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1. Compression-sensitive smart windows: inclined pores for dynamic transparency changes

Author

Haomin Chen, Gunho Chang, Tae Hee Lee, Seokhwan Min, Sanghyeon Nam, Donghwi Cho, Kwonhwan Ko, Gwangmin Bae, Yoonseong Lee, Jirou Feng, Heng Zhang, Jang-Kyo Kim, Jonghwa Shin, Jung-Wuk Hong, and Seokwoo Jeon

Subjects
Science
Abstract

Abstract Smart windows, capable of tailoring light transmission, can significantly reduce energy consumption in building services. While mechano-responsive windows activated by strains are promising candidates, they face long-lasting challenges in which the space for the light scatterer’s operation has to be enlarged along with the window size, undermining the practicality. Recent attempts to tackle this challenge inevitably generate side effects with compromised performance in light modulation. Here, we introduce a cuttlefish-inspired design to enable the closing and opening of pores within the 3D porous structure by through-thickness compression, offering opacity and transparency upon release and compression. By changing the activation mode from the conventional in-plane to through-thickness direction, the space requirement is intrinsically decoupled from the lateral size of the scatterer. Central to our design is the asymmetry of pore orientation in the 3D porous structure. These inclined pores against the normal direction increase the opaqueness upon release and improve light modulation sensitivity to compression, enabling transmittance regulation upon compression by an infinitesimal displacement of 50 μm. This work establishes a milestone for smart window technologies and will drive advancements in the development of opto-electric devices.

Published
2024
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2. Ultrawideband electromagnetic metamaterial absorber utilizing coherent absorptions and surface plasmon polaritons based on double layer carbon metapatterns

Author

Yongjune Kim, Pyoungwon Park, Jeongdai Jo, Joonsik Lee, Leekyo Jeong, Jonghwa Shin, Jeong-Hae Lee, and Hak-Joo Lee

Subjects
Medicine, Science
Abstract

Abstract An ultrawideband electromagnetic metamaterial absorber is proposed that consists of double-layer metapatterns optimally designed by the genetic algorithm and printed using carbon paste. By setting the sheet resistance of the intermediate carbon metapattern to a half of that of the top one, it is possible to find an optimal intermediate metapattern that reflects and absorbs the EM wave simultaneously. By adding an absorption resonance via a constructive interference at the top metapattern induced by the reflection from the intermediate one, an ultrawideband absorption can be achieved without increasing the number of layers. Moreover, it is found that the metapatterns support the surface plasmon polaritons which can supply an additional absorption resonance as well as boost the absorption in a broad bandwidth. Based on the simulation, the $$90\%$$ 90 % absorption bandwidth is confirmed from 6.3 to 30.1 GHz of which the fractional bandwidth is 130.77 $$\%$$ % for the normal incidence. The accuracy is verified via measurements well matched with the simulations. The proposed metamaterial absorber could not only break though the conventional concept that the number of layers should be increased to extend the bandwidth but also provide a powerful solution to realize a low-profile, lightweight, and low cost electromagnetic absorber.

Published
2021
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3. Fabrication and characterization of resistive double square loop arrays for ultra-wide bandwidth microwave absorption

Author

Ji-Young Jeong, Je-Ryung Lee, Hyeonjin Park, Joonkyo Jung, Doo-Sun Choi, Eun-chae Jeon, Jonghwa Shin, Jun Sae Han, and Tae-Jin Je

Subjects
Medicine, Science
Abstract

Abstract Microwave absorbers using conductive ink are generally fabricated by printing an array pattern on a substrate to generate electromagnetic fields. However, screen printing processes are difficult to vary the sheet resistance values for different regions of the pattern on the same layer, because the printing process deposits materials at the same height over the entire surface of substrate. In this study, a promising manufacturing process was suggested for engraved resistive double square loop arrays with ultra-wide bandwidth microwave. The developed manufacturing process consists of a micro-end-milling, inking, and planing processes. A 144-number of double square loop array was precisely machined on a polymethyl methacrylate workpiece with the micro-end-milling process. After engraving array structures, the machined surface was completely covered with the developed conductive carbon ink with a sheet resistance of 15 Ω/sq. It was cured at room temperature. Excluding the ink that filled the machined double square loop array, overflowed ink was removed with the planing process to achieve full filled and isolated resistive array patterns. The fabricated microwave absorber showed a small radar cross-section with reflectance less than − 10 dB in the frequency band range of 8.0–14.6 GHz.

Published
2021
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4. Extreme anti-reflection enhanced magneto-optic Kerr effect microscopy

Author

Dongha Kim, Young-Wan Oh, Jong Uk Kim, Soogil Lee, Arthur Baucour, Jonghwa Shin, Kab-Jin Kim, Byong-Guk Park, and Min-Kyo Seo

Subjects
Science
Abstract

Magneto-optic Kerr effect microscopy is useful for dynamic magnetic studies, but is limited by the weak magneto-optical activity. Here, the authors show that extreme anti-reflection result in a Kerr amplitude as large as 20° and enables real-time detection of sub-wavelength magnetic domain reversals.

Published
2020
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5. High‐Contrast Optical Modulation from Strain‐Induced Nanogaps at 3D Heterogeneous Interfaces

Author

Donghwi Cho, Young‐Seok Shim, Jae‐Wook Jung, Sang‐Hyeon Nam, Seokhwan Min, Sang‐Eon Lee, Youngjin Ham, Kwangjae Lee, Junyong Park, Jonghwa Shin, Jung‐Wuk Hong, and Seokwoo Jeon

Subjects
3D nanostructures, air gaps, scatterers, smart windows, stretchable nanocomposites, Science
Abstract

Abstract The realization of high‐contrast modulation in optically transparent media is of great significance for emerging mechano‐responsive smart windows. However, no study has provided fundamental strategies for maximizing light scattering during mechanical deformations. Here, a new type of 3D nanocomposite film consisting of an ultrathin (≈60 nm) Al2O3 nanoshell inserted between the elastomers in a periodic 3D nanonetwork is proposed. Regardless of the stretching direction, numerous light‐scattering nanogaps (corresponding to the porosity of up to ≈37.4 vol%) form at the interfaces of Al2O3 and the elastomers under stretching. This results in the gradual modulation of transmission from ≈90% to 16% at visible wavelengths and does not degrade with repeated stretching/releasing over more than 10 000 cycles. The underlying physics is precisely predicted by finite element analysis of the unit cells. As a proof of concept, a mobile‐app‐enabled smart window device for Internet of Things applications is realized using the proposed 3D nanocomposite with successful expansion to the 3 × 3 in. scale.

