Your search keyword '"Daehee Seol"' showing total 14 results

1. Mixed Triboelectric and Flexoelectric Charge Transfer at the Nanoscale

Author

Huimin Qiao, Pin Zhao, Owoong Kwon, Ahrum Sohn, Fangping Zhuo, Dong‐Min Lee, Changhyo Sun, Daehee Seol, Daesu Lee, Sang‐Woo Kim, and Yunseok Kim

Subjects

atomic force microscopy, charge transfer, flexoelectricity, triboelectricity, Science

Abstract

Abstract The triboelectric effect is a ubiquitous phenomenon in which the surfaces of two materials are easily charged during the contact‐separation process. Despite the widespread consequences and applications, the charging mechanisms are not sufficiently understood. Here, the authors report that, in the presence of a strain gradient, the charge transfer is a result of competition between flexoelectricity and triboelectricity, which could enhance charge transfer during triboelectric measurements when the charge transfers of both effects are in the same direction. When they are in the opposite directions, the direction and amount of charge transfer could be modulated by the competition between flexoelectric and triboelectric effects, which leads to a distinctive phenomenon, that is, the charge transfer is reversed with varying forces. The subsequent results on the electrical power output signals from the triboelectrification support the proposed mechanism. Therefore, the present study emphasizes the key role of the flexoelectric effect through experimental approaches, and suggests that both the amount and direction of charge transfer can be modulated by manipulating the mixed triboelectric and flexoelectric effects. This finding may provide important information on the triboelectric effect and can be further extended to serve as a guideline for material selection during a nanopatterned device design.

Published

2021

2. Recent Progress in the Nanoscale Evaluation of Piezoelectric and Ferroelectric Properties via Scanning Probe Microscopy

Author

Owoong Kwon, Daehee Seol, Huimin Qiao, and Yunseok Kim

Subjects

conductive atomic force microscopy, ferroelectricity, piezoelectricity, piezoresponse force microscopy, scanning probe microscopy, Science

Abstract

Abstract Piezoelectric and ferroelectric materials have garnered significant interest owing to their excellent physical properties and multiple potential applications. Accordingly, the need for evaluating piezoelectric and ferroelectric properties has also increased. The piezoelectric and ferroelectric properties are evaluated macroscopically using laser interferometers and polarization–electric field loop measurements. However, as the research focus is shifted from bulk to nanosized materials, scanning probe microscopy (SPM) techniques have been suggested as an alternative approach for evaluating piezoelectric and ferroelectric properties. In this Progress Report, the recent progress on the nanoscale evaluation of piezoelectric and ferroelectric properties of diverse materials using SPM‐based methods is summarized. Among the SPM techniques, the focus is on recent studies that are related to piezoresponse force microscopy and conductive atomic force microscopy; further, the utilization of these two modes to understand piezoelectric and ferroelectric properties at the nanoscale level is discussed. This work can provide guidelines for evaluating the piezoelectric and ferroelectric properties of materials based on SPM techniques.

Published

2020

3. Recent Progress in the Nanoscale Evaluation of Piezoelectric and Ferroelectric Properties via Scanning Probe Microscopy

Author

Yunseok Kim, Daehee Seol, Owoong Kwon, and Huimin Qiao

Subjects

Materials science, General Chemical Engineering, General Physics and Astronomy, Medicine (miscellaneous), scanning probe microscopy, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), law.invention, Scanning probe microscopy, law, General Materials Science, lcsh:Science, Nanoscopic scale, Progress Report, piezoelectricity, General Engineering, Conductive atomic force microscopy, 021001 nanoscience & nanotechnology, Laser, conductive atomic force microscopy, Ferroelectricity, Piezoelectricity, ferroelectricity, 0104 chemical sciences, Piezoresponse force microscopy, lcsh:Q, 0210 nano-technology, Material properties, piezoresponse force microscopy

