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1. High-performance terahertz modulators induced by substrate field in Te-based all-2D heterojunctions

Author

Pujing Zhang, Qihang Liang, Qingli Zhou, Jinyu Chen, Menglei Li, Yuwang Deng, Wanlin Liang, Liangliang Zhang, Qinghua Zhang, Lin Gu, Chen Ge, Kui-juan Jin, Cunlin Zhang, and Guozhen Yang

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Abstract High-performance active terahertz modulators as the indispensable core components are of great importance for the next generation communication technology. However, they currently suffer from the tradeoff between modulation depth and speed. Here, we introduce two-dimensional (2D) tellurium (Te) nanofilms with the unique structure as a new class of optically controlled terahertz modulators and demonstrate their integrated heterojunctions can successfully improve the device performances to the optimal and applicable levels among the existing all-2D broadband modulators. Further photoresponse measurements confirm the significant impact of the stacking order. We first clarify the direction of the substrate-induced electric field through first-principles calculations and uncover the unusual interaction mechanism in the photoexcited carrier dynamics associated with the charge transfer and interlayer exciton recombination. This advances the fundamental and applicative research of Te nanomaterials in high-performance terahertz optoelectronics.

Published
2024
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2. Dynamic large-array terahertz imaging display based on high-performance 1D/2D tellurium homojunction modulators

Author

Pujing Zhang, Xue Hao, Qingli Zhou, Guangwei She, Jinyu Chen, Xuteng Zhang, Wanlin Liang, Yuwang Deng, Tingyin Ning, WenSheng Shi, Liangliang Zhang, and Cunlin Zhang

Subjects
Applied optics. Photonics, TA1501-1820
Abstract

Mixed-dimensional van der Waals systems could improve terahertz modulators’ performance by utilizing the advantages of different dimensional materials. However, the reported available mixed-dimensional heterojunctions using two-dimensional (2D) and three-dimensional materials usually sacrifice the modulation speed to realize a higher modulation depth. Here, we creatively integrate one-dimensional (1D) nanowires with 2D nanofilms to construct the novel mixed-dimensional tellurium (Te) homojunction and achieve optimal indices with an ultrahigh modulation depth and a shorter carrier lifetime. In addition, a Te-based large-array imaging element was fabricated to successfully reproduce the painting colors under specific pump conditions as well as the dynamic multicolor display. Further measurements with the introduction of metamaterials prove that the required energy consumption can be significantly reduced by one order of magnitude. Our proposed 1D/2D integration strategy opens a new way to build high-performance terahertz functional devices and greatly expands the application fields of Te nanomaterials.

Published
2024
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3. Multi-state polarization switching and multifunction-integrated terahertz metadevice enabled by inverse resonance responses

Author

Yuwang Deng, Qingli Zhou, Xuteng Zhang, Pujing Zhang, Wanlin Liang, Tingyin Ning, Yulei Shi, and Cunlin Zhang

Subjects
terahertz, metadevice, multi-state polarization switching, multifunction-integrated, resonance coupling, Physics, QC1-999
Abstract

Dynamical control of terahertz metadevices and integration of versatile functions are highly desired due to increasing practical demands. Here, we propose a multifunctional photosensitive Si hybrid metastructure consisting of twisted split-ring resonator pairs that could empower multi-state polarization switching and object-recognized imaging. The theoretical and simulated results show that inverse complete modulation of cross-polarized components could be realized via tuning the conductivity of the Si-bridge. The calculated ellipticity indicates that our metadevices possess the ability to convert linearly polarized light into left-hand circular-polarized or right-hand circular-polarized waves, as well as left-hand circular-polarized or right-hand circular-polarized into linearly polarized states. Combined with these properties, mono-parameter amplitude imaging and amplitude-phase synergistic encryption imaging are accomplished. Our research provides a new strategy to develop reconfigurable and multifunctional components in the terahertz regime.