Published
2020
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6. Highly tunable refractive index visible-light metasurface from block copolymer self-assembly

Author

Ju Young Kim, Hyowook Kim, Bong Hoon Kim, Taeyong Chang, Joonwon Lim, Hyeong Min Jin, Jeong Ho Mun, Young Joo Choi, Kyungjae Chung, Jonghwa Shin, Shanhui Fan, and Sang Ouk Kim

Subjects
Science
Abstract

Wider control of the refractive index is desired for new optical applications. Here the authors manipulate block copolymer self-assembled nanopatterns via shrinkage in order to control the refractive index. They achieve an index above 3 over 1,000 nm bandwidth.

Published
2016
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7. Broadband giant-refractive-index material based on mesoscopic space-filling curves

Author

Taeyong Chang, Jong Uk Kim, Seung Kyu Kang, Hyowook Kim, Do Kyung Kim, Yong-Hee Lee, and Jonghwa Shin

Subjects
Science
Abstract

The refractive index of natural materials only covers a limited range. Here, Chang et al. use the principle of space-filling curves to construct a mesoscopic crystal with a refractive index greater than 1000 at GHz frequencies. The concept is inherently broadband and scalable.

Published
2016
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9. Spontaneous generation and active manipulation of real-space optical vortices

Author

Dongha Kim, Arthur Baucour, Yun-Seok Choi, Jonghwa Shin, and Min-Kyo Seo

Subjects
Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter::Superconductivity, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Physics::Optics, Optics (physics.optics), Physics - Optics
Abstract

Optical vortices host the orbital nature of photons, which offers an extra degree of freedom in photonic applications. Unlike vortices in other physical entities, optical vortices require structural singularities, which restrict their abilities in terms of dynamic and interactive characteristics. In this study, we present the spontaneous generation and external magnetic field-induced manipulation of an optical vortex and antivortex. A gradient-thickness optical cavity (GTOC) consisting of an Al/SiO2/Ni/SiO2 multilayer structure realised the distinct transition between the trivial and non-trivial topological phases, depending on the magneto-optic effects of the Ni layer. In the non-trivial topological phase, the mathematical singularities generating the optical vortex and antivortex pair in the reflected light existed in the generalised parameter space of the thicknesses of the top and bottom SiO2 layers, which is bijective to the real space of the GTOC. Coupled with the magnetisation, the optical vortex and antivortex in the GTOC experienced an effective spin-orbit interaction and showed topology-dependent dynamics under external magnetic fields. We expect that field-induced engineering of optical vortices will pave the way for the study of topological photonic interactions and their applications., 22 pages, 4 figures

Published
2022

10. Nanoscale physical unclonable function labels based on block copolymer self-assembly

Author

Jang Hwan Kim, Suwan Jeon, Jae Hyun In, Seonho Nam, Hyeong Min Jin, Kyu Hyo Han, Geon Gug Yang, Hee Jae Choi, Kyung Min Kim, Jonghwa Shin, Seung-Woo Son, Seok Joon Kwon, Bong Hoon Kim, and Sang Ouk Kim

Subjects
Electrical and Electronic Engineering, Instrumentation, Electronic, Optical and Magnetic Materials
Abstract

Hardware-based cryptography that exploits physical unclonable functions is required for the secure identification and authentication of devices in the Internet of Things. However, physical unclonable functions are typically based on anticounterfeit identifiers created from randomized microscale patterns or non-predictable fluctuations of electrical response in semiconductor devices, and the validation of an encrypted signature relies on a single-purpose method such as microscopy or electrical measurement. Here we report nanoscale physical unclonable function labels that exploit non-deterministic molecular self-assembly. The labels are created from the multilayer superpositions of metallic nanopatterns replicated from self-assembled block copolymer nanotemplates. Due to the nanoscale dimensions and diverse material options of the system, physical unclonable functions are intrinsically difficult to replicate, robust for authentication and resistant to external disturbance. Multiple, independently operating keys—which use electrical resistance, optical dichroism or Raman signals—can be generated from a single physical unclonable function, offering millisecond-level validation speeds. We also show that our physical unclonable function labels can be used on a range of different surfaces including dollar bills, human hair and microscopic bacteria.

Published
2022

12. Data-driven concurrent nanostructure optimization based on conditional generative adversarial networks

Author

Arthur Baucour, Myungjoon Kim, and Jonghwa Shin

Subjects
Electrical and Electronic Engineering, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Biotechnology
Abstract

Iterative numerical optimization is a ubiquitous tool to design optical nanostructures. However, there can be a significant performance gap between the numerically simulated results, with pristine shapes, and the experimentally measured values, with deformed profiles. We introduce conditional generative adversarial networks (CGAN) into the standard iterative optimization loop to learn process-structure relationships and produce realistic simulation designs based on the fabrication conditions. This ensures that the process-structure mapping is accurate for the specific available equipment and moves the optimization space from the structural parameters (e.g. width, height, and period) to process parameters (e.g. deposition rate and annealing time). We demonstrate this model agnostic optimization platform on the design of a red, green, and blue color filter based on metallic gratings. The generative network can learn complex M-to-N nonlinear process-structure relations, thereby generating simulation profiles similar to the training data over a wide range of fabrication conditions. The CGAN-based optimization resulted in fabrication parameters leading to a realistic design with a higher figure of merit than a standard optimization using pristine structures. This data-driven approach can expedite the design process both by limiting the design search space to a fabrication-accurate subspace and by returning the optimal process parameters automatically upon obtaining the optimal structure design.

Published
2022

14. Photonic topological Lifshitz interfaces

Author

Xianji Piao, Jonghwa Shin, and Namkyoo Park

Subjects
Condensed Matter::Strongly Correlated Electrons, Electrical and Electronic Engineering, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Biotechnology
Abstract

The intrinsic geometry of wavevector diagrams describes electronic or photonic transport at a given energy level. Lifshitz transition is an intriguing example of the topological transition in wavevector diagrams, which plays a critical role in abnormal transport with enhanced magnetoresistance or superconductivity. Here, we develop the spatial analogy of the Lifshitz transition, which provides a comprehensive topological perspective on transverse-spin interface states. We establish the excitation conditions of transverse-spin interface states, which require the “Lifshitz interface” – the interface between different topologies of wavevector diagrams – along with the gap in wavevector diagrams. Based on the detailed analysis of this topological phenomenon with respect to the dimensionality and gaps of wavevector diagrams across the Lifshitz interface, we show distinct parity of transverse spins and power flows in transverse-spin modes. The unique symmetry of interface states realizing Abraham-spin-momentum locking represents the gauge induced by the Lifshitz interface, which provides a novel insight into the Abraham–Minkowski controversy.

