Byung Kyu Yu scite author profile

Ideal electromagnetic (EM) wave absorbers can absorb all incident EM waves, regardless of the incident direction, polarization, and frequency. Absorptance and reflectance are intrinsic material properties strongly correlated with electrical conductivity; hence, achieving perfect absorptance with zero reflectance is challenging. Herein, we present a design strategy for preparing a nearly ideal EM absorber based on a layered metal that maximizes absorption by utilizing multiple internal reflections and minimizes reflection using a monotonic gradient of intrinsic impedance. This approach was experimentally verified using aluminum nanoflakes prepared via topochemical etching of lithium from Li9Al4, and the impedance-graded structure was obtained through the size-based sorting behavior of aluminum nanoflakes sinking in dispersion. Unlike in traditional shielding materials, strong absorption (26.76 dB) and negligible reflectivity (0.04 dB) with a ratio of >103 can be achieved in a 120 μm thick film. Overall, our findings exhibit potential for developing a novel class of antireflective shielding materials.

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Enhancement of thermoelectric properties by effective K-doping and nano precipitation in quaternary compounds of (Pb_1−xK_xTe)_0.70(PbSe)_0.25(PbS)_0.05

Ginting

Lin

Rathnam

et al. 2016

RSC Adv.

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We investigated thermoelectric properties in K-doped quaternary compounds of (Pb1-xKxTe)0.70(PbSe)0.25(PbS)0.05 (x ≤ 0.03). In terms of two valence bands model, we argue that the L-band approaches to the Σ-band with increasing the K-doping concentration resulting in the increase of carrier concentration and effective mass of carrier due to the increase of band degeneracy. The effective K-doping by x = 0.02 and PbS substitution causes high power factor and low thermal conductivity, resulting in the comparatively high ZT value of 1.72 at 800 K. The low thermal conductivity for (Pb0.98K0.020Te)0.70(PbSe)0.25(PbS)0.05 compound is attributed from the lattice distortion and line dislocation in a phase of nano precipitation. By optimizing K-doping and PbS substitution, we achieved the enhancement of practical thermoelectric performance such as average ZTavg = 1.08, engineering (ZT)eng = 0.81, maximum efficiency ηmax = 11.63 %, and output power density Pd = 6.3 W cm -2 , with temperature difference ΔT = 500 K, which has practical applicability in waste heat power generation technologies.

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Filled Skutterudites for Broadband Saturable Absorbers

Lee

Jhon

et al. 2017

Advanced Optical Materials

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Filled skutterudites (FSs), which are known to be good thermoelectric materials, have been intensively investigated in the field of condensed matter physics in the past decades, due to their large variety of electronic and magnetic properties. However, to the best of the authors' knowledge, there has been no previous investigation of the optical properties of FSs. The nonlinear optical saturable absorption property of FSs is investigated in this work for the first time, and the results are reported here. More specifically, Co4Sb12 is chosen as a binary skutterudite system, and indium ions are added as a filling element to form a FS of In0.2Co4Sb12. The material properties are systematically investigated using a series of measurements. Density functional theory calculations of the electronic band structures of InCo4Sb12 and In0.25Co4Sb12 are conducted for better understanding of their energy band structures. It is also demonstrated that a broadband saturable absorber (SA) that can simultaneously operate at 1.5 and 1.9 µm can readily be implemented by depositing particles of In0.2Co4Sb12 onto fiber ferrules. The efficacy of the prepared SA is tested by incorporating the device into rare earth ion‐doped fiber ring cavities, to show its capability for both 1.5 and 1.9 µm operation.

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Byung Kyu Yu

High thermoelectric performance due to nano-inclusions and randomly distributed interface potentials in N-type (PbTe_0.93−xSe_0.07Cl_x)_0.93(PbS)_0.07composites

Layered Aluminum for Electromagnetic Wave Absorber with Near-Zero Reflection

Enhancement of thermoelectric properties by effective K-doping and nano precipitation in quaternary compounds of (Pb_1−xK_xTe)_0.70(PbSe)_0.25(PbS)_0.05

Filled Skutterudites for Broadband Saturable Absorbers

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Byung Kyu Yu

High thermoelectric performance due to nano-inclusions and randomly distributed interface potentials in N-type (PbTe0.93−xSe0.07Clx)0.93(PbS)0.07composites

Layered Aluminum for Electromagnetic Wave Absorber with Near-Zero Reflection

Enhancement of thermoelectric properties by effective K-doping and nano precipitation in quaternary compounds of (Pb1−xKxTe)0.70(PbSe)0.25(PbS)0.05

Filled Skutterudites for Broadband Saturable Absorbers

Contact Info

Product

Resources

About

High thermoelectric performance due to nano-inclusions and randomly distributed interface potentials in N-type (PbTe_0.93−xSe_0.07Cl_x)_0.93(PbS)_0.07composites

Enhancement of thermoelectric properties by effective K-doping and nano precipitation in quaternary compounds of (Pb_1−xK_xTe)_0.70(PbSe)_0.25(PbS)_0.05