Published
2023
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4. Dual-Band and Multi-State Polarization Conversion Using aTerahertz Symmetry-Breaking Metadevice

Author

Yuwang Deng, Qingli Zhou, Xuteng Zhang, Pujing Zhang, Wanlin Liang, Tingyin Ning, Yulei Shi, and Cunlin Zhang

Subjects
terahertz, symmetry-breaking metadevice, dual band, multi state, polarization conversion, Chemistry, QD1-999
Abstract

We numerically and experimentally demonstrate a terahertz metadevice consisting of split-ring resonators (SRRs) present within square metallic rings. This device can function as a dual-band polarization converter by breaking the symmetry of SRRs. Under x-polarized incidence, the metastructure is able to convert linearly polarized (LP) light into a left-hand circular-polarized (LCP) wave. Intriguingly, under y-polarized incidence, frequency-dependent conversion from LP to LCP and right-hand circular-polarized (RCP) states can be achieved at different frequencies. Furthermore, reconfigurable LCP-to-LP and RCP-to-LP switching can be simulated by integrating the device with patterned graphene and changing its Fermi energy. This dual-band and multi-state polarization control provides an alternative solution to developing compact and multifunctional components in the terahertz regime.

Published
2023
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5. Analysis of Evolution of Coupled Lorentz Resonances and Their Sensing Properties in Terahertz Metamaterials

Author

Nan Jiang, Ziye Zhang, Wanlin Liang, Yuwang Deng, Pujing Zhang, Cunlin Zhang, and Qingli Zhou

Subjects
coupled resonances, Lorentz oscillator model, terahertz metamaterial, spectral evolution, sensing property, Physics, QC1-999
Abstract

Combined with experimental and simulated results, the resonances and metamaterial-induced transparency have been theoretically investigated using the Lorentz oscillator model for terahertz metamaterials with unequal-length bar structures. The bar spacing has an impact on the spectral evolution, implying that the coupling between metal bars varies correspondingly in one unit cell and the adjacent cells. Different from the evidence that the strongest coupling occurs in double bar structures when the bar spacing is uniform in the entire sample, the coupling in 3 bar structures is more complicated due to the weakened coupling with the middle bar and increased coupling between the other 2 bars by further increasing the bar spacing. The dependence of calculated transmission spectra on the damping rate and coupling coefficient is demonstrated, showing that the fitting parameters could control and tune the resonant dips, the transparency peaks, and even the quality factors of the spectra regularly. Furthermore, the sensing properties have been investigated by simulating the spectral evolution with the overlayers of different refractive indices to optimize the sensing parameters. Our obtained results could advance the understanding of resonance coupling and offer the possibility to further study the modulation and biosensing in the coupled terahertz devices.

Published
2022
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8. Ultrahigh Modulation Enhancement in All-Optical Si-Based THz Modulators Integrated with Gold Nanobipyramids

Author

Pujing Zhang, Tong Cai, Qingli Zhou, Guangwei She, Wanlin Liang, Yuwang Deng, Tingyin Ning, WenSheng Shi, Liangliang Zhang, and Cunlin Zhang

Subjects
Mechanical Engineering, General Materials Science, Bioengineering, General Chemistry, Condensed Matter Physics
Abstract

Optical regulation strategy with the aid of hybrid materials can significantly optimize the performance of terahertz devices. Gold nanobipyramids (AuNBPs) with synthetical tunability to the near-infrared band show strong local field enhancement, which improves optical coupling at the interface and benefits the modulation performance. We design AuNBPs-integrated terahertz modulators with multiple structured surfaces and demonstrate that introducing AuNBPs can effectively enhance their modulation depths. In particular, an ultrahigh modulation enhancement of 1 order of magnitude can be achieved in the AuNBPs hybrid metamaterials accompanied by the multifunctional modulation characteristics. By application of the coupled Lorentz oscillator model, the theoretical calculation suggests that the optical regulation with AuNBPs originates from increased damping rate and higher coupling coefficient under pump excitation. Additionally, a terahertz spatial light modulator is constructed to demonstrate multiple imaging display and consume extremely low power, which is promising for the potential application in spatial and frequency selective imaging.

