List of Publication
[1] Park Y.S.*, Kim S.-H., Lee J.-W. Effect of Nucleation Density on the Morphology of Diamond Thin Films. Japanese Journal of Applied Physics 1994; 33:6320-6324.
[2] Kim S.-H.* Park Y.S., Lee J.-W. Deposition of white diamond thin films by increasing the total pressure in a microwave plasma-enhanced chemical vapor deposition system. Thin Solid Films 1994; 253:109-113.
[3] Kim S.-H.* Deposition of Tungsten Thin Film on Silicon Surface by Low Pressure Chemical Vapor Deposition Method. Journal of the Korean Chemical Society 1994; 38(7):473-479.
[4] Park Y. S., Kim S.-H.*, Lee J.-W. Effect of substrate temperature on the morphology of diamond film. Korean Journal of Materials Research 1994; 4(4):385-392.
[5] Kim S.-H.*, Park Y.S., Jung S.K., Song S.A., Yoon S.Y., and Lee J.-W. Deposition of high quality diamond thin film and the film growth mode. Journal of the Korean Vacuum Society 1994; 3(2):207-211.
[6] Kim S.-H.*, Park Y.S., Lee J.-W. Deposition of diamond thin film by MPECVD method. Journal of Korean Association of Crystal Growth 1994;4(1):92-99.
[7] Kim S.-H.*, Park Y.S., Jung S.K., Kang D.H., Lee J-W. Effect of Substrate State on the Formation of the Diamond Film using a Low Temperature Microwave Plasma System. Journal of Vacuum Science & Technology A 1995; 13(3):1619-1623.
[8] Kim S.-H.*, Park Y.S., Jung S.K. Lee J-W., Park H.J., Jang H.K., Yang I.S., and Yun W.S. Enhancement of Heat Dissipation in {100} Diamond Thin Films. Material Science & Engineering A 1996; 209:68-73.
[9] Park Y.S.*, Kim S.-H., Jung S.K., and Lee J-W. Enhancement of Diamond Thin Film Characteristics by Cyclic Deposition Method under MPECVD System. Material Science & Engineering A 1996; 209:414-419.
[10] Kim S.-H.*, Park Y.S. Han I.T., Yun W.S., Baek H.K., and Lee J.-W. Application of Cyclic Process to {100}-Oriented Texture Growth of Diamond Film. Diamond Films and Technology 1996; 6(3):129-138.
[11] Kim S.-H.*, Park Y.S. Han I.T., Lee J.W., and Yun W.S. Effect of cyclic process on the {100}-oriented texture growth of diamond film. Applied Physics Letters 1996; 69(15):2184-2186.
[12] Kim S.-H.*, Park Y.S., Han I.T., Yun W.S., and Lee J.W. Effect of the cyclic growth/etching time ratio on the {100}-oriented texture growth of a diamond film. Thin Solid Film 1996; 209-291:161-164.
[13] Lee J.-W.*, Kim S.-H., Park Y.S., Shinn M.N., Kang D.H., Yoon S.Y., Kim D.S., Park T.S., Ha S.H., Lee J.H., Kim S.J. Retardation of the Onset time for signal dropout arising from wear debris using diamond-like carbon overcoats on the VCR head. IEEE Transactions on Magnetics 1997;33(1):826-835.
[14] Francois N., Kim S.-H. *, Park Y.S., Lee J.-W., Han I.T., and Yun W.S. Effect of substrate on the characteristics of the interface between diamond film and substrate. Diamond and Related Materials 1997;303(8):959-963.
[15] Lee J.-W., Kim S.-H. *, Park Y.S., and Han I.T. Cyclic technique for the enhancement of highly oriented diamond film growth. Thin Solid Film 1997; 303(1-2):264-268.
[16] Kim S.-H. *, Park Y.S., Yun W.S., and Lee J.-W. Enhancement of the diamond film uniformity in a biased microwave-plasma-enhanced chemical vapor deposition system. J. Crystal Growth 1997; 180(2):198-205.