Published
2022

15. Highly angle-sensitive and efficient optical metasurfaces with broken mirror symmetry

Author

Nayoung Kim, Myungjoon Kim, Joonkyo Jung, Taeyong Chang, Suwan Jeon, and Jonghwa Shin

Subjects
Electrical and Electronic Engineering, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Biotechnology
Abstract

Optical metasurfaces have great potential to overcome the functional limitations of conventional optical devices. In addition to polarization- or wavelength-multiplexed metasurfaces, angle-multiplexed metasurfaces can provide new degrees of freedom, enabling previously unrealized complex functionality in diverse applications such as LiDAR, augmented reality glasses, and imaging. However, there have been fundamental trade-offs in transmission efficiency and angular sensitivity for practically important paraxial rays. In this paper, we overcome this limitation by breaking mirror symmetries of single-layer metasurface structures. Based on an effective medium theory, we intuitively explain which material parameters affect the sensitivity and efficiency and prove that high sensitivity and high efficiency can be achieved simultaneously by breaking the mirror symmetry. Based on this, we propose optimized metasurfaces for two applications: an angle-multiplexed beam-steering device with up to 93% relative efficiency and an angle-multiplexed metalens array that can break the fundamental resolution–density trade-off of microlens arrays with high efficiency. The proposed angle-selective designs could pave the way for the development of new classes of compact optical devices with novel functions.

Published
2023

16. Mechanoresponsive scatterers for high-contrast optical modulation

Author

Donghwi Cho, Haomin Chen, Jonghwa Shin, and Seokwoo Jeon

Subjects
Electrical and Electronic Engineering, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Biotechnology
Abstract

Smart chromatic materials with optical transmittances that can be modified by light scattering upon external stimuli are attracting extensive interest because of their appealing applications in smart windows, privacy protection, electronic displays, etc. However, the development of these scatterers, which are mostly activated by electric fields, is hindered by their intrinsic energy consumption, slow responses, and poor stability. Recently, mechanoresponsive scatterers based on a strain-driven reconfiguration of the surface or internal structure have emerged, featuring fast responses and a simple composition/fabrication. Because there is no energy consumption to maintain the transparency/opacity, this novel scheme for scatterers holds great promise to break the existing bottleneck. This article presents recent advances in the development of mechanoresponsive scatterers and compares different structural design strategies. The scatterers are categorized into 2D, 3D, and other types according to the dimensions of their functioning structures. The fabrication methods, mechanisms, and relationships between the structural parameters and optical modulating performances are discussed for each category. Next, the potential applications of these scatterers are outlined. Finally, the advantages and disadvantages of the mainstream 2D and 3D categories are summarized, followed by a perspective on future research directions.

Published
2021

19. Universal Metasurfaces for Complete Linear Control of Coherent Light Transmission

Author

Taeyong Chang, Joonkyo Jung, Sang‐Hyeon Nam, Hyeonhee Kim, Jong Uk Kim, Nayoung Kim, Suwan Jeon, Minsung Heo, and Jonghwa Shin

Subjects
Mechanics of Materials, Mechanical Engineering, Physics::Optics, FOS: Physical sciences, General Materials Science, Physics - Optics, Optics (physics.optics)
Abstract

Recent advances in metasurfaces and optical nanostructures have enabled complex control of incident light with optically thin devices. However, it has thus far been unclear whether it is possible to achieve complete linear control of coherent light transmission, i.e., independent control of polarization, amplitude, and phase for both input polarization states, with just a single, thin nanostructure array. Here we prove that it is possible and propose a universal metasurface, a bilayer array of high-index elliptic cylinders, that possesses a complete degree of optical freedom with fully designable chirality and anisotropy. We mathematically show the completeness of achievable light control with corresponding Jones matrices, experimentally demonstrate new types of three-dimensional holographic schemes that were formerly impossible, and present a systematic way of realizing any input-state-sensitive vector linear optical device. Our results unlock previously inaccessible degrees of freedom in light transmission control., Comment: Main text: 30 pages, 5 figures. Supplementary discussion: 12 pages, 4 figures

Published
2022

20. Self-Assembled Nano–Lotus Pod Metasurface for Light Trapping

Author

Mark L. Brongersma, Nayeun Lee, Jonghwa Shin, Sang-Hee Ko Park, Jong Beom Ko, Ju Young Kim, Sang Ouk Kim, and Reehyang Kim

Subjects
Materials science, biology, Lotus, Nanotechnology, Trapping, biology.organism_classification, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, symbols.namesake, Point of delivery, Nano, symbols, Electrical and Electronic Engineering, Spectroscopy, Lithography, Plasmon, Raman scattering, Biotechnology
Published
2021

21. Photolithographic realization of target nanostructures in 3D space by inverse design of phase modulation

Author

Sang-Hyeon Nam, Myungjoon Kim, Nayoung Kim, Donghwi Cho, Myungwoo Choi, Jun Hyung Park, Jonghwa Shin, and Seokwoo Jeon

Subjects
Multidisciplinary
Abstract

The mass production of precise three-dimensional (3D) nanopatterns has long been the ultimate goal of fabrication technology. While interference lithography and proximity-field nanopatterning (PnP) may provide partial solutions, their setup complexity and limited range of realizable structures, respectively, remain the main problems. Here, we tackle these challenges by applying an inverse design to the PnP process. Our inverse design platform based on the adjoint method can efficiently find optimal phase masks for diverse target lattices and motifs. We fabricate a 2D rectangular array of nanochannels, which has not been reported for conventional PnP with normally incident light, as a proof of concept. With further demonstration of material conversion, our work provides versatile platforms for nanomaterial fabrication.

Published
2022

22. Ideal spectral emissivity for radiative cooling of earthbound objects

Author

Suwan Jeon and Jonghwa Shin

Subjects
Convection, Radiative cooling, lcsh:Medicine, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Thermal insulation, Mid-infrared photonics, Radiative transfer, Emissivity, lcsh:Science, Physics, Multidisciplinary, Ideal (set theory), business.industry, Thermoelectric devices and materials, lcsh:R, 021001 nanoscience & nanotechnology, Thermal conduction, 0104 chemical sciences, Computational physics, Atmospheric optics, Heat transfer, lcsh:Q, 0210 nano-technology, business, Green photonics
Abstract

Radiative coolers that can passively cool objects by radiating heat into the outer space have recently received much attention. However, the ultimate limits of their performance as well as their ideal spectral design are still unknown. We present the fundamental lower bound of the temperature of a radiatively cooled object on earth surfaces under general conditions, including non-radiative heat transfer, and the upper bound of the net radiative power density of a radiative cooler as a function of temperature. We derive the ideal spectral emissivities that can realize such bounds and, contrary to common belief, find that the ideal emission window is different from 8 to 13 um and forms disjointed sets of wavelengths, whose width diminishes at lower temperatures. We show that ideal radiative coolers with perfect thermal insulation against conduction and convection have a steady-state temperature of 243.6 K in summer and 180.5 K in winter, much below previously measured values. We also provide the ideal emission window for a single-band emitter and show that this window should be much narrower than that of previous designs if the objective is to build a radiative freezer that can operate in summer. We provide a general guideline for designing spectral emissivity to achieve the maximum temperature drop or the maximum net radiative power density.