Abstract

Piezoelectric and ferroelectric materials have garnered significant interest owing to their excellent physical properties and multiple potential applications. Accordingly, the need for evaluating piezoelectric and ferroelectric properties has also increased. The piezoelectric and ferroelectric properties are evaluated macroscopically using laser interferometers and polarization–electric field loop measurements. However, as the research focus is shifted from bulk to nanosized materials, scanning probe microscopy (SPM) techniques have been suggested as an alternative approach for evaluating piezoelectric and ferroelectric properties. In this Progress Report, the recent progress on the nanoscale evaluation of piezoelectric and ferroelectric properties of diverse materials using SPM‐based methods is summarized. Among the SPM techniques, the focus is on recent studies that are related to piezoresponse force microscopy and conductive atomic force microscopy; further, the utilization of these two modes to understand piezoelectric and ferroelectric properties at the nanoscale level is discussed. This work can provide guidelines for evaluating the piezoelectric and ferroelectric properties of materials based on SPM techniques., Piezoelectric and ferroelectric materials have been of significant interest owing to their remarkable physical properties. This Progress Report summarizes the recent advances in the nanoscale evaluation of piezoelectric and ferroelectric properties of diverse materials using approaches based on scanning probe microscopy.

Published

2020

4. Room Temperature Ferroelectric Ferromagnet in 1D Tetrahedral Chain Network

Author

Daehee Seol, Sungkyun Park, Amit Khare, Yoon Seok Oh, Jaejun Yu, Woo Seok Choi, Tae Yoon Lee, Kyeong Tae Kang, Seunghun Kang, Jaekwang Lee, Jong Seok Lee, Chang Jae Roh, J. D. Lim, Kyoungjun Lee, Hiromichi Ohta, Seung Chul Chae, Jun Han Lee, Yunseok Kim, Jiwoong Kim, and Taewon Min

Subjects

Condensed Matter - Materials Science, Materials science, Condensed matter physics, Magnetism, Mechanical Engineering, Point reflection, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Ionic bonding, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Ferroelectricity, 0104 chemical sciences, Ferromagnetism, Mechanics of Materials, Tetrahedron, engineering, Brownmillerite, General Materials Science, 0210 nano-technology, Perovskite (structure)

Abstract

Ferroelectricity occurs in crystals with broken spatial inversion symmetry. In conventional perovskite oxides, concerted ionic displacements within a three-dimensional network of transition metal-oxygen polyhedra (MOx) manifest spontaneous polarization. Meanwhile, some two-dimensional networks of MOx can foster geometric ferroelectricity with magnetism, owing to the distortion of the polyhedra. Because of the fundamentally different mechanism of ferroelectricity in a two-dimensional network, one can further challenge an uncharted mechanism of ferroelectricity in a one-dimensional channel of MOx and estimate its feasibility. This communication presents ferroelectricity and coupled ferromagnetism in a one-dimensional FeO4 tetrahedral chain network of a brownmillerite SrFeO2.5 epitaxial thin film. The result provides a new paradigm for designing low-dimensional MOx networks, which is expected to benefit the realization of macroscopic ferro-ordering materials including ferroelectric ferromagnets., 28 pages, 1 table, 3 figures, 5 supplementary figures

Published

2019

5. Ferroelectric polarization rotation in order-disorder-type LiNbO3 thin films

Author

Yunseok Kim, Seunghun Kang, Ahmed Yousef Mohamed, Woo Seok Choi, Hu Young Jeong, Seunggyo Jeong, Young-Min Kim, Sungkyun Park, Deok-Yong Cho, Tae Sup Yoo, Chang Jae Roh, Daehee Seol, Sang A Lee, Jiwoong Kim, Tom Wu, Ji Young Jo, Jong Seok Lee, Xinwei Guan, and Jong-Seong Bae

Subjects

Materials science, Condensed matter physics, Point reflection, Second-harmonic generation, FOS: Physical sciences, 02 engineering and technology, Dielectric, Applied Physics (physics.app-ph), Physics - Applied Physics, 021001 nanoscience & nanotechnology, Polarization (waves), 01 natural sciences, Ferroelectricity, Piezoelectricity, Condensed Matter::Materials Science, Vacancy defect, 0103 physical sciences, General Materials Science, Hexagonal lattice, 010306 general physics, 0210 nano-technology