Published
2022

12. Facile synthesis of Ni foam-supported prickly Au nanoparticles by galvanic displacement for electrocatalytic oxidation of glycerol

Author

Tong Cai, Pujing Zhang, Guangwei She, Qingli Zhou, Lixuan Mu, Yun Liu, and Wensheng Shi

Subjects
General Materials Science
Abstract

The development of electrocatalysts with high activity is essential to convbar glycerol into value-added chemicals through electrocatalytic oxidation. Nano-sized metals with prickly structures are expected to possess high electrocatalytic activity due to the strong electric field at the sharp tips. We propose a facile approach to prepare Au nanoparticles with prickly structure by galvanic displacement in this work. The reaction between Au3+ and Ni generates in situ highly dispersed Au nanoparticles with prickly structures on the Ni foam. Owing to appropriate prickly structure, the Au nanoparticles prepared at 25∘C for 30 s exhibited the best electrocatalytic performance. Finite element simulation method simulations show that the high-density of positive charge at the tips forms strong electric field, which enriches OH− ions and promotes glycerol oxidation, thus exhibiting excellent electrocatalytic activity. This study will guide further design/development of electrocatalytic nanostructured Au particles and provide an effective route to electrocatalytically oxidize glycerol.

Published
2022

15. Resonance dependence of electrically reconfigurable VO2-based THz metadevice for memory information processing

Author

Wanlin Liang, Ge Li, Qingli Zhou, Ziye Zhang, Suqi Zhang, Tingyin Ning, Pujing Zhang, Yuwang Deng, Cunlin Zhang, Chen Ge, and Kuijuan Jin

Subjects
Physics and Astronomy (miscellaneous)
Abstract

A terahertz hybrid metamaterial incorporated with active media VO2 holds great promise for the realization of a new generation of reconfigurable and multifunctional devices. However, for the electrical control, many efforts on reducing high working threshold are usually based on the utilization of patterned VO2 patches or additional insulation layers, which will increase the complexity of the fabrication procedure. Here, we have proposed an effective strategy only by combining the surface microstructure and the unpatterned VO2 film to realize the tunability of working current and uncover its highly dependent correlation with the structural resonance responses. It is shown the fully modulated current in our hybrid metastructures can be reduced with the prominently separated hysteresis loops. Further developed binary encoders can perform not only the information transformation of the fixed code symbols but also the arbitrary encoding with the programmable current pulse. Additionally, the dynamic color display can be accomplished to illustrate the intriguing function of the information encryption and multi-image reappearance with the current as the decryption key. Our work provides an approach to reduce the operating current and paves a pathway for the development of photonic memory information processors.

Published
2023

16. Active control properties and coupling effect in the terahertz metamaterials

Author

Pujing Zhang, Zhengyan Liu, Chenxin Ding, Qingli Zhou, Ji Qi, Hongru Ma, and Cunlin Zhang

Subjects
Split-ring resonator, Dipole, Materials science, Terahertz radiation, Physics::Optics, Resonance, Metamaterial, Dielectric, LC circuit, Atomic physics, Coupling coefficient of resonators
Abstract

We modulate the electromagnetic response of terahertz metamaterials by exciting photogenerated carriers with ultra-short pulsed laser, and realize the active control of terahertz transmission and resonances in a wide band. The experimental results show that when the terahertz electric vector is perpendicular and parallel to the bar direction with the open gap in the circular split ring resonators, respectively, the transmission of the non-resonant region and resonance absorption are significantly tuned by the irradiated pump pulse. With the increase of the pump power, the resonance absorption peak decreases and the frequency of resonance dip has a remarkable blue-shift. Meanwhile, the transmission of the non-resonant region decreases correspondingly. It is also found that the blue-shift of the resonance is mainly determined by the change of conductivity and dielectric constant in the photoexcited layer of the substrate. Through the numerical simulation, we have further proved the introduction of pump light has a significant modulation effect on the electromagnetic properties of terahertz metamaterials. Additionally, it can be observed that the LC resonance annihilates earlier than the resonance of the dipole resonance with the increase of pump power, implying the former is particularly sensitive to the variation of the active control. In the theoretical analysis, based on the Lorenz oscillator model, we have derived and calculated the resonance response intensity of the coupled oscillators under an external field. The calculated results indicate the coupling coefficient and damping rate have an impact on the spectra evolution, showing that the resonant response peak has a remarkable blue-shift with the increase of coupling coefficient and the resonance response intensity decreases with the increase of damping rate.