[17] Kim S.-H. * and Han I.T. Field emission characteristics of patterned free-standing diamond film. J. Vac. Sci. Technol. A 1998; 16(3):922-925.
[18] Han I.T.*, Lee N., Lee S.W., Kim S.-H., Jeon D. Field emission of nitrogen-doped diamond films. J. Vac. Sci. Technol. B 1998; 16(4):2052-2056.
[19] Kim S.-H.* and Han I.T. Fabrication of tubular-volcano-type free-standing diamond films. Diamond Films and Technology 1998; 8(6):425-433.
[20] Kim S.-H.* Patterned free-standing diamond field emitters for large area field emission display applications. Journal of the Korean Vacuum Society 1999; 3(1):10-15.
[21] Kim S.-H.* Effect of hydrogen plasma treatment on the photoconductivity of free-standing diamond film. Journal of Korean Association of Crystal Growth 1999; 9(4):441-445.
[22] Ryu H.J., Kim S.-H. and Hong S.H.* Effect of deposition pressure on bonding nature in hydrogenated amorphous carbon films processed by electron cyclotron resonance plasma enhanced chemical vapor deposition. Materials Science & Engineering A 2000; 277:57-63.
[23] Kim S.-H. *, Han I. T., Kim Y. H., Kim T.-G., Kang S. G., Lee S. H., Moon S. B., and Kim D.-G. Effect of H2 and/or O2 plasma treatments on photoconductivity of freestanding polycrystalline diamond films. Journal of the Electrochemical Society 2000; 147(10):3935-3939.
[24] Guillemain R., KimS .-H.*, Cho S.-W., Kim Y.-H., Kim T.-G., Lee S.H. and Moon S.B. Investigation of the {100}-oriented texture growth of diamond film as functions of carburization and bias enhanced nucleation times. Journal of the ceramic processing research 2000; 1(2):102-108.
[25] Kim S.-H.* Investigation of the interface between diamond film and silicon substrate using transmission electron microscopy. Journal of Korean Association of Crystal Growth 2000; 10(2):100-104.
[26] Kim S.-H.*, Kim T.-G., Kim Y.-H., Kim D.-U., Lee S. K., Hosomi T., Maki T., and Kobayashi T. Selective deposition of diamond film on glass substrate via the enhancement of the diamond nucleation density by the cyclic process. Journal of the Electrochemical Society 2001; 148(3):C247-C251.
[27] Kim D. U.*, Paik S. H., Kim S.-H. and Tsutsui T. Design and synthesis of a novel red electroluminescent dye. Synthetic Metals 2001; 123:43-46.
[28] Kim S.-H.* Enhancement of low temperature selective deposition of diamond film. Journal of the Korean Chemical Society. 2001; 45(3):120-123.
[29] Kim S.-H.* Planarization of the diamond film surface by using the hydrogen plasma etching with carbon diffusion process. Journal of the Korean Chemical Society 2001; 45(4):351-356.
[30] Kim S.-H.*, Kim Y.-H., Kim T.-G., Bae E.-J., Lee S.K., and Kim D.U. Producing a Mirror-Finish Diamond Film Surface via the Dry Grinding Polishing Process on the Substrate Side of Free-Standing Diamond Film. New Diamond and Frontier Carbon Technology 2002; 12(1):1-11.
[31] Chae S.Y., Lee S.K.*, and Kim S.-H. Observation of Vibronic Emission Spectra of Jet-Cooled o-Chlorobenzyl Radical. Bulletin of Korean Chemical Society 2002; 23:795-801.
[32] Kim S.-H. Formation of Vertically Well-Aligned Carbon Nanotubes Bundles. Journal of the Korean Chemical Society 2002; 46(5):467-470.
[33] Kim S.-H. *, Bae E.-J., Park J.C., Kim T.-G., Lee S.K., Hosomi T., Maki T., and Kobayashi T. Effect of gas phase composition cycling on diamond nucleation density. Thin Solid Films 2003; 425: 282-286.
Authors:
[34] Kim S.-H.*, Kim B. Enhancement of the Diamond Film Characteristics by Increasing the Cyclic Modulation Time Interval of CH4 Flow. New Diamond and Frontier Carbon Technology 2003; 13(6):333-340.