Abstract

The direction of ferroelectric polarization is prescribed by the symmetry of the crystal structure. Therefore, rotation of the polarization direction is largely limited, despite the opportunity it offers in understanding important dielectric phenomena such as piezoelectric response near the morphotropic phase boundaries and practical applications such as ferroelectric memory. In this study, we report the observation of continuous rotation of ferroelectric polarization in order-disorder type LiNbO3 thin films. The spontaneous polarization could be tilted from an out-of-plane to an in-plane direction in the thin film by controlling the Li vacancy concentration within the hexagonal lattice framework. Partial inclusion of monoclinic-like phase is attributed to the breaking of macroscopic inversion symmetry along different directions and the emergence of ferroelectric polarization along the in-plane direction., 38 pages, 12 figures

Published

2018

6. Nanoscale mapping of electromechanical response in ionic conductive ceramics with piezoelectric inclusions.

Author

Daehee Seol, Hosung Seo, Jesse, Stephen, and Yunseok Kim

Subjects

*ELECTRONIC ceramics, *PIEZORESPONSE force microscopy, *MICROMETRY, *CRYSTALLOGRAPHY, *ELECTROCHEMICAL analysis

Abstract

Electromechanical (EM) response in ion conductive ceramics with piezoelectric inclusions was spatially explored using strain-based atomic force microscopy. Since the sample is composed of two dominant phases of ionic and piezoelectric phases, it allows us to explore two different EM responses of electrically induced ionic response and piezoresponse over the same surface. Furthermore, EM response of the ionic phase, i.e., electrochemical strain, was quantitatively investigated from the comparison with that of the piezoelectric phase, i.e., piezoresponse. These results could provide additional information on the EM properties, including the electrochemical strain at nanoscale. [ABSTRACT FROM AUTHOR]

Published

2015

7. Direct probing of polarization charge at nanoscale level

Author

Yunseok Kim, Dongkyu Lee, Marin Alexe, Hee Han, Woo Lee, Stephen Jesse, Ionela Lindfors-Vrejoiu, Owoong Kwon, Sergei V. Kalinin, Ho Nyung Lee, and Daehee Seol

Subjects

010302 applied physics, Materials science, T1, business.industry, Mechanical Engineering, Charge (physics), Nanotechnology, 02 engineering and technology, Conductive atomic force microscopy, 021001 nanoscience & nanotechnology, 01 natural sciences, Ferroelectricity, Piezoresponse force microscopy, Parasitic capacitance, Mechanics of Materials, 0103 physical sciences, Optoelectronics, General Materials Science, Thin film, 0210 nano-technology, Polarization (electrochemistry), business, Nanoscopic scale, QC

Abstract

Ferroelectric materials possess spontaneous polarization that can be used for multiple applications. Owing to a long-term development of reducing the sizes of devices, the preparation of ferroelectric materials and devices is entering the nanometer-scale regime. Accordingly, to evaluate the ferroelectricity, there is a need to investigate the polarization charge at the nanoscale. Nonetheless, it is generally accepted that the detection of polarization charges using a conventional conductive atomic force microscopy (CAFM) without a top electrode is not feasible because the nanometer-scale radius of an atomic force microscopy (AFM) tip yields a very low signal-to-noise ratio. However, the detection is unrelated to the radius of an AFM tip and, in fact, a matter of the switched area. In this work, the direct probing of the polarization charge at the nanoscale is demonstrated using the positive-up-negative-down method based on the conventional CAFM approach without additional corrections or circuits to reduce the parasitic capacitance. The polarization charge densities of 73.7 and 119.0 µC cm−2 are successfully probed in ferroelectric nanocapacitors and thin films, respectively. The obtained results show the feasibility of the evaluation of polarization charge at the nanoscale and provide a new guideline for evaluating the ferroelectricity at the nanoscale.

Published

2017

8. Non-piezoelectric effects in piezoresponse force microscopy

Author

Daehee Seol, Bora Kim, and Yunseok Kim

Subjects

010302 applied physics, Condensed Matter - Materials Science, Cantilever, Materials science, business.industry, Atomic force microscopy, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Piezoelectricity, Ferroelectricity, Piezoresponse force microscopy, 0103 physical sciences, Optoelectronics, General Materials Science, 0210 nano-technology, business, Nanoscopic scale

