[80] H. Kwon, High-Hardness Cemented Carbide With Nickel-Tungsten Alloy Binder, J. Powder Mater., 31, 318 (2024)
[79] H. Kwon, Synthesis of High Value