Published
2020

23. Broadband metamaterials and metasurfaces: a review from the perspectives of materials and devices

Author

Hyeonjin Park, Jun Hyung Park, Jonghwa Shin, Taeyong Chang, and Joonkyo Jung

Subjects
Physics, QC1-999, Physics::Optics, Metamaterial, Nanotechnology, 02 engineering and technology, metamaterial, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, 010309 optics, metamaterial-based device, 0103 physical sciences, Broadband, broadband absorber, broadband, Electrical and Electronic Engineering, broadband metalens, 0210 nano-technology, constitutive parameter, Biotechnology
Abstract

Metamaterials can possess extraordinary properties not readily available in nature. While most of the early metamaterials had narrow frequency bandwidth of operation, many recent works have focused on how to implement exotic properties and functions over broad bandwidth for practical applications. Here, we provide two definitions of broadband operation in terms of effective material properties and device functionality, suitable for describing materials and devices, respectively, and overview existing broadband metamaterial designs in such two categories. Broadband metamaterials with nearly constant effective material properties are discussed in the materials part, and broadband absorbers, lens, and hologram devices based on metamaterials and metasurfaces are discussed in the devices part.

Published
2020

25. Fabrication and characterization of resistive double square loop arrays for ultra-wide bandwidth microwave absorption

Author

Doo-Sun Choi, Jonghwa Shin, Eun-chae Jeon, Tae-Jin Je, Joonkyo Jung, Hyeonjin Park, Ji-Young Jeong, Je-Ryung Lee, and Jun Sae Han

Subjects
Materials science, Science, 02 engineering and technology, Substrate (printing), Engraving, Article, Engineering, Conductive ink, 0202 electrical engineering, electronic engineering, information engineering, Sheet resistance, Resistive touchscreen, Multidisciplinary, business.industry, 020206 networking & telecommunications, 021001 nanoscience & nanotechnology, visual_art, Screen printing, Metamaterial absorber, visual_art.visual_art_medium, Optoelectronics, Medicine, 0210 nano-technology, business, Microwave
Abstract

Microwave absorbers using conductive ink are generally fabricated by printing an array pattern on a substrate to generate electromagnetic fields. However, screen printing processes are difficult to vary the sheet resistance values for different regions of the pattern on the same layer, because the printing process deposits materials at the same height over the entire surface of substrate. In this study, a promising manufacturing process was suggested for engraved resistive double square loop arrays with ultra-wide bandwidth microwave. The developed manufacturing process consists of a micro-end-milling, inking, and planing processes. A 144-number of double square loop array was precisely machined on a polymethyl methacrylate workpiece with the micro-end-milling process. After engraving array structures, the machined surface was completely covered with the developed conductive carbon ink with a sheet resistance of 15 Ω/sq. It was cured at room temperature. Excluding the ink that filled the machined double square loop array, overflowed ink was removed with the planing process to achieve full filled and isolated resistive array patterns. The fabricated microwave absorber showed a small radar cross-section with reflectance less than − 10 dB in the frequency band range of 8.0–14.6 GHz.

Published
2021

27. Ultrawide meta-film replication process for the mass production of a flexible microwave absorbing meta-surface

Author

Jun Sae Han, Hyeonjin Park, Ji-Young Jeong, Joonkyo Jung, Eun-Ji Gwak, Eun-chae Jeon, Tae-Jin Je, Jonghwa Shin, and Doo-Sun Choi

Subjects
Atomic and Molecular Physics, and Optics
Abstract

The manufacturing process for an ultrawide flexible microwave absorbing meta-surface was developed and optimized experimentally. The developed replication process consists of four main steps to demonstrate double-square loop array meta-structures: (1) mechanical machining of a master mold, (2) soft mold replication and patterned film imprinting, (3) conductive ink blade filling, (4) lamination of a base flexible film to meta sheet. Based on experimental optimization of the individual steps, the manufacturing process for a large-area flexible meta-film was established successfully. The feasibility of a developed process has been demonstrated with a 200 mm × 500 mm fabricated meta-film with a focus on microwave absorbing uniformity in the X-band region.

Published
2022

28. Machine learning assisted synthesis of lithium-ion batteries cathode materials

Author

Chi Hao Liow, Hyeonmuk Kang, Seunggu Kim, Moony Na, Yongju Lee, Arthur Baucour, Kihoon Bang, Yoonsu Shim, Jacob Choe, Gyuseong Hwang, Seongwoo Cho, Gun Park, Jiwon Yeom, Joshua C. Agar, Jong Min Yuk, Jonghwa Shin, Hyuck Mo Lee, Hye Ryung Byon, EunAe Cho, and Seungbum Hong

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science, Electrical and Electronic Engineering
Published
2022

29. Machine Learning Assisted Synthesis of Lithium-Ion Batteries Cathode Materials

Author

Chi Hao Liow, Hyeonmuk Kang, Seunggu Kim, Moony Na, Yongju Lee, Arthur Baucour, Kihoon Bang, Yoonsu Shim, Gyuseong Hwang, Seongwoo Cho, Gun Park, Jiwon Yeom, Joshua C. Agar, Jong Min Yuk, Jonghwa Shin, Hyuck Mo Lee, Hye Ryung Byon, EunAe Cho, and Seungbum Hong

Subjects
History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering
Published
2021

30. Extreme anti-reflection enhanced magneto-optic Kerr effect microscopy

Author

Kab-Jin Kim, Jonghwa Shin, Min-Kyo Seo, Arthur Baucour, Byong-Guk Park, Dong Ha Kim, Soogil Lee, Jong Uk Kim, and Young-Wan Oh

Subjects
Diffraction, Materials science, Kerr effect, Magnetic domain, Science, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, Imaging techniques, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Condensed Matter::Materials Science, Magnetic properties and materials, 0103 physical sciences, Microscopy, 010306 general physics, Nanophotonics and plasmonics, Multidisciplinary, Birefringence, Spintronics, Spins, business.industry, Imaging and sensing, General Chemistry, 021001 nanoscience & nanotechnology, Magneto-optic Kerr effect, Optoelectronics, Magneto-optics, 0210 nano-technology, business
Abstract

Magnetic and spintronic media have offered fundamental scientific subjects and technological applications. Magneto-optic Kerr effect (MOKE) microscopy provides the most accessible platform to study the dynamics of spins, magnetic quasi-particles, and domain walls. However, in the research of nanoscale spin textures and state-of-the-art spintronic devices, optical techniques are generally restricted by the extremely weak magneto-optical activity and diffraction limit. Highly sophisticated, expensive electron microscopy and scanning probe methods thus have come to the forefront. Here, we show that extreme anti-reflection (EAR) dramatically improves the performance and functionality of MOKE microscopy. For 1-nm-thin Co film, we demonstrate a Kerr amplitude as large as 20° and magnetic domain imaging visibility of 0.47. Especially, EAR-enhanced MOKE microscopy enables real-time detection and statistical analysis of sub-wavelength magnetic domain reversals. Furthermore, we exploit enhanced magneto-optic birefringence and demonstrate analyser-free MOKE microscopy. The EAR technique is promising for optical investigations and applications of nanomagnetic systems., Magneto-optic Kerr effect microscopy is useful for dynamic magnetic studies, but is limited by the weak magneto-optical activity. Here, the authors show that extreme anti-reflection result in a Kerr amplitude as large as 20° and enables real-time detection of sub-wavelength magnetic domain reversals.

