Your search keyword '"Lee, Hyunseung"' showing total 4 results

1. Effects of the PbBr 2 :PbI 2 Molar Ratio on the Formation of Lead Halide Thin Films, and the Ratio's Application for High Performance and Wide Bandgap Solar Cells.

Author

Sheikh, Md. Abdul Kuddus, Singh, Son, Abdur, Rahim, Lee, Sung-Min, Kim, Jae-Hun, Nam, Ho-Seok, Lee, Hyunseung, and Lee, Jaegab

Subjects

PHOTOVOLTAIC power systems, SOLAR cells, LEAD halides, THIN films, X-ray photoelectron spectroscopy, CRYSTAL grain boundaries

Abstract

We investigate the effects of the molar ratio (x) of PbBr2 on the phases, microstructure, surface morphology, optical properties, and structural defects of mixed lead halides PbI2(1−x)Br2x for use in solar cell devices. Results indicate that as x increased to 0.3, the surface morphology continued to improve, accompanied by the growth of PbI2 grains. This resulted in lead halide films with a very smooth and continuous morphology, including large grains when the film was formed at x = 0.3. In addition, the microstructure changed from (001)-oriented pure PbI2 to a highly (001)-oriented β (PbI2-rich) phase. The plausible mechanism for the enhanced morphology of the lead halide films by the addition of PbBr2 is proposed based on the growth of a Br-saturated lead iodide solid solution. Furthermore, iodine vacancies, identified by X-ray photoelectron spectroscopy, decreased as the ratio of PbBr2 increased. Finally, an electrical analysis of the solar cells was performed by using a PN heterojunction model, revealing that structural defects, such as iodine vacancies and grain boundaries, are the main contributors to the degradation of the performance of pure PbI2-based solar cells (including high leakage, low stability, and high hysteresis), which was significantly improved by the addition of PbBr2. The solar cell fabricated at x = 0.3 in air showed excellent stability and performance. The device lost merely 20% of the initial efficiency of 4.11% after 1500 h without encapsulation. This may be due to the dense microstructure and the reduced structural defects of lead halides formed at x = 0.3. [ABSTRACT FROM AUTHOR]

Published

2022

2. Scalable Synthesis and Electrochemical Properties of Porous Si-CoSi 2 -C Composites as an Anode for Li-ion Batteries.

Author

Seo, Hyungeun, Yang, Hae-Ri, Yang, Youngmo, Kim, Kyungbae, Kim, Sung Hyon, Lee, Hyunseung, and Kim, Jae-Hun

Subjects

LITHIUM-ion batteries, X-ray photoelectron spectroscopy, CHEMICAL processes, ELECTRIC conductivity, POROUS materials, ANODES, MECHANICAL alloying

Abstract

Si-based anodes for Li-ion batteries (LIBs) are considered to be an attractive alternative to graphite due to their higher capacity, but they have low electrical conductivity and degrade mechanically during cycling. In the current study, we report on a mass-producible porous Si-CoSi2-C composite as a high-capacity anode material for LIBs. The composite was synthesized with two-step milling followed by a simple chemical etching process. The material conversion and porous structure were characterized by X-ray diffraction, X-ray photoelectron spectroscopy, and electron microscopy. The electrochemical test results demonstrated that the Si-CoSi2-C composite electrode exhibits greatly improved cycle and rate performance compared with conventional Si-C composite electrodes. These results can be ascribed to the role of CoSi2 and inside pores. The CoSi2 synthesized in situ during high-energy mechanical milling can be well attached to the Si; its conductive phase can increase electrical connection with the carbon matrix and the Cu current collectors; and it can accommodate Si volume changes during cycling. The proposed synthesis strategy can provide a facile and cost-effective method to produce Si-based materials for commercial LIB anodes. [ABSTRACT FROM AUTHOR]

Published

2021

3. Printability and Setting Time of CSA Cement with Na 2 SiO 3 and Gypsum for Binder Jetting 3D Printing.

Author

Na, Okpin, Kim, Kangmin, Lee, Hyunjoo, and Lee, Hyunseung

Subjects

THREE-dimensional printing, GYPSUM, CEMENT, SOLUBLE glass, VISCOSITY, 3-D printers

Abstract

The purpose of this study is to optimize the composition of CSA (calcium sulfoaluminate) cement with sodium silicate (Na2SiO3) and gypsum for binder jetting 3D printing. The preliminary test was carried out with an applicator to decide the proper thickness of one layer before using the 3D printer. A liquid binder was then selected to maintain the shape of the particles. Based on the results, the optimal mixture of dry materials and a liquid activator was derived through various parametric studies. For dry materials, the optimum composition of CSA cement, gypsum, and sand was suggested, and the liquid activator made with sodium silicate solution and VMA (viscosity modified agent) were selected. The setting time with gypsum and sodium silicate was controlled within 30 s. In case of the delayed setting time and the rapid setting mixture, the jetting line was printed thicker or thinner and the accuracy of the printout was degraded. In order to adjust the viscosity of the liquid activator, 10% of the VMA was used in 35% of sodium silicate solution and the viscosity of 200–400 cP was suitable to be sprayed from the nozzle. With this optimal mixture, a prototype of atypical decorative wall was printed, and the compressive strength was measured at about 7 MPa. [ABSTRACT FROM AUTHOR]

Published

2021

4. Structural Characterization and Comparison of Monovalent Cation-Exchanged Zeolite-W.

Author

Seoung, Donghoon, Kim, Hyeonsu, Kim, Pyosang, Song, Chihyun, Lee, Suhyeong, Chae, Sungmin, Lee, Sihyun, Lee, Hyunseung, and Lee, Yongmoon

Subjects

SYNCHROTRONS, X-ray powder diffraction, CRYSTAL symmetry, RIETVELD refinement, MONOVALENT cations, UNIT cell, MARINE natural products

Abstract

We report comparative structural changes of potassium-contained zeolite-W (K-MER, structural analogue of natural zeolite merlinoite) and monovalent extra-framework cation (EFC)-exchanged M-MERs (M = Li+, Na+, Ag+, and Rb+). High-resolution synchrotron X-ray powder diffraction study precisely determines that crystal symmetry of MERs is tetragonal (I4/mmm). Rietveld refinement results reveal that frameworks of all MERs are geometrically composed of disordered Al/Si tetrahedra, bridged by linkage oxygen atoms. We observe a structural relationship between a group of Li-, Na-, and Ag-MER and the group of K- and Rb-MER by EFC radius and position of M(1) site inside double 8-membered ring unit (d8r). In the former group, a-axes decrease reciprocally, c-axes gradually extend by EFC size, and M(1) cations are located at the middle of the d8r. In the latter group, a- and c-axes lengths become longer and shorter, respectively, than axes of the former group, and these axial changes come from middle-to-edge migration of M(1) cations inside the d8r channel. Unit cell volumes of the Na-, Ag-, and K-MER are ca. 2005 Å3, and the volume expansion in the MER series is limited by EFC size, the number of water molecules, and the distribution of extra-framework species inside the MER channel. EFC sites of M(1) and M(2) show disordered and ordered distribution in the former group, and all EFC sites change to disordered distribution after migration of the M(1) site in the latter group. The amount of water molecules and porosities are inversely proportional to EFC size due to the limitation of volume expansion of MERs. The channel opening area of a pau composite building unit and the amount of water molecules are universally related as a function of cation size because water molecules are mainly distributed inside a pau channel. [ABSTRACT FROM AUTHOR]

Published

2020