[35] Kim S.-H.* Effect of the Applied Bias Voltage on the Formation of Vertically Well-Aligned Carbon Nanotubes. Korean Journal of Materials Research 2003; 13(7):415-419.
[36] Kim S.-H.* Interconnection of carbon nanotubes islands by bamboo-like carbon nanotubes. Journal of the Korean Chemical Society 2003; 47(6):659-662.
[37] Kim S.-H.* Competitive Growth of Carbon Nanotubes versus Carbon Nanofibers. Journal of the Korean Ceramic Society 2003; 40:1150-1153.
[38] Kim D.U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Han Y.-S. Kim S.-D., Kim K.-B., Ju H.-J., and Kim T.J. Electro-Optical characteristics of indandione-pyran derivatives as red emission dopants in electoluminescent device. Materials Science & Engineering C 2004; 24(1-1):147-149.
[39] Kim S.-H.*, Park J.-C., Kim B., Lee S.K., Kim D.U., and Kim Y.-H. Self-assembled interconnection by bamboo-like carbon nanotubes. Materials Science & Engineering C 2004; 24(1-1):297-300.
[40] Kim Y.-H.* and Kim S.-H. Enhancement of the Stability of Capacitance-Voltage Characetristics of Hg(1-x)Zn(x)Te-Based Metal-Insulator-Semiconductor Capacitors by Voltage Annealing. Japanese Journal of Applied Physics 2004; 43(10):1244-1246.
[41] Kim D.-U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Han Y.-S., Kim S.-D., Kim K.-D., Ju H.-J., Moon H.-W., and Kim T.-J. Novel green phosphorescent materials with various substituted acetylacetonate ligands for organic electroluminescent device. Molecular Crystals and Liquid Crystals 2004; 424:111-117.
[42] Kim S.-H. Growth of Nickel-Catalyzed Carbon Nanofibers using MPCVD method and their Electrical Properties. Journal of the Korean Crystal Growth and Crystal Technology 2004; 14(1):1-5.
[43] Kim S.-H. Field emission characteristics of carbon nanofiber bundles. Journal of the Korean Crystal Growth and Crystal Technology 2004; 14(5):211-214.
[44] Kim S.-H. Time-dependent cyclic modulation process of CH4 gas flow rate in CH4-H2-O2 plasma. Journal of the Korean Chemical Society 2004; 48(6):663-666.
[45] Kim S.-H. Selective growth of the carbon nanofibers at the groove area of the MgO substrate. Journal of the Korean Ceramic Society 2004; 41(12):880-883.
[46] Kim Y.-H.*, Kim S.-H., Kim I.-J., An S.Y., Kim K.H. The surface passivation of Cd1-xZnxTe as to ZnS thickness and pre-heating. Current Applied Physics 2005; 5:392-396.
[47] Lee G.W., Lee S.K.*, and Kim S.-H. Observation of Jet-Cooled 2,6-Dichlorobenzyl Radical in a Corona Excited Supersonic Expansion. Bulletin of the Korean Chemical Society 2005; 26(8):1164-1165.
[48] Kim D.-U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Kim S.-D., Kim K.-D., Kim K.-H., Jung Y.C., and Park L.S. Synthesis and Electroluminescent Properties of Novel Emissive Iridium Complex with Phenyl-isoquinoline Ligand. Molecular Crystals and Liquid Crystals 2005; 443:79-85.
[49] Kim D.U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Kim S.-D., Kim K.-D., Ju H.-J., Kim T.-J., and Han Y.S. Iridium Complexes with 3-Methyl-2,4-Pentanedione Ligand for Organic Electroluminescent Device. Journal of Nonlinear Optical Physics & Materials 2005; 14(4):529-534.
[50] Kim S.-H.* Control the growth direction of carbon nanofibers under direct current bias voltage applied
microwave plasma enhanced chemical vapor deposition system. Journal of the Korean Crystal Growth and Crystal Technology 2005; 15(1):198-201.