Published
2020

31. Laser Synthesis of MOF-Derived Ni@Carbon for High-Performance Pseudocapacitors

Author

Hak-Joo Lee, Do Van Lam, Jonghwa Shin, Seong Ok Han, Muhammad Sohail, Hyunuk Kim, Jae-Hyun Kim, Seung-Mo Lee, and Duckjong Kim

Subjects
Materials science, Nanoparticle, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, Nanomaterials, Chemical engineering, chemistry, Phase (matter), Pseudocapacitor, General Materials Science, Metal-organic framework, Particle size, 0210 nano-technology, Carbon
Abstract

Although nanosizing of multiphase pseudocapacitive nanomaterials could dramatically improve their electrochemical properties, a proper way to simultaneously control both the size and the phase of the pseudocapacitive materials is still elusive. Herein, we employed a commercial CO2 laser engraver to do the transformation of a metal-organic framework (MOF-74(Ni)) into size-controlled Ni nanoparticles (4-12 nm) in porous carbon. The produced Ni@carbon hybrid showed the best specific capacitance of 925 F/g with excellent cycling stability when the particle size is 5.5 nm. We found that the highly redox-active α-Ni(OH)2 is more predominantly formed than the less redox-active β-Ni(OH)2 as the particle size becomes smaller. Our results substantiate that various MOFs could be created into high-performance pseudocapacitive materials with the controlled size and phase. It is believed that the laser-based synthesis could also serve as a powerful tool for the discovery of new MOF-derived materials in the field of energy storage and catalysis.

Published
2020

32. Spectrally sharp metasurfaces for wide-angle high extinction of green lasers

Author

Joonkyo Jung, Arthur Baucour, Minsung Heo, Taeyong Chang, Myungjoon Kim, Jonghwa Shin, and Na Young Kim

Subjects
Physics, business.industry, Guided-mode resonance, Bandwidth (signal processing), Physics::Optics, Hyperspectral imaging, Laser, Atomic and Molecular Physics, and Optics, law.invention, Optics, law, Color filter array, business, Plasmon, Structural coloration
Abstract

In optical nanostructures used as artificial resonance-based color filters, there is unfortunate universal trade-off between spectral sharpness and angular tolerance as well as maximum extinction. We rigorously derive the maximum performance bounds of wavelength-rejection filters realized by single-layer plasmonic metasurfaces with a dominant resonance and weak near-field coupling, and propose a multi-layer approach to overcome these single-layer limits and trade-offs. We also present a realistic example that has a narrow full-width-at-half-maximum bandwidth of 24 nm with 10 dB extinction at 532 nm with good angular tolerance up to 60°. The performance of the proposed metasurface is close to the general theoretical bound.

Published
2020

33. Mimicking bio-mechanical principles in photonic metamaterials for giant broadband nonlinearity

Author

Suwan Jeon, Jonghwa Shin, Taeyong Chang, and Minsung Heo

Subjects
Physics, business.industry, Quantitative Biology::Tissues and Organs, Physics::Optics, General Physics and Astronomy, Metamaterial, Nonlinear optics, lcsh:Astrophysics, Thermal conduction, lcsh:QC1-999, Photonic metamaterial, Nonlinear system, Orders of magnitude (time), lcsh:QB460-466, Optoelectronics, Photonics, business, Elastic modulus, lcsh:Physics
Abstract

Microscopic structuring can change the effective properties of a material by several orders of magnitude. An example of this is animal bone, which has an effective elastic modulus that is more than 1,000 times larger than that of the constituent proteins. Here, we propose a broadband-enhancement principle of photonic nonlinearity that has a similar mathematical origin as the bone example. The proposed staggered array metamaterials violate the standard Miller’s rule in nonlinear optics and can enhance the third-order nonlinearity by more than a thousand to a billion times, depending on target operation frequencies. This metamaterial principle also enables manipulation of the individual components of the linear and nonlinear susceptibility tensors. Our biomimetic approach overcomes the fundamental speed-efficiency trade-off in current resonant enhancement schemes, making faster and more efficient all-optical devices possible for 1.55 μm wavelength. The principle is also applicable to ionic diffusion, heat conduction, or other transport problems. Biological materials such as bone show enhanced mechanical properties due to their specific structures, which can inspire new biomimetic materials. Here, a broadband metamaterial exhibiting giant optical nonlinearity is proposed, who’s properties share a mathematical origin with mechanically enhanced biomaterials.

Published
2020

34. Pyramidal Metal–dielectric hybrid-structure geometry with an asymmetric TiO2 layer for broadband light absorption and photocatalytic applications

Author

Jeongyong Kim, Jeong Min Baik, Junha Park, Heon Lee, Hak Jong Choi, Changwon Seo, Jong Kyu Kim, Hyunah Kwon, Junho Jun, Hee Jun Kim, and Jonghwa Shin

Subjects
Photocurrent, Materials science, Renewable Energy, Sustainability and the Environment, Confocal, Nanoparticle, Geometry, 02 engineering and technology, Dielectric, Electron, 021001 nanoscience & nanotechnology, 01 natural sciences, 010309 optics, Metal, visual_art, 0103 physical sciences, visual_art.visual_art_medium, Photocatalysis, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology, Layer (electronics)
Abstract

In this study, a pyramidal metal–dielectric hybrid-structure geometry with high broadband light absorption was prepared and applied as a photoelectrode for solar water oxidation. TiO2 was obliquely deposited on the pyramidal Au film, leading to asymmetrically thick pyramids. With the decoration of Au nanoparticles, the light absorption in the entire UV–visible region significantly increased to > 90%, which was examined by three-dimensional finite-difference time-domain simulations and confirmed by confocal spectral mapping techniques. By the introduction of Ti as the insertion layer, the alignment of bands at the TiO2/Au film interface was tuned, thereby promoting the separation of photogenerated carriers via the efficient transport of electrons to the Au film. This transport led to a remarkable enhancement in the photocurrent density (~0.16 mA/cm2) by 3.4 times compared to that observed for a flat TiO2 layer.

