Yungui Ma scite author profile

We demonstrated an ultra-broadband, polarization-insensitive, and wide-angle metamaterial absorber for terahertz (THz) frequencies using arrays of truncated pyramid unit structure made of metal-dielectric multilayer composite. In our design, each sub-layer behaving as an effective waveguide is gradually modified in their lateral width to realize a wideband response by effectively stitching together the resonance bands of different waveguide modes. Experimentally, our five layer sample with a total thickness 21 μm is capable of producing a large absorptivity above 80% from 0.7 to 2.3 THz up to the maximum measurement angle 40°. The full absorption width at half maximum of our device is around 127%, greater than those previously reported for THz frequencies. Our absorber design has high practical feasibility and can be easily integrated with the semiconductor technology to make high efficient THz-oriented devices.

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Experimental Demonstration of a Multiphysics Cloak: Manipulating Heat Flux and Electric Current Simultaneously

Liu

et al. 2014

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In past years, triggered by their successful realizations in electromagnetics, invisible cloaks have experienced rapid development and have been widely pursued in many different fields, though so far only for a single physical system. In this letter we made an unprecedented experimental attempt to show a multidisciplinary framework designed on the basis of two different physical equations. The proposed structure has the exceptional capability to simultaneously control two different physical phenomena according to the predetermined evolution scenarios. As a proof of concept, we implemented an electric--thermal bifunctional device that can guide both electric current and heat flux "across" a strong 'scatter' (air cavity) and restore their original diffusion directions as if nothing exists along the paths, thus rending dual cloaking effects for objects placed inside the cavity. This bifunctional cloaking performance is also numerically verified for a point--source nonuniform excitation. Our results and the fabrication technique presented here will help broaden the current research scope for multiple disciplines and may pave a prominent way to manipulate multiple flows and create new functional devices, e.g., for on--chip applications. The state and evolution of one physical phenomenon (wave or flux) are fundamentally determined by their manner of interaction with surrounding matters abiding different physical theorems or laws, mathematically described by different characteristic equations, such as Maxwell's equations for electromagnetic (EM) waves or conduction equation for current/heat flow. According to Einstein's theory of general relativity, these differential equations representing basic physical laws will experience formality invariance (but with their parametrical coefficients changed) if transformed among different coordinate systems [1,2]. The covariance of free--space Maxwell's equations successfully explains the constant nature of light velocity in different inertia systems [3] and also led to the important conclusion that wave behaviors in curved empty geometries are equivalent to electromagnetism in a medium [4,5]. In 2006, Pendry and Leonhardt developed this important conception on coordinate mapping with their independent proposals that light could be bent to realize invisible cloaking [6,7], which was quickly verified in the experiment [8]. This scientific milestone on cloaking has triggered enormous research enthusiasm on transformation optics (TO) and their technological applications associated with the development of metamaterials [9,10], which has greatly contributed to the advancement of modern electromagnetism [11]. In past years people working in this field were mostly endeavored to improve the practicality of EM cloaks with various versions of designing algorithms and have successfully demonstrated the cloaking effect covering nearly the whole frequency range from static to visible light [12--21]. In addition to EM cloaks, other instrumental EM devices with functionalities deemed impossible ...

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High-performance silicon−graphene hybrid plasmonic waveguide photodetectors beyond 1.55 μm

et al. 2020

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A fast silicon-graphene hybrid plasmonic waveguide photodetectors beyond 1.55 μm is proposed and realized by introducing an ultra-thin wide silicon-on-insulator ridge core region with a narrow metal cap. With this novel design, the light absorption in graphene is enhanced while the metal absorption loss is reduced simultaneously, which helps greatly improve the responsivity as well as shorten the absorption region for achieving fast responses. Furthermore, metal-graphenemetal sandwiched electrodes are introduced to reduce the metal-graphene contact resistance, which is also helpful for improving the response speed. When the photodetector operates at 2 μm, the measured 3dB-bandwidth is >20 GHz (which is limited by the experimental setup) while the 3dB-bandwith calculated from the equivalent circuit with the parameters extracted from the measured S 11 is as high as ~100 GHz. To the best of our knowledge, it is the first time to report the waveguide photodetector at 2 μm with a 3dB-bandwidth over 20 GHz. Besides, the present photodetectors also work very well at 1.55 μm. The measured responsivity is about 0.4 A/W under a bias voltage of −0.3 V for an optical power of 0.16 mW, while the measured 3dB-bandwidth is over 40 GHz (limited by the test setup) and the 3 dB-bandwidth estimated from the equivalent circuit is also as high as ~100 GHz, which is one of the best results reported for silicon-graphene photodetectors at 1.55 μm.

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A transient thermal cloak experimentally realized through a rescaled diffusion equation with anisotropic thermal diffusivity

et al. 2013

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Transformation optics has made a major contribution to the advancement of modern electromagnetism and related research assisted by the development of metamaterials. In this work, we applied this concept to the thermodynamics using the coordinate transformation to the time-dependent heat diffusion equation to manipulate the heat flux by predefined diffusion paths. Experimentally, we demonstrated a transient thermal cloaking device engineered with effective thermal materials and successfully hid a centimeter-sized vacuum cavity. A rescaled heat equation accounting for all the pertinent parameters of various ingredient materials was proposed to greatly facilitate the fabrication. Our results unambiguously demonstrate the practical possibility of implementing complex transformed thermal media with high accuracy and acquiring several unprecedented thermodynamic functions, which we believe will help to broaden the current research and pave a new path to manipulate heat for novel device applications.

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Observing of the super-Planckian near-field thermal radiation between graphene sheets

Jiang¹,

Du²,

Su³

et al. 2018

Nat Commun

139

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Thermal radiation can be substantially enhanced in the near-field scenario due to the tunneling of evanescent waves. Monolayer graphene could play a vital role in this process owing to its strong infrared plasmonic response, however, which still lacks an experimental verification due to the technical challenges. Here, we manage to make a direct measurement about plasmon-mediated thermal radiation between two macroscopic graphene sheets using a custom-made setup. Super-Planckian radiation with efficiency 4.5 times larger than the blackbody limit is observed at a 430-nm vacuum gap on insulating silicon hosting substrates. The positive role of graphene plasmons is further confirmed on conductive silicon substrates which have strong infrared loss and thermal emittance. Based on these, a thermophotovoltaic cell made of the graphene–silicon heterostructure is lastly discussed. The current work validates the classic thermodynamical theory in treating graphene and also paves a way to pursue the application of near-field thermal management.

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Yungui Ma

Ultra-broadband terahertz metamaterial absorber

Experimental Demonstration of a Multiphysics Cloak: Manipulating Heat Flux and Electric Current Simultaneously

High-performance silicon−graphene hybrid plasmonic waveguide photodetectors beyond 1.55 μm

A transient thermal cloak experimentally realized through a rescaled diffusion equation with anisotropic thermal diffusivity

Observing of the super-Planckian near-field thermal radiation between graphene sheets

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