[51] Kikuchi T., MaruyamaT., Fujii T., Kobayashi T., Kim S.-H.*, Kim D.U., and Lee S.K. The manipulation of the carbon nanofibers growth into lateral or vertical direction with respect to the substrate synthesized with iridium catalyst. Thin Solid Films 2006; 503:219-223.
[52] Kim S.-H.*, Kim D.U., and Lee S.K. Elongation of vertically well-aligned carbon nanofiber bundles and their field emission characteristics. Current Applied Physics 2006; 6:766-771.
[53] Kim D.-U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Kim S.-D., Kim K.-D., Kim K.-H., Ko T.-H., Yoon U.-C., Han Y.-S., Jeong Y.C., and Park L.S. Development of novel red phosphorescent iridium complex with phenyl-isoquinoline ligand for organic electroluminescent device. Current Applied Physics 2006; 6:805-807.
[54] Kim S.-H.* Different growth position of iridium-catalyzed carbon nanofibers on the substrate according to the value of the applied bias voltage. Korean Journal of Materials Research 2006; 16(1):25-29.
[55] Kim S.-H.* Different formation of carbon nanofilaments as a function of the gap between the substrate and the microwave plasma. Journal of the Korean Crystal Growth and Crystal Technology 2006; 16(1):20-24.
[56] Kim T.-G., Kim S.-H., Yoon S.-J.* Cyclic on/off modulation of CH4 and/or O2 flows for the enhancement of the diamond film characteristics. Journal of the Korean Institute of Surface Engineering 2006; 39(2):82-86.
[57] Kim K.-D., Kim S.-H.*, Kim N.S. Bridge-type formation of iridium-catalyzed carbon nanofibers across the gap on MgO substrate and their electrical properties. Journal of the Korean Crystal Growth and Crystal Technology 2006; 16(5):198-202.
[58] Huang Y., Jang K.*, Wang X., Xian G., Cho E., Lee H.S. and Kim S.-H. The luminescence of Pr3+ ions doped Y4Al2O9 by sol-gel synthesis. Journal of non-crystalline solids 2007; 353:4102-4107.
[59] Kim N.S., Kim S.-H.* Investigation of the growth of carbon nanofilaments over a wide temperature range. Journal of Ceramic Processing Research 2007; 8(6):458-462.
[60] Kim K.-D., Kim S.-H.*, Kim N.S., and Kim D.-U. Effect of the on/off cyclic modulation time ratio of C2H2/H2 flow on the low temperature deposition of carbon nanofilaments. Journal of Nanoscience and Nanotechnology 2007; 7:3969-3973.
[61] Kim N.S., Kim K.-D., and Kim S.-H.* Low temperature deposition of carbon nanofilaments using vacuum-sublimated Fe(CO)5 catalyst with thermal chemical vapor deposition. Journal of the Korean Crystal Growth and Crystal Technology 2007;17(1):18-22.
[62] Kim K.-D., Yun H.-S., Kim N.-S., Kim S.-S., Kim S.-H.* Nickel-encapsulated amorphous carbon clusters: one of the origins for the formation of carbon nanofibers. Journal of Korean Society for imaging & technology 2007; 13(1):19-23.
[63] Kim S.-H.* Enhancement of the characteristics of carbon nanofibers by the on/off cyclic modulation. Journal of the Korean Crystal Growth and Crystal Technology 2007; 17(4):160-164.
[64] Kim D.U.*, Paik S.-H., Kim S.-H., Tak Y.-H., Kim S.-D., Han Y.-S., Kim T.-J., Ko T.-H., Yoon U.-C., and Patrick S.M. Electroluminescent characteristics of novel platinum-porphyrin complex. Colloids and Surfaces A 2008; 313:444-447.
[65] Kim K.-D., Kim N.-S., and Kim S.-H.* Formation of branched-type carbon nanofibers. Journal of Korean Society for imaging & technology 2008; 14(2):117-121.
[66] Gao Y.X., Kim S.-H.*, Lee S.-H. Variation in the characteristics of carbon nanofilaments according to the cycic modulation period of C2H2/H2 Flow. Journal of Korean Society for imaging & technology 2008; 14(3):173-179.