Published
2021

17. Influence of dielectric environment on the resonant characteristics in anisotropic terahertz metamaterials

Author

Chenxin Ding, Zhengyan Liu, Hongru Ma, Qingli Zhou, Pujing Zhang, Ji Qi, and Cunlin Zhang

Subjects
Dipole, Materials science, business.industry, Terahertz radiation, Oscillation, Physics::Optics, Optoelectronics, Metamaterial, Resonance, Dielectric, business, Polarization (waves), Refractive index
Abstract

Highly sensitive response of anisotropic terahertz metamaterials to electromagnetic waves has attracted considerable attention due to its potential applications in terahertz modulators and biosensing devices. We designed three microstructure samples with split ring arrays. The terahertz transmission spectra are experimentally measured at different rotation angle. It is found that as the rotation angle increases, the resonance mode has gradually evolved from a single dipole oscillation mode to the double oscillation modes accompanied with LC and dipole oscillations, we further simulated the polarization conversion characteristics of the single splitting rings. It shows that the highest conversion efficiency appears at 45 degrees. But it doesn’t have polarization conversion effect at 0° and 90°. Subsequently, we have utilized ultrashort pulse laser to optically control the electromagnetic response by exciting the photogenerated carriers in the metamaterial samples. The experimental data show that the transmittance change obviously with the pump light. Additionally, when the angle is 90 degrees, it can be observed that the LC resonance annihilates earlier than the resonance of the dipole resonance with the increase of pump power, implying the former is particularly sensitive to the variation of the dielectric environment. To further explore the influence of dielectric environment on the resonance characteristics of the terahertz metamaterials, we have further performed the simulations with the applied surface analyte of different refractive index. The simulated data show that with the increase of the refractive index of the surface analyte, the resonance frequency of the dipole oscillation has a more significant blue shift than the resonance frequency of the LC oscillation. Our obtained results could provide the idea for designing terahertz modulators and sensitive biosensing devices.

Published
2021

18. Simulation of terahertz transmission modulation based on nested metal resonator metamaterials

Author

Mengyuan Wang, Qingli Zhou, Cunlin Zhang, Suqi Zhang, and Pujing Zhang

Subjects
Split-ring resonator, Resonator, Amplitude, Materials science, Electromagnetics, Modulation, Terahertz radiation, business.industry, Metamaterial, Resonance, Optoelectronics, business
Abstract

Metamaterials has shown outstanding flexibility and functionality in optics and electromagnetics, which attracted plenty of interest. Nested ring resonators have a wide range of applications in terahertz (THz) spectroscopy, sensing and communication. Hence, we design a kind of metamaterials structure which can modulate THz transmission and resonance. It consists of a circular split ring resonator (CSRR) inside a closed square ring resonator. The single CSRR has an inductive-capacitive (LC) resonance and the single closed square ring resonator has a dipole resonance. After nesting two resonators, the resonance mode is changed from single mode to double modes. The results show that the amplitude transmission of non-resonant region is related to the gap opening and the asymmetry of structure. The amplitude transmission of resonance region depends on the conductivity of substrate. With the gap opening of CSRR increases, the amplitude transmission of non-resonant region increase. Meanwhile, the frequency of resonance has an obvious blue-shift. With the bottom edge distance of the two resonators decreases(the asymmetry increases), the amplitude transmission of the non-resonant region increases gradually and the low frequency of resonance has a red-shift and the high frequency of resonance has a blue-shift. To further analyze the influence of conductivity of substrate on amplitude transmission, we change the conductivity of substrate during the simulation. The results demonstrate that with the conductivity of the substrate increases, the resonance absorption peak decreases until disappears, the amplitude transmission of the non-resonant region decreases. Our results may have the potential applications in THz modulator.