Abstract

Piezoresponse force microscopy (PFM) has been used extensively for exploring nanoscale ferro/piezoelectric phenomena over the past two decades. The imaging mechanism of PFM is based on the detection of the electromechanical (EM) response induced by the inverse piezoelectric effect through the cantilever dynamics of an atomic force microscopy. However, several non-piezoelectric effects can induce additional contributions to the EM response, which often lead to a misinterpretation of the measured PFM response. This review aims to summarize the non-piezoelectric origins of the EM response that impair the interpretation of PFM measurements. We primarily discuss two major non-piezoelectric origins, namely, the electrostatic effect and electrochemical strain. Several approaches for differentiating the ferroelectric contribution from the EM response are also discussed. The review suggests a undamental guideline for the proper utilization of the PFM technique, as well as for achieving a reasonable interpretation of observed PFM responses., 46 pages, 14 figures

Published

2017

9. Determination of ferroelectric contributions to electromechanical response by frequency dependent piezoresponse force microscopy

Author

Yunseok Kim, Shinbuhm Lee, Ho Nyung Lee, O.V. Varenyk, Anna N. Morozovska, Seongjae Park, and Daehee Seol

Subjects

010302 applied physics, Multidisciplinary, Materials science, Condensed matter physics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Bioinformatics, 01 natural sciences, Ferroelectricity, Article, Hysteresis, Amplitude, Piezoresponse force microscopy, 0103 physical sciences, 0210 nano-technology, Nanoscopic scale

Abstract

Hysteresis loop analysis via piezoresponse force microscopy (PFM) is typically performed to probe the existence of ferroelectricity at the nanoscale. However, such an approach is rather complex in accurately determining the pure contribution of ferroelectricity to the PFM. Here, we suggest a facile method to discriminate the ferroelectric effect from the electromechanical (EM) response through the use of frequency dependent ac amplitude sweep with combination of hysteresis loops in PFM. Our combined study through experimental and theoretical approaches verifies that this method can be used as a new tool to differentiate the ferroelectric effect from the other factors that contribute to the EM response.

Published

2016

10. Probing of multiple magnetic responses in magnetic inductors using atomic force microscopy

Author

Yunseok Kim, Hosung Seo, Young-Hwan Yoon, Daehee Seol, Mi Yang Kim, and Seongjae Park

Subjects

010302 applied physics, Multidisciplinary, Materials science, Magnetic domain, Atomic force microscopy, 02 engineering and technology, 021001 nanoscience & nanotechnology, Inductor, computer.software_genre, 01 natural sciences, Article, Computational physics, law.invention, law, Electromagnetic coil, 0103 physical sciences, Eddy current, Data mining, Current (fluid), Magnetic force microscope, 0210 nano-technology, computer, Nanoscopic scale

Abstract

Even though nanoscale analysis of magnetic properties is of significant interest, probing methods are relatively less developed compared to the significance of the technique, which has multiple potential applications. Here, we demonstrate an approach for probing various magnetic properties associated with eddy current, coil current and magnetic domains in magnetic inductors using multidimensional magnetic force microscopy (MMFM). The MMFM images provide combined magnetic responses from the three different origins, however, each contribution to the MMFM response can be differentiated through analysis based on the bias dependence of the response. In particular, the bias dependent MMFM images show locally different eddy current behavior with values dependent on the type of materials that comprise the MI. This approach for probing magnetic responses can be further extended to the analysis of local physical features.

Published

2016

11. Ferroelectric-like hysteresis loop originated from non-ferroelectric effects.

Author

Bora Kim, Daehee Seol, Shinbuhm Lee, Ho Nyung Lee, and Yunseok Kim

Subjects

*HYSTERESIS loop, *FERROELECTRIC materials, *PIEZORESPONSE force microscopy, *PIEZOELECTRIC devices, *ELECTROSTATIC interaction

Abstract

Piezoresponse force microscopy (PFM) has provided advanced nanoscale understanding and analysis of ferroelectric and piezoelectric properties. In PFM-based studies, electromechanical strain induced by the converse piezoelectric effect is probed and analyzed as a PFM response. However, electromechanical strain can also arise from several non-piezoelectric origins that may lead to a misinterpretation of the observed response. Among them, electrostatic interaction can significantly affect the PFM response. Nonetheless, previous studies explored solely the influence of electrostatic interaction on the PFM response under the situation accompanied with polarization switching. Here, we show the influence of the electrostatic interaction in the absence of polarization switching by using unipolar voltage sweep. The obtained results reveal that the electromechanical neutralization between piezoresponse of polarization and electrostatic interaction plays a crucial role in the observed ferroelectric-like hysteresis loop despite the absence of polarization switching. Thus, our work can provide a basic guideline for the correct interpretation of the hysteresis loop in PFM-based studies. [ABSTRACT FROM AUTHOR]