[67] Kim N.-S., and Kim S.-H.* The effects of functional monomers on the synthesis and physical properties of solution type quaternary polymer acrylic pressure-sensitive adhesives. Journal of the Korean Oil Chemists’ Society 2008; 25(4): 525-532.
[68] Balakrishnaiah R., Kim D.W., Yi S.S.*, Kim K.D., and Kim S.-H., Jang K., Lee H.S., and Jeong J.H. Fluorescence Properties of Nd3+ -Doped KNbO3 Phosphors. Electrochemical and Solid-State Letters 2009;12(7):J64-J68.
[69] Balakrishnaiah R., Kim D.W., Yi S.S.*, Kim K.D., and Kim S.-H., Jang K., Lee H.S., and Jeong J.H. Frequency upconversion fluorescence studies of Er3+/Yb3+ -codoped KNbO3 phosphors. Thin Solid Films 2009; 517:4138-4142.
[70] Kim K.D., Kim S.-H.*, Yi S.S., and Jang K. Enhancement of Carbon Nanofilaments Formation Density and the Surface Electrical Conductivity by the Gas Phase Composition Cycling. Molecular Crystals and Liquid Crystals 2009; 513:179-186.
[71] Ratnam B.V., Jayasimhadri M., Yoon J.h., Jang K.*, Lee H.-S., Yi S.-S., Kim S.-H., and Jeon J.H. Luminescent Properties of Tb3+ - Doped NaCaPO4 Phosphor. Journal of the Korean Physical Society 2009; 55(6):2383-2387.
[72] Kim K.D., and Kim S.-H.* Controlling the Diameter Size of Carbon Nanofilaments by the Cyclic on/off Modulation of C2H2/H2/SF6 Flow in a Thermal Chemical Vapor Deposition System. Journal of the Korean Vacuum Society 2009; 18(6):481-487.
[73] Kim N.-S., and Kim S.-H.* Effect of alcohol solvents and calcination temperature on the synthesis of titanium particles. Journal of the Korean Oil Chemists’ Society 2009; 26(4):473-482.
[74] Kim K.D., Kim S.-H.*, Yi S.-S., and Jang K. Effect of SF6 incorporation in the cyclic process on the low temperature deposition of carbon nanofilaments. Thin Solid Films 2010; 518:6412-6416.
[75] Balakrishnaiah R., Kim D.W. and Yi S.S.*, Jang K., Lee H.S., Kim S.-H., Moon B.K., and Jeong J.H. Photoluminescence properties of Li+-doped KNbO3:Eu3+ Phosphors. J. Korean Physical Society 2010; 57(6): 1841–1846.
[76] Balakrishnaiah R., Kim D.W., and Yi S.S.*, Kim S.-H., Jang K., Lee H.S., Moon B.K., and Jeong J.H. NIR to VIS frequency upconversion luminescence properties of Er3+-doped YPO4 phosphors. Thin Solid Films 2010; 518:6145-6148.
[77] Yi S.S.*, Kim J.-C., Kim D.W., Balakrishnaiah R., Kim S.-H., Jang K., Lee H.S., Moon B.K., and Jeong J.H. Luminescence properties of Nd3+-doped (Y,Gd)BO3 phosphors. Thin Solid Films 2010; 518: 6163-6167.
[78] Kim N.-S., and Kim S.-H.* Effect of protective colloid on the synthesis of Poly(Vinyl acetate-co-Ethyl acrylate). J. of the Korean Oil Chemists’ Soc. 2010; 27(2):216-221.
[79] Kim S.-H.* Effect of injection stage of SF6 gas incorporation on the limitation of carbon coils geometries. J. of the Korean Vacuum Soc. 2011; 20(5):374-380.
[80] Kim S.-H.* The geometry change of carbon nanofilaments by SF6 incorporation in a thermal chemical vapor deposition system. J. of the Korean Crystal Growth and Crystal Technology 2011; 21(3): 119-123.
