple metallic nano-groove gratings, which support enhanced diffractions for an ultrawide incident angle range from 10o to 80o due to the excitations of localized gap plasmon modes at different resonance wavelengths. Incident light at these resonance wavelengths can be efficiently diffracted into the same direction with complete suppression of the specular reflection. This approach is applied to the design of an achromatic flat lens for focusing light of different wavelengths into the same position. Our findings provide a facile way to design various achromatic flat optical elements for imaging and display applications.

Published
2016
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43. Flexible Single-Crystal Perovskite Photodetectors via Polymer-Controlled Transfer

Author

Zhang, Zhen Yu and Wang, Guo Ping

Abstract

The large-sized perovskite single-crystal sheet (SCS) serves as the ideal research platform for perovskite photodetectors due to its outstanding carrier photophysics, pronounced geometric aspect ratio, and ultrahigh material utilization rate. However, its performance in flexible device applications is relatively lackluster due to the rigid and brittle nature of the three-dimensional cubic lattices. In this work, the indium tin oxide (ITO)-based multimillimeter-sized MAPbBr3SCS is transformed into MAPbI3SCS via ion exchange strategy. Significantly, we proposed and implemented a polymer-controlled transfer strategy─utilizing the dichloromethane (DCM) solution of poly(methyl methacrylate) (PMMA)─to nondestructively transfer the whole perovskite SCS off the ITO substrates and subsequently adhere it onto a flexible polyethylene terephthalate (PET) substrate of interdigital electrode, thereby fabricating a lateral-structured photodetector with a PMMA-SCS-Au-PET multilayer configuration. The tight self-encapsulation between the top PMMA membrane and the bottom PET substrate imparts excellent waterproof stability and concurrently excellent mechanical flexibility to these devices; additionally, the MAPbI3device exhibits comprehensively superior performance to the MAPbBr3one. This work represents a proactive attempt and exploration of the high-performance advancement of large-sized SCS photodetectors, undoubtedly introducing novel momentum and solutions to this domain.

Published
2024
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45. Silencing linc00662 inhibits cell proliferation and colony formation of lung cancer cells via regulating the miR-145-5p-PAFAH1B2 axis

Author

Xu, Zhe-yuan, Peng, Jun, Shi, Zhi-zhou, Chen, Xin-long, Cheng, Hong-zhong, Wang, Han, Wang, Yang, Wang, Guo-ping, Jiang, Wen, and Peng, Hao

Subjects
Cell proliferation -- Analysis, Gene expression -- Analysis, Gene silencing -- Analysis, Squamous cell carcinoma -- Physiological aspects, MicroRNA -- Analysis -- Identification and classification, Lung cancer -- Physiological aspects, Biological sciences
Abstract

Lung cancer is the most common cause of cancer-related death in the world. Long non-coding RNAs (lncRNAs) are longer than 200 nucleotide transcripts, and are not translated into protein. The lncRNA linc00662 is overexpressed in lung cancer; however, its role in lung cancer is still unknown. In our study, by analyzing the TCGA data, we found that linc00662 was overexpressed in lung adenocarcinoma (LUAD) and lung squamous cell carcinoma (LUSC). We knocked-down the expression of linc00662 using siRNA, and found that silencing linc00662 significantly inhibited the proliferation and colony formation of the lung cancer cell lines A549 and H460. We also found that knockdown of linc00662 increased the expression of the microRNA miR-145-5p and decreased the expression of the platelet-activating factor acetylhydrolase IB subunit beta (PAFAH1B2) gene. We further show that linc00662 binds with miR-145-5p, and that miR-145-5p binds to the 3'UTR of PAFAH1B2. miR-145-5p negatively regulates PAFAH1B2 both at the mRNA and the protein level. Loss of miR-145-5p abolished the inhibitory effects of silencing linc00662 on the proliferation and colony formation of A549 and H460 cells. These findings indicate that linc00662 functions as an oncogene by acting as a competing endogenous RNA (ceRNA) and sponges and regulates miR-145-5p in lung cancer, and thus may provide a potential target for treating lung cancer. Key words: linc00662, PAFAH1B2, miR-145-5p, proliferation, colony formation, lung cancer. Le cancer du poumon est la cause la plus fréquente de décès liés au cancer dans le monde. Les longs ARN non codants (lncARN) sont des transcrits de plus de 200 nucléotides qui ne sont pas traduits en protéines. Le linc00662 est surexprimé dans le cancer du poumon. Cependant, le rôle du linc00662 dans la progression du cancer du poumon est encore inconnu. Dans cette étude, les auteurs ont découvert que le linc00662 était surexprimé dans l'adénocarcinome du poumon et le carcinome épidermoïde du poumon en analysant les données de l'atlas TCGA. Ils ont réduit par knockdown l'expression du linc00662 en utilisant des ARNsi et découvert que le silençage du linc00662 inhibait de manière significative la prolifération et la formation de colonies des cellules A549 et H460. Ils ont également découvert que le knockdown du linc00662 accroissait l'expression du miR-145-5p et diminuait l'expression de PAAFAAH1B2 (platelet-activating factor acetylhydrolase IB subunit beta). Ils ont aussi montré que le linc00662 pouvait se lier au miR-145-5p, et que le miR-145-5p pouvait se lier à l'extrémité 3'UTR de PAFAH1B2. Le miR-145-5p pouvait réguler négativement PAFAH1B2 au niveau de l'ARNm et de la protéine. La perte du miR-145-5p pouvait abolir les effets inhibiteurs du silençage du linc00662 sur la prolifération et la formation de colonies des cellules A549 et H460. Toutes ces données ont montré que le linc00662 fonctionnait comme un oncogène en agissant comme un ARN endogène compétitif (ARNce) pour capturer et réguler le miR-145-5p dans le cancer du poumon et qu'il pourrait constituer une cible potentielle pour le traitement du cancer du poumon. [Traduit par la Rédaction.] Mots-clés : linc00662, PAFAH1B2, miR-145-5p, prolifération, formation de colonies, cancer du poumon., Introduction Lung cancer is the leading cause of cancer-related death in the world. Although progress has been made in the treatment of lung cancer, the survival of patients with lung [...]

Published
2021
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