Published
2021

19. Plasmon-induced transparency effect in terahertz metamaterials

Author

Mengyuan Wang, Cunlin Zhang, Pujing Zhang, Suqi Zhang, and Qingli Zhou

Subjects
Resonator, Materials science, Terahertz radiation, business.industry, Transmittance, Physics::Optics, Resonance, Metamaterial, Optoelectronics, Absorption (electromagnetic radiation), business, Refractive index, Plasmon
Abstract

With strong optical response from subwavelength metamaterial structures in terahertz, plasmon-induced transparency (PIT) has attracted considerable attention in terahertz modulators and biosensing devices. Here, we tune PIT effect by the destructive interference of two bright modes. We design a terahertz metamaterials structure with triple U-shaped resonators (TUR) arrays. In the vertical direction, double U-shaped resonators (DUR) are arranged downward, single-U resonator (SUR) is upward. We change the length of the SUR, the inner arms of the DUR and the horizontal distance of the DUR in order to observe the terahertz transmission spectrum. It is found from the results that with the length of the SUR increases, the resonant frequency has an obvious red-shift, the absorption of the low-frequency resonance increases and the nonresonance absorption peak gradually decreases. As the arms of the DUR increase and the distance between them decreases in horizontal, the frequency of resonance dip has a red-shift, and the transmittance of the non-resonant region increases slightly. To explore the influence of dielectric environment on the resonance characteristics of the terahertz metamaterials, we have further performed the simulations with the applied surface analyte of different refractive index. The results show that with the increase of the refractive index of the surface of the analyte, the resonance frequency has a more significant red-shift. Our obtained results could provide the idea for designing terahertz modulators and sensitive biosensing devices.

Published
2021

20. Heterointerface-Enhanced Ultrafast Optical Switching via Manipulating Metamaterial-Induced Transparency in a Hybrid Terahertz Graphene Metamaterial

Author

Nan Jiang, Pujing Zhang, Wanlin Liang, Tingyin Ning, Yuwang Deng, Qingli Zhou, and Cunlin Zhang

Subjects
Coupling, Materials science, business.industry, Terahertz radiation, Graphene, Physics::Optics, Metamaterial, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Optical switch, 0104 chemical sciences, law.invention, Photoexcitation, Dipole, law, Electric field, Optoelectronics, General Materials Science, 0210 nano-technology, business
Abstract

We have demonstrated the active manipulation of metamaterial-induced transparency (MIT) in a terahertz hybrid metamaterial with graphene overlayer under photoexcitation. It is found that the introduction of graphene can greatly modify the resonant dips and transparency window through the formed depolarization field around unequal-length double bars to weaken dipole resonances and their destructive interference. Transient control of MIT behaviors is determined by the photogenerated carrier dynamics, which influences the distributions of currents and electric fields in the resonant region to hinder the near-field coupling of two bright modes. Optical modulation depth is sensitive to bar spacing due to an anomalous increased double-bar coupling involving intracell and intercell interaction. Heterointerface formed by the added graphene with substrate could further enhance terahertz response via effective separation of the photoexcited carriers. Theoretical calculation based on the coupled Lorentz oscillator model reveals that the photoinduced terahertz response mainly originates from the coupling and damping in hybrid structures. Our findings could facilitate the development of graphene-based dynamical terahertz modulators and optoelectronic devices.