[81] Eum J.-H., Kim S.-H.*, Yi S.S., Jang K. Large-scale synthesis of the controlled-geometry carbon coils by the manipulation of the SF6 gas flow injection time. Journal of Nanoscience and Nanotechnology 2012; 12(5):4397-4402
[82] Jeon Y.-C., Eum J.-H., Kim S.-H.*, Park J.-C., Ahn S.I. Effect of the on/off cycling modulation time ratio of C2H2/SF6flows on the formation of geometrically controlled carbon coils. Journal of Nanomaterials 2012; 2012(Article ID 908961)
[83] Ahn S.I.*, Kim W.K., Ryu S.H., Kim K.J., Lee S.E., Kim S.-H., Park J.-C., Cho K.C. OLED with a controlled molecular weight of the PVK(poly(9-vinylcarbazole)) formed by a reactive ink-jet process. Organic Electronics 2012; 13: 980–984.
[84] Jeon Y.-C., and Kim S.-H.* Formation of the geometrically controlled carbon coils by manipulating the additive gas (SF6) flow rate. Journal of Nanoscience and Nanotechnology 2012; 12(7):5957-61.
[85] Eum J.-H., Jeon Y.-C., and Kim S.-H.* Effect of Gas Phase Composition Cycling On/Off Modulation Numbers of C2H2/SF6 Flows on the Formation of Geometrically Controlled Carbon Coils. Journal of Nanoscience and Nanotechnology 2012; 12(7), 6100–6106.
[86] Park S., Kim S.-H.*, and Kim T.-G. Effect of Si and SiO2 substrates on the geometries of as-grown carbon coils. Journal of Nanomaterials 2012; 2012(Article ID 389248)
[87] Kim S.-H.* Effect of reaction temperature on the geometry of carbon coils formed by SF6 flow incorporation in C2H2 and H2 source gases. J. of the Korean Vacuum Society 2012; 21(1):48-54.
[88] Lee S.-H., and Kim S.-H.* Effect of gas phase cycling modulation of C2H2/SF6 flows on the formation of carbon coils. J. of the Korean Vacuum Society 2012; 21(3): 178-184.
[89] Lee S.-H. and Kim S.-H.* Geometry variation for as-grown carbon coils under the minimized sulfur additive condition deposition system. J. of the Korean Crystal Growth and Crystal Technology 2012; 22(5): 213-217
[90] Jeon Y.-C., Park S., and Kim S.-H.* The Geometry Variation of As-Grown Carbon Coils withNi Layer Thickness and Hydrogen Plasma Pretreatment. Journal of Nanomaterials 2013; 2013(Article ID 325827)
[91] Jeon Y.-C., Ahn S.I., and Kim S.-H.* Developing Aspect of Carbon Coils Formation During the Beginning Stage of the Process. Journal of Nanoscience and Nanotechnology 2013; 13: 5754-5758.
[92] Jeon Y.-C., Yi S.S., and Kim S.-H.* Dominant Formation of the Microsized Carbon Coils by a Short Time SF6 Flow Incorporation During the Initial Deposition Stage. Journal of Nanoscience & Nanotechnology 2013; 13: 5855-5858.
[93] Park S., and Kim S.-H.* Controlled Geometry Formation of the Carbon Coils by the Substrate Pretreatment. ISRN Nanomaterials 2013; 2013(Article ID 893636)
[94] Park S., Jeon Y.-C., and Kim S.-H.* Effect of Injection Stage of SF6 flow on Carbon Micro Coils Formation. ECS Journal of Solid State Science and Technology 2013; 2(11):M56-M59
[95] Jang C.-Y. and Kim S.-H.* Effect of the Ni Catalyst Size and Shape on the Variation of the Geometries for the As-grown Carbon Coils. J. Kor. Inst. Surf. Eng. 2013; 46(4): 175-180.
[96] Kim S.-H.* Large Scale Synthesis of Geometrically Controlled Carbon Coils using Al2O3Ceramic Boat for the Supporting Substrate. J. of Korean Oil Chemists’ Soc. 2013; 30(3): 423-430.
