Your search keyword '"Sukyung Nam"' showing total 3 results

1. LAPAROENDOSCOPIC SINGLE SITE SURGERY OF EXTREMELY LARGE OVARIAN CYSTS : USE OF ANGIOCATHETER

Author

Sukyung, Nam, primary

Published

2017

2. One-Step Pyro-Synthetic Strategy of LiFePO4-Li3V2(PO4)3 Nanocomposite with a High Energy Density for Lithium-Ion Batteries

Author

Jeonggeun Jo, Jinju Song, Sungjin Kim, Muhammad Hilmy Alfaruqi, Seokhun Kim, Yeoeun Kim, Sukyung Nam, and Jaekook Kim

Abstract

In commercially available Li-ion cells, cobalt-based oxide is utilized as the cathode material, but its high cost and low thermal stability prohibit the large-scale use such as Energy Storage Systems (ESS) and Electric Vehicles (EV). Lithium iron phosphate (LiFePO4) and lithium vanadium phosphate (Li3V2(PO4)3) exhibit good thermal stability and high operating voltage, which make them the most promising cathode candidates so far. Despite of their advantages, LiFePO4 and Li3V2(PO4)3 also have some drawbacks. For instance, LiFePO4 has a stable voltage platform and its cyclic attenuation rate is almost negligible, but its relatively low capacity and low voltage limit its energy density and consequently limits its use. Li3V2(PO4)3 has a higher voltage, however, it suffers from its stepped voltage platforms and severe cycle attenuation. In order to combine the advantages from both materials, many research groups have attempted by designing hybrid materials since the doping approach can only improve the main material without combining the advantages of two different active materials. In this work, we focus on obtaining nanostructured materials as well as hybrid materials by using pyro-synthetic method which is very effective for production of highly crystalline carbon coated nanomaterials under very short reaction times in open-air conditions. Further, the pyro-synthetic route using polyol medium will be beneficial for producing nanomaterials in terms of time and cost effectiveness because the combustion strategy is also applied to this strategy. Moreover, poly alcohols or polyols such as ethylene glycol and di/tri/tetra ethylene glycol can play multi-roles of a solvent, a reducing agent and a carbon source. We have successfully synthesized 0.66LiFePO4•0.33Li3V2(PO4)3 nanocomposites with high crystallinity by one-step pyro-synthetic strategy using the polyol at low temperature. The as-prepared sample without any additional heat treatment showed average particle size of about 30 – 60 nm and spherical shape as observed by SEM studies. After moderate heat-treatment was applied, the particle sizes of 0.66LFP•0.33LVP increased due to crystal growth of monoclinic phase of LVP accompanied by particle agglomeration. When tested for lithium-ion cell, the nanoparticles composite electrode demonstrated impressive electrochemical properties with enhanced energy density. Furthermore, it showed high reversible capacity of 145.65 mAh g-1 at 0.1C and exhibited remarkable capacity of 119 mAh g-1 at 6.4C. After cycled at 6.4C, the electrode can recover to 85% of its initial capacity when the current density returned back to 0.1C indicating the excellent rate capabilities of the present electrode.

Published

2016

3. Ex-Situ Synchrotron X-Ray Studies of Alpha-Type Manganese Dioxide Nanorod Cathode in Zinc-Ion Battery

Author

Muhammad Hilmy Alfaruqi, Sukyung Nam, Jihyeon Gim, Jinju Song, Sungjin Kim, Vinod Mathew, Jeonggeun Jo, Seulgi Lee, Saiful Islam, and Jaekook Kim

Abstract

Nowadays, extensive researches to overcome the world energy crisis has emphasized the urgent necessity of developing sustainable energy storage systems. The rechargeable lithium-ion battery (LIB) dominates today's battery market for portable device applications. Nonetheless, the crucial issues concerning its safety, eco-friendliness, and cost-effectiveness, as well as the controversies associated with the availability of lithium resources, have led to the continuous exploration of new battery chemistries. Sodium-ion, potassium-ion, and aluminum-ion batteries are promising alternative since these devices are based on relatively abundant and cheap sodium, potassium, and aluminum elements, respectively. However, these battery systems also suffer from complicated issues of safety, processing costs, and environmental concerns. Earlier efforts for developing a rechargeable aqueous zinc-ion battery (ZIB), which facilitates energy storage application via zinc-ion insertion/extraction, has opened the way for the realization of safe, environmentally benign and cost-effective next generation energy storage system. ZIB is still in the stage of early phase of development, therefore, fundamental studies concentrating on the zinc-ion insertion mechanism is an attractive goal to pursue. In this work, we used nanorod alpha-type manganese dioxide cathode for ZIB application. Alpha-type manganese deioxide was prepared by a simple hydrothermal synthesis. SEM and TEM studies showed rod-type sample with approximately 20 and 200 nm of width and length, respectively. The nanorod cathode exhibited an initial discharge capacity of 176.8 mAh g-1 at a current density of 83 mA g-1 and demonstrated nearly 100% Coulombic efficiencies under prolonged cycling when tested for zinc storage properties. Rate performance measurements revealed that specific capacities of 43.33 and 31.48 mAh g-1 were registered at current densities as high as 1333 and 1666 mA g-1. A combination of ex-situ synchrotron XRD and XAS studies confirmed the reversibility of electrochemical zinc-ion insertion into [2x2] tunnels of the alpha-type manganese dioxide host structure. The host exhibits structural stability by accommodating an unit cell volume expansion of approximately 3.12% during Zn-insertion. The present study hence paves the way for further development of rechargeable aqueous ZIB as an alternative ideal energy storage system due to its excellent safety and reliability. Figure 1

Published

2016