Published

2016

12. Dynamic mechanical control of local vacancies in NiO thin films.

Author

Daehee Seol, Sang Mo Yang, Stephen Jesse, Minseok Choi, Inrok Hwang, Taekjib Choi, Bae Ho Park, Sergei V Kalinin, and Yunseok Kim

Subjects

*THIN films, *TIDAL forces (Mechanics), *IONIC liquids

Abstract

The manipulation of local ionic behavior via external stimuli in oxide systems is of great interest because it can help in directly tuning material properties. Among external stimuli, mechanical force has attracted intriguing attention as novel stimulus for ionic modulation. Even though effectiveness of mechanical force on local ionic modulation has been validated in terms of static effect, its real-time i.e., dynamic, behavior under an application of the force is barely investigated in spite of its crucial impact on device performance such as force or pressure sensors. In this study, we explore dynamic ionic behavior modulated by mechanical force in NiO thin films using electrochemical strain microscopy (ESM). Ionically mediated ESM hysteresis loops were significantly varied under an application of mechanical force. Based on these results, we were able to investigate relative relationship between the force and voltage effects on ionic motion and, further, control effectively ionic behavior through combination of mechanical and electrical stimuli. Our results can provide comprehensive information on the effect of mechanical forces on ionic dynamics in ionic systems. [ABSTRACT FROM AUTHOR]

Published

2018

13. Evenly transferred single-layered graphene membrane assisted by strong substrate adhesion.

Author

Seongjae Park, Hoijoon Kim, Daehee Seol, Taejin Park, Mirine Leem, Hyunwoo Ha, Hyesung An, Hyun You Kim, Seong-Jun Jeong, Seongjun Park, Hyoungsub Kim, and Yunseok Kim

Subjects

GRAPHENE, ADHESION, VAN der Waals forces

Abstract

We explored the transfer of a single-layered graphene membrane assisted by substrate adhesion. A relatively larger adhesion force was measured on the SiO2 substrate compared with its van der Waals contribution, which is expected to result from the additional contribution of the chemical bonding force. Density functional theory calculations verified that the strong adhesion force was indeed accompanied by chemical bonding. The transfer of single-layered graphene and subsequent deposition of the dielectric layer were best performed on the SiO2 substrate exhibiting a larger adhesion force. This study suggests the selection and/or modification of the underlying substrate for proper transfer of graphene as well as other 2D materials similar to graphene. [ABSTRACT FROM AUTHOR]

Published

2017

14. Nanosculpting of complex oxides by massive ionic transfer.

Author

Daehee Seol, Stephen Jesse, Sang-Joon Park, Woo Lee, Sergei V Kalinin, and Yunseok Kim

Subjects

*ATOMIC force microscopy, *TITANIUM dioxide, *SCANNING probe microscopy

Abstract

Scanning probe microscopy (SPM)-based approaches have been extensively studied as methods to control the structure and properties of materials on the nanoscale. In many cases, the SPM probe is physically utilized to control structure and properties. In addition to physical modulation, it has been reported that voltage can be effectively used to modulate electrochemical phenomena on the sample surface. These studies suggest that electrochemical modulation of the structure and properties is possible by applying a voltage. Herein, in order to demonstrate voltage induced modulation of surface structure, we explored surface nanosculpting by creating electrochemically induced pits on the surface of TiO2 thin films through the application of voltage using the atomic force microscope tip. Using a unipolar negative voltage sweep, pits were successfully generated. Further, the electric potential distribution was simulated to unravel the relationship between the pit volume and the magnitude of the applied voltage. Finally, surface protrusion induced by positive voltage sweep was also observed to elucidate the complete process of electrochemically induced surface modulation. These results can offer fundamental information for understanding how surface structure can be modulated by electrochemical phenomena. [ABSTRACT FROM AUTHOR]

Published

2016