[97] Park C.-H. and Kim S.-H.* Synthesis of the carbon nano/micro coils applicable to the catalyst support to hold the tiny catalyst grain. J. of the Korean Vacuum Society 2013; 22(6): 277-284.
[98] Jeon Y.-C., and Kim S.-H.* Large-scale synthesis of the carbon coils using stainless steel substrate. J. of the Korean Crystal Growth and Crystal Technology 2013; 23(6): 296-301.
[99] Lee D.G., Kesavulu C.R., Yi S.S.*, Cho S., Jang K., Kim S.-H., and Jeong J.H. Photoluminescence Properties ofNa(Sr, Ca)VO4:Eu3+ Phosphors. Journal of Nanoscience and Nanotechnology 2014; 14:5877-5880.
[100] Kim D., Jang J., Ahn S.I., Kim S.-H., and Park J.-C.* Novel blue-emitting Eu2+-activated LaOCl:Eumaterials. Journal of Materials Chemistry C 2014; 2: 2799-2805.
[101] Jeon Y.-C., and Kim S.-H.* Geometry Development of the Carbon Microcoils from the Carbon Nanofilaments. Vacuum 2014; 107: 219-224.
[102] Ahn S.I.,*, Kim K., Kim J.Y., Kim E.S., Han J.Y., Eom J.W., Choi K.-K., Park J.-C., Kim S.-H., Jeong E.D. and Choi K.C. Reduction intermediates of graphene oxide for low temperature reduction electrode material. RSC Advances 2014; 4: 22476-22480.
[103] Jeon Y.-C., Park B., Park S., and Kim S.-H.* Investigation of SF6 Injection During Cyclic C2H2/SF6 Flow for the Formation of Geometrically Controlled Carbon Coils. Journal of Nanoscience and Nanotechnology 2014; 14(12): 9182-9188.
[104] Kang G.-H. and Kim S.-H.* Electromagnetic Wave Shielding Effectiveness Based on Carbon Microcoil-Polyurethane Composites. Journal of Nanomaterials 2014; 2014(Article ID 727024)
[105] Jeon Y.-C., and Kim S.-H.* The Formation of the Carbon Microcoils without the Catalyst on the Mesh-type Stainless Steel Substrate. Advanced Materials Research 2014; 894: 116-120
[106] Kang G.-H. and Kim S.-H.* Carbon coils-Polyurethane Composites for the Shielding Materials of Electromagnetic Interference. Advances in Science and Technology 2014; 95: 50-55
[107] Kim D.-U.* and Kim S.-H. Recognition of Korean Pre-service Elementary Teachers Concerning Environment Class. J. of Environmental Science International 2014; 23(8): 1507-1512.
[108] Kang G.-H., Bae M.-K., and Kim S.-H.* Formation of noble-shaped carbon nanostructures. J. Incl. Phenom. Macrocycl. Chem. 2015; 82: 179-186.
[109] Kang G.-H., Kim S.-H.*, and, Yun W.S. Effectiveness of Electromagnetic-Wave Shielding by Composites of Carbon Nanotubes and Carbon Microcoils in Polyurethane. Journal of Nanoscience and Nanotechnology 2015; 15: 9131-9135.
[110] Kang G.-H., and Kim S.-H.* The Formation of Carbon Microcoils Having the Coil-Type Overall Geometry. Journal of Coating Science and Technology 2015; 2: 100-104.
[111] Lee J.-K. and Kim S.-H.* Effect of the SF6 Flow Injection Time on the Formation of the Carbon Coils. Key Engineering Materials 2016; 869: 48-54.
[112] Kang G.-H., and Kim S.-H.* The Aligned Carbon Microcoils Having the Straight Type Overall Geometry. Key Engineering Materials 2016; 689: 43-47.
[113] Kim H.-J., Kang G.-H., Lee J.-K., and Kim S.-H.*Comparative Investigation into the catalytic efficiency of Ni and Fe in the Formation of Carbon Coils. Advanced Materials and Structural Engineering 2016; 81-85 (Book Series, 978-1-138-02786-2).