Published
2018

35. Metal Nanoparticle Array as a Tunable Refractive Index Material over Broad Visible and Infrared Wavelengths

Author

Sang-Hee Ko Park, Kyungjae Chung, Yunyong Nam, Ju Young Kim, Reehyang Kim, and Jonghwa Shin

Subjects
Range (particle radiation), Materials science, business.industry, Infrared, Physics::Optics, Resonance, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Wavelength, Optoelectronics, Diamagnetism, Self-assembly, Electrical and Electronic Engineering, 0210 nano-technology, business, Refractive index, Biotechnology
Abstract

Common materials show a limited range of refractive indices over the visible and infrared wavelengths, and their values are not easily tunable once the material is chosen. Here, self-assembled metal nanoparticle arrays are proposed as an effective optical material with a large range of possible refractive indices that are nearly dispersionless over broad wavelength ranges. The material can be potentially fabricated over a large curved surface, and the resulting index is even more tunable by various postprocessing methods, such as material substitution or mechanical stretching. We achieve the highest refractive index of 5.0 at resonance in the visible, exceeding 4.2 over a broadband wavelength regime out of resonance. The key differences from previous studies of self-assembled metal particle arrays are the consideration of the diamagnetic effect and the careful choice of the ligands, which determine the gaps between particles. The sensitivity of the effective index to the size and material of the gap regio...

Published
2018

36. Bimodal phase separated block copolymer/homopolymer blends self-assembly for hierarchical porous metal nanomesh electrodes

Author

Hyeong Min Jin, Young-Gi Lee, Seung Keun Cha, Dong Ok Shin, Jin Young Choi, Jun Soo Kim, Suwan Jeon, Jonghwa Shin, Seong-Jun Jeong, Geon Gug Yang, Sang Ouk Kim, Jang Hwan Kim, Taeyong Chang, Ju Young Kim, Bong Hoon Kim, and Kwang Man Kim

Subjects
Materials science, Nanoporous, Oxide, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Nanomesh, chemistry, Phase (matter), Electrode, General Materials Science, Self-assembly, Thin film, 0210 nano-technology, Microscale chemistry
Abstract

Transparent conducting electrodes (TCEs) are essential components in various optoelectronic devices. Nanostructured metallic thin film is one of the promising candidates to complement current metal oxide films, such as ITO, where high cost rare earth elements have been a longstanding issue. Herein, we present that multiscale porous metal nanomesh thin films prepared by bimodal self-assembly of block copolymer (BCP)/homopolymer blends may offer a new opportunity for TCE. This hierarchical concurrent self-assembly consists of macrophase separation between BCP and homopolymer as well as microphase separation of BCP, and thus provides a straightforward spontaneous production of a highly porous multiscale pattern over an arbitrary large area. Employing a conventional pattern transfer process, we successfully demonstrated a multiscale highly porous metallic thin film with reasonable optical transparency, electro-conductance, and large-area uniformity, taking advantage of low loss light penetration through microscale pores and significant suppression of light reflection at the nanoporous structures. This well-defined controllable bimodal self-assembly can offer valuable opportunities for many different applications, including optoelectronics, energy harvesting, and membranes.

Published
2018

37. Designing air-core photonic-bandgap fibers free of surface modes

Author

Hyang Kyun Kim, Jonghwa Shin, Shanhui fan, Digonnet, Michel J.F., and Kino, Gordon S.

Subjects
Photonics -- Analysis, Crystals -- Analysis, Business, Computers, Electronics, Electronics and electrical industries
Abstract

Using computer simulations, the relationship between the air-core geometry and the presence or absence of the surface modes in air-core PBFs with a triangular hole pattern is analyzed. The absence of surface modes suggested that fibers within the identified ranges of core radii for which the fiber supports no surface modes over the entire wavelength range of the bandgap, should exhibit a very low propagation loss.

Published
2004

38. Colloidal deposition of colored daytime radiative cooling films using nanoparticle-based inks

Author

Ji Yeon Chae, Tae Yeol Yoon, Hangyu Lim, Heon Lee, Soomin Son, Seokhwan Min, Taejong Paik, Dongwoo Chae, Ho Young Woo, and Jonghwa Shin

Subjects
Materials science, Photoluminescence, Physics and Astronomy (miscellaneous), Radiative cooling, business.industry, Nanoparticle, Quantum dot, Heat generation, Emissivity, Optoelectronics, General Materials Science, business, Solution process, Energy (miscellaneous), Visible spectrum
Abstract

In this study, we fabricated easily applicable and processible colored passive daytime radiative cooling (PDRC) films using a solution process with colloidal nanoparticle-based inks. White PDRC films were prepared using hollow silica nanoparticle (H–SiO2)-based colloidal inks and polymeric binders and spray coating. The films have an average reflectivity of 97.2% and emissivity of 94.3% and their temperature is 6.12 °C lower than the ambient temperature during the daytime at outdoor measurement. We also fabricated colored PDRC films by depositing Cu-based quantum dots (QDs) on white PDRC films. The Cu-based QDs partially absorb light in the visible spectrum, allowing yellow, red, and brown colors, that are highly efficient in preventing heat generation. The absorbed energy is converted into another wavelength and emitted as photons based on the photoluminescence effect. Based on the wavelength conversion, the yellow, red, and brown PDRC films can re-emit powers of 14.06, 28.36, and 43.92 W/m2, respectively, resulting in the prevention of heating. The results of outdoor measurements confirm that the temperature of the yellow and red PDRC films decreases by 3.25 and 0.51 °C, respectively, compared with the ambient temperature. Furthermore, we numerically and experimentally determined the daytime cooling performance of two brown PDRC films with different quantum efficiencies. Our results confirm that these easily processable colored PDRC films are more efficient daytime cooling than commercial paint color films on various substrates.

Published
2021

39. Near-atomically flat, chemically homogeneous, electrically conductive optical metasurface

Author

Jong Uk Kim, Minsung Heo, Yong-Hee Lee, Jonghwa Shin, Hwi-Min Kim, Na Young Kim, Suwan Jeon, and Reehyang Kim

Subjects
Electromagnetic field, Materials science, business.industry, Physics::Optics, 02 engineering and technology, Dielectric, 010402 general chemistry, 021001 nanoscience & nanotechnology, Coupled mode theory, 01 natural sciences, 0104 chemical sciences, Wavelength, Electric field, Electrode, Optoelectronics, General Materials Science, Work function, 0210 nano-technology, business, Layer (electronics)
Abstract

Metasurfaces, or two-dimensional arrays of subwavelength-scale structures, can exhibit extraordinary optical properties. However, typical metasurfaces have a bumpy surface morphology that may restrict their practical applications. Here, we propose and demonstrate an optical metasurface that is composed of a thin metallic film, with hidden dielectric structures underneath, and a metal back mirror layer. Exploiting the large difference between the Thomas–Fermi screening length for longitudinal electric fields and the skin depth for transverse electromagnetic fields, the near-atomically flat top surface of the proposed structure can appear homogeneous chemically and electrically but highly inhomogenous optically. The size and shape of the hidden dielectric structures as well as the thickness of the top metallic layer can be tailored to acquire desired optical properties. We performed both theoretical and experimental studies of the proposed metasurface, finding a good agreement between them. This work provides a new platform for ultra-flat optical devices, such as a wavelength selective electrode, diffusive back reflector, meta-lens, and plasmonically enhanced optical biosensors.