Published
2021

21. Varied terahertz transmission responses observed from split ring resonator based on polyethylene terephthalate

Author

Zhanyi Wu, Pujing Zhang, and Ziye Zhang

Subjects
Materials science, Terahertz radiation, business.industry, Metamaterial, Resonance, Dielectric, Split-ring resonator, chemistry.chemical_compound, Dipole, Transmission (telecommunications), chemistry, Polyethylene terephthalate, Optoelectronics, business
Abstract

We demonstrate the active control of resonant frequency in terahertz (THz) metamaterial comprised of split ring resonator arrays (SRRs). It is found that the introduction of different substrates can greatly modify the sensing capabilities of the SRRs structure, i.e., the SRRs designed on PET (polyethylene terephthalate) is more sensitive to THz wave accompanied with higher resonance frequency as well as wider non-resonant region. Furthermore, our simulated findings indicate that THz response sensitivity can be distinctly tuned by changing the gap of SRRs on PET. The mechanism of inductance-capacitance (LC) resonance and dipole resonance is exploited to explain the varied THz transmission responses. Our work infers that the SRRs structure based on PET with low dielectric constant is a significantly better option for biological and chemical sensing applications.

Published
2020

22. Study on terahertz transmission spectrum of single and double split ring resonators integrated with MoS2

Author

Ziye Zhang, Zhanyi Wu, and Pujing Zhang

Subjects
Materials science, Terahertz radiation, business.industry, Physics::Optics, Resonance, Metamaterial, Low frequency, Ring (chemistry), Split-ring resonator, chemistry.chemical_compound, Resonator, chemistry, Optoelectronics, business, Molybdenum disulfide
Abstract

Nowadays, the combination of metamaterials and molybdenum disulfide (MoS2) plays more and more important roles, due to its broad applications in many areas. Here, we propose a novel hybrid structure for terahertz (THz) wave manipulation with the integration of MoS2 layer and metamaterials consisting of split ring resonators (SRRs) arrays on Si substrate. Compared with the simulation results of single ring resonator and double ring resonators, it is found that the original dual-mode resonance transforms four mode resonance after inserting the inner ring. When the inner ring is rotated, the multi-mode resonance does not change. The resonance intensity decreases and the frequency moves to the low frequency with the red-shift effect, when MoS2 is added. The hybrid MoS2-SRRs structure THz modulator has multi-mode resonance, and the interaction between SRRs and MoS2 is revealed through the analysis of multi-mode resonance.

Published
2020

23. Tunable terahertz transmission behaviors and coupling mechanism in hybrid MoS2 metamaterials

Author

Cunlin Zhang, Yuwang Deng, Pujing Zhang, Qingli Zhou, and Wanlin Liang

Subjects
Coupling (electronics), Mechanism (engineering), Materials science, Transmission (telecommunications), business.industry, Terahertz radiation, General Physics and Astronomy, Optoelectronics, Metamaterial, business
Abstract

A hybrid metamaterial with the integration of molybdenum disulfide (MoS2) overlayer is proposed to manipulate the terahertz (THz) wave. The simulated results indicate that the introduction of MoS2 layer could significantly modify the resonant responses with large resonance red-shift and bandwidth broadening due to the depolarization field effect, especially for the structure on the small permitivity substrate. Additionally, the wide-band modulator in off-resonant region and a switch effect at resonance can be achieved by varying the conductivity of MoS2 layer. Further theoretical calculations based on the Lorentz coupling model are consistent with the simulated results, explicating the response behaviors originate from the coupling between MoS2 overlayer and the metastructure. Our results could provide a possibility for active control THz modulator and switchable device based on the MoS2 overlayer and advance the understanding of the coupling mechanism in hybrid structures.

Published
2022

24. Dynamical Mechanism of Incubator Industrial Base Based on Secondary Incubating

Author

Pujing Zhang, Liyan Tang, and Jing Zhang

Subjects
Engineering, business.industry, Incubator, Operations management, Small to medium enterprises, Base (topology), business, Manufacturing engineering
Abstract

This paper analyzes the functionality of incubator industrial base and the secondary incubation progress based on the definition of secondary incubator. And then the dynamical factors of incubator industrial base are systematically analyzed in relation to the forming and developing stages of incubator industrial base. At last it builds a model of dynamical mechanism of incubator industrial base, and moreover, the dynamical mechanism is further researched.

Published
2010

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