[114] Yang W., Kim S.-H., Park S. Multi-color tunable Ce3+-Mn2+ cooperative Y7O6F9 vernier phosphors. Journal of Alloys and Compounds, 2016; 673: 1-7.
[115] Kang G.-H., Kim S.-H.*, and Kim G.-R. Formation of the carbon microcoils dangled from the carbon nanofibers. Advanced Materials and Structural Engineering 2016; 117-121 (Book Series, 978-1-138-02908-8).
[116] Kang G.-H., and Kim S.-H.* Effect of incorporating carbon nanocoils on the efficiency of electromagnetic-wave shielding of carbon-nanomaterial composites. Applied Surface Science 2016; 380: 114-118.
[117] Kang G.-H., and Kim S.-H.* and Park S. Controllablle synthesis of carbon nanocoil-carbon microcoils hybrid materials. Materials & Design 2016; 116: 42-50.
[118] Ahn S.-E., and Kim S.-H.* Low temperature synthesis of the carbon micro materials. Key Engineering Materials 2017; 730: 327-332.
[119] Kim D.-C., and Kim S.-H.* Dominant Formation of the Carbon Nanocoils at Low Temperature. Key Engineering Materials 2017; 744: 446-452.
[120] Yun H., Kim S.-H., and Park S.* Bi3+, Eu3+-doped Ba9Y2Si6O24 phosphors based on the site-selected substitution. Optical Materials 2017; 72: 571-577.
[121] Kang G.-H., and Kim S.-H.* and Park S. Enhanced Formation of Carbon Microcoils with Ni Catalysts of Different Sizes. ECS Journal of Solid State Science and Technology 2017; 6(8): M103-M108
[122] Lee N.-Y., and Kim S.-H.* Enhanced Formation of the Carbon Microcoils by the Stepwise Type Manipulation of CS2 Flow Injection. Key Engineering Materials 2018; 765: 83-91.
[123] Kim D.-C., and Kim S.-H.* Geometry-controlled Carbon Coils by SF6 Flow Injection Time with Reaction Temperature. Journal of Nanomaterials 2018; 2018:1-11(ID7859747)
[124] Yang S.-J., Kim S.-H., and Park S.* Color-tunable self-activated oxyfluoride phosphors induced by anion-defect with cation-disorder. Journal of Alloys and Compounds 2018; 756: 212-216.
[125] Kim H.-J., Kim S.-H.*, Park S. Effects of the Carbon Fiber-Carbon Microcoil Hybrid Formation on the Effectiveness of Electromagnetic Wave Shielding on Carbon Fibers-Based Fabrics. Materials 2018; 11(12):2344.
[126] Yoo C.M., Lee C.H., Shin H.S.*, Yeo D.H., and Kim S.-H. Dispersion Optimization of Alumina Slurry with Variation of the Dispersant. Journal of Nanoscience and Nanotechnology 2019; 19: 11677-1681.
[127] Kim H.-J., and Kim S.-H.* Effect of CS2 Flow Rate on the Formation of Aligned Carbon Microcoils. Materials Science Forum 2019; 947: 40-46.
[128] Kim H.-J., and Kim S.-H.* Comparative Investigation into the Electromagnetic Wave Shielding Effectiveness of Different Type Carbon-Based Fabrics. Key Engineering Materials 2019; 803: 81-87.
[129] Kang G.-H., and Kim S.-H.* and Park S. Enhancement of shielding effectiveness for electromagnetic wave radiation using carbon nanocoil-carbon microcoil hybrid materials. Applied Surface Science 2019; 447: 264-270.
[130] Kim H.-J., and Kim S.-H.* Enhanced Electromagnetic Wave Shielding Effectiveness of Carbon-Based Nonwoven Fabrics by H2 Plasma Treatment. Key Engineering Materials 2020; 834:120-126.
[131] Kim H.-J., Kang G.-H., Kim S.-H.*, and Park S. Enhancement of Electromagnetic Wave Shielding Effectiveness of Carbon Fibers via Chemical Composition Transformation Using H2 Plasma Treatment. Nanomaterials 2020; 10:1611.