Published
2019

40. Directional radiation for optimal radiative cooling

Author

Jonghwa Shin and Suwan Jeon

Subjects
Materials science, Radiative cooling, business.industry, Isotropy, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010309 optics, Optics, Infrared window, 0103 physical sciences, Thermal, Emissivity, Radiative transfer, 0210 nano-technology, Omnidirectional antenna, business, Zenith
Abstract

The omnidirectional radiation scheme has been widely applied to thermal emitters for radiative cooling. We quantitatively illustrate that significant net radiative absorption at high zenith angles limits the performance of such isotropic emitters, and demonstrate that simply cutting off components corresponding to high angles can substantially improve the cooling performance of commonly used isotropic emitter designs. We also present an expression for the ideal directional spectral emissivity at conditions below ambient temperature. As our approach can be applied to coolers with arbitrary surfaces, our results may serve as a basic guideline for designing practical systems with various surfaces, such as rooftops or façades of modern buildings with complicated geometries.

Published
2021

42. Flexible Near-Field Nanopatterning with Ultrathin, Conformal Phase Masks on Nonplanar Substrates for Biomimetic Hierarchical Photonic Structures

Author

Suck Won Hong, Junyong Park, Seok Hee Kang, Hyowook Kim, Seokwoo Jeon, Jonghwa Shin, Taehoon Kim, and Youngwoo Kwon

Subjects
Nanostructure, Materials science, Fabrication, business.industry, General Engineering, General Physics and Astronomy, Near and far field, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Phase (matter), Nano, General Materials Science, Wafer, Nanodot, Photonics, 0210 nano-technology, business
Abstract

Multilevel hierarchical platforms that combine nano- and microstructures have been intensively explored to mimic superior properties found in nature. However, unless directly replicated from biological samples, desirable multiscale structures have been challenging to efficiently produce to date. Departing from conventional wafer-based technology, new and efficient techniques suitable for fabricating bioinspired structures are highly desired to produce three-dimensional architectures even on nonplanar substrates. Here, we report a facile approach to realize functional nanostructures on uneven microstructured platforms via scalable optical fabrication techniques. The ultrathin form (∼3 μm) of a phase grating composed of poly(vinyl alcohol) makes the material physically flexible and enables full-conformal contact with rough surfaces. The near-field optical effect can be identically generated on highly curved surfaces as a result of superior conformality. Densely packed nanodots with submicron periodicity are uniformly formed on microlens arrays with a radius of curvature that is as low as ∼28 μm. Increasing the size of the gratings causes the production area to be successfully expanded by up to 16 in(2). The "nano-on-micro" structures mimicking real compound eyes are transferred to flexible and stretchable substrates by sequential imprinting, facilitating multifunctional optical films applicable to antireflective diffusers for large-area sheet-illumination displays.

Published
2016

43. Two-dimensional metal-dielectric hybrid-structured film with titanium oxide for enhanced visible light absorption and photo-catalytic application

Author

Hak Jong Choi, Hyowook Kim, Sang Hyeon Nam, Heon Lee, Jeong Min Baik, Joonmo Park, Youn Jeong Jang, Hee Jun Kim, Jonghwa Shin, and Jae Sung Lee

Subjects
Photocurrent, Materials science, Renewable Energy, Sustainability and the Environment, business.industry, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Evaporation (deposition), 0104 chemical sciences, Atomic layer deposition, Optoelectronics, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology, business, Absorption (electromagnetic radiation), Layer (electronics), Plasmon, Localized surface plasmon, Visible spectrum
Abstract

Two-dimensional design based on ultrathin TiO2 film for enhanced visible light absorption and photo-catalytic applications is reported, which mainly consists of three layers of gold film, TiO2 film, and gold nanoparticles (Au NPs). The Au and TiO2 films are produced by e-beam evaporation and atomic layer deposition, respectively, in a carefully controlled way to minimize surface roughness. As compared with bare TiO2 film, the Au NPs/TiO2/Au film significantly increased the photoactivity over the entire UV and visible wavelength range. The Au film increases the light absorption in the UV region with TiO2 acting as an impedance-matching layer, while the Au NPs increase the light absorption in the visible region due to the plasmonic resonance effects, increasing the photocurrent under visible light. 3D numerical simulation results suggest that the Au film also plays an important role in enhancing the electrical field intensity at the TiO2 film in contact with Au NPs, by efficient excitation of localized surface plasmon resonances, thereby, contributing to the enhanced photoactivity of the film in the visible range. This simple system may serve as an efficient platform for solar energy conversion utilizing the whole UV-visible range of solar spectrum based on two-dimensional plasmonic photoelectrodes.

Published
2016

44. Data-Driven Synthesis Optimization of Cathode Materials

Author

Seungbum Hong, Yongju Lee, EunAe Cho, Moony Na, Yoon Su Shim, Jiwon Yeom, Jonghwa Shin, Chi Hao Liow, Gun Park, Seongwoo Cho, Hyeonmuk Kang, Hye Ryung Byon, Hyuck Mo Lee, Arthur Baucour, Kihoon Bang, and Jong Min Yuk

Subjects
Materials science, law, Engineering physics, Cathode, Data-driven, law.invention
Abstract

Machine intelligence-based optimizing synthesis parameters offers exciting opportunities in various domain of materials chemistry where large and comprehensive dataset are available. Aiming to construct a “design-to-device” pipeline for battery application with small discrepancy, we adapt machine learning model based on actual experimental data from curated literatures to predict the discharge capacity of Nickel-Manganese-Cobalt (NCM) cathode material. However, missing data is an inherent problem from the results based on literature. Herein we introduce imputation techniques to fill the missing data based. To this end, we show that our model have remarkable predictive capability with the average coefficient of determinant, R2 = 0.84 for training sets. In addition, we also validate our model prediction by the experiments, which yields in less than 8% error. The present work highlights a promising data driven materials synthesis approach, which underpins nonlinear structure-properties relationship for broad range of materials development.

Published
2020

45. Ultralarge Area Sub-10 nm Plasmonic Nanogap Array by Block Copolymer Self-Assembly for Reliable High-Sensitivity SERS

Author

Ju Young Kim, Seung Keun Cha, Bong Hoon Kim, Hyeong Min Jin, Sang Ouk Kim, Minsung Heo, Jang Hwan Kim, Seong-Jun Jeong, Jonghwa Shin, Kyu Hyo Han, and Geon Gug Yang

Subjects
Materials science, business.industry, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, symbols.namesake, Copolymer, symbols, Optoelectronics, General Materials Science, Wafer, Self-assembly, Thin film, 0210 nano-technology, business, Nanoscopic scale, Plasmon, Raman scattering
Abstract

Effective surface enhancement of Raman scattering (SERS) requires strong near-field enhancement as well as effective light collection of plasmonic structures. To this end, plasmonic nanoparticle (NP) arrays with narrow gaps or sharp tips have been suggested as desirable structures. We present a highly dense and uniform Au nanoscale gap array enabled by the customized design of NP shape and arrangement employing block copolymer self-assembly. Block copolymer self-assembly in thin films offers uniform hexagonally packed nanopost template arrays over the entire surface of a 2 in. wafer. Conventional evaporative metal deposition over the nanotemplate surface allows precise geometric control and positional arrangement of metal NPs, constituting tunable, strong plasmonic near-field enhancement particularly at the "hot spots" near interparticular nanoscale gaps. Underlying field distribution has been investigated by a finite-difference time-domain simulation. In the detection of thiophenol, our Au nanogap array shows a remarkable enhancement of Raman intensity greater than ∼10

Published
2018

46. Bright and vivid plasmonic color filters having dual resonance modes with proper orthogonality

Author

Taeyong Chang, Suwan Jeon, Heon Lee, Na Young Kim, Arthur Baucour, Jonghwa Shin, Myungjoon Kim, Hyowook Kim, and Hak Jong Choi

Subjects
Physics, Guided-mode resonance, business.industry, sRGB, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Surface plasmon polariton, Atomic and Molecular Physics, and Optics, 010309 optics, Optics, Gamut, Orthogonality, 0103 physical sciences, RGB color model, Color filter array, 0210 nano-technology, business, Localized surface plasmon
Abstract

The mode orthogonality fundamentally influences the scattering spectra of multi-resonance systems, such as plasmonic color filters. We show that planar arrays of silver nanostructures with dual localized surface plasmon resonances and the right mode orthogonality can function as transmissive RGB color filters with peak transmittances higher than 70%, and color gamut areas larger than 90% of the sRGB space. These are the brightest and most saturated of all designs proposed thus far. We present the Pareto frontier from designs with more than 80% peak transmittance, to designs that achieve a color gamut larger than 120% of the sRGB space.

Published
2018

47. Finite-difference time-domain analysis of increased penetration depth in optical coherence tomography by wavefront shaping

Author

YongKeun Park, Hyun Choi, Jong Uk Kim, and Jonghwa Shin

Subjects
genetic structures, 02 engineering and technology, 01 natural sciences, Light scattering, Article, 010309 optics, Optics, Optical coherence tomography, 0103 physical sciences, medicine, Penetration depth, Physics, Wavefront, medicine.diagnostic_test, business.industry, Scattering, Numerical analysis, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, eye diseases, Reciprocity (electromagnetism), sense organs, 0210 nano-technology, business, Phase conjugation, Biotechnology
Abstract

Multiple scattering in turbid media inhibits optimal light focusing and thus limits the penetration depth in optical coherence tomography (OCT). However, the effects of multiple scattering in a turbid medium can be systematically controlled by shaping the incident wavefront. The authors utilize the reciprocity of Maxwell’s equations and finite-difference time-domain numerical analysis to investigate the ultimate performance bounds of wavefront shaping-OCT under ideal and realistic configurations and compare them with the conventional method. The results reveal that the optimized impinging wavefront significantly enhances the penetration depth of OCT.

Published
2018

48. Transferrable Plasmonic Au Thin Film Containing Sub-20 nm Nanohole Array Constructed via High-Resolution Polymer Self-Assembly and Nanotransfer Printing

Author

Hyowook Kim, Yeon Sik Jung, Kwang Min Baek, Jonghwa Shin, Soonmin Yim, Jong Min Kim, Gun Ho Lee, and Suwan Jeon

Subjects
Materials science, Fabrication, business.industry, Extraordinary optical transmission, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Nanomesh, chemistry, Miniaturization, Optoelectronics, General Materials Science, Thin film, 0210 nano-technology, business, Lithography, Nanoscopic scale, Plasmon
Abstract

The fabrication and characterization of nanoscale hole arrays (NHA) have been extensively performed for a variety of unique characteristics including extraordinary optical transmission phenomenon observed for plasmonic NHAs. Although the size miniaturization and hole densification are strongly required for enhancement of high-frequency optical responses, from a practical point-of-view, it is still not straightforward to manufacture NHA using conventional lithography techniques. Herein, a facile, cost-effective, and transferrable fabrication route for high-resolution and high-density NHA with sub-50 nm periodicity is demonstrated. Solvent-assisted nanotransfer printing with ultrahigh-resolution combined with block copolymer self-assembly is used to fabricate well-defined Si nanomesh master template with 4-fold symmetry. An Au NHA film on quartz substrate is then obtained by thermal-evaporation on the Si master and subsequent transfer of the sample, resulting in NHA structure having a hole with a diameter of 18 nm and a density over 400 holes/μm

Published
2018

50. Signal self-enhancement by coordinated assembly of gold nanoparticles enables accurate one-step-immunoassays

Author

H-Y. Lee, Reehyang Kim, Minsung Heo, J-H. Kwon, J-H. Lee, Jonghwa Shin, Y. J. Cha, H.W. Kim, and Jeewon Lee

Subjects
Analyte, Myocardial Infarction, Metal Nanoparticles, One-Step, 02 engineering and technology, Biosensing Techniques, 010402 general chemistry, 01 natural sciences, Signal, Antigen, medicine, Humans, General Materials Science, Immunoassay, Chromatography, biology, medicine.diagnostic_test, Chemistry, Troponin I, Hepatitis C Antibodies, Nucleocapsid Proteins, 021001 nanoscience & nanotechnology, Hepatitis C, 0104 chemical sciences, Capsid, Colloidal gold, Apoferritins, biology.protein, Gold, Antibody, 0210 nano-technology
Abstract

Current immunoassays are in general performed through time-consuming multi-step procedures that depend on the use of premade signal-producing reporters and often cause assay inaccuracy. Here we report an advanced immunoassay technology that resolves the delayed, complex, and inaccurate assay problems of conventional immunoassays. We have developed an accurate, rapid, simple, and label-free one-step-immunoassay based on the self-enhancement of sensitive immunoassay signals in an assay solution. The nano-scale protein particles (hepatitis B virus capsid and human ferritin heavy chain particles) were genetically engineered to present many well-oriented antibody (or antigen) probes and multi-copies of poly-histidine peptides on their surface, resulting in the construction of 3-dimensional (3D) bioprobes that chemisorb gold ions via coordination bonding and sensitively detect both antigen and antibody analytes. Systematic numerical and experimental analyses show that the signal self-enhancement happens through two coupled reactions under reducing conditions: (1) 3D bioprobe-based sensitive immuno-detection of analytes and (2) coordinated assembly of free and chemisorbed gold nanoparticles around the 3D bioprobe-analyte-associated complexes, which is followed by the quick generation of apparent optical signals. This advanced one-step-immunoassay was successfully applied to diagnostic assays requiring high accuracy and/or speed, i.e. diagnosis of acute myocardial infarction and hepatitis C through detecting a cardiac protein (troponin I) and anti-hepatitis C virus antibodies in patient sera, indicating that it is applicable to the accurate and rapid detection of both antigen and antibody markers of a wide range of diseases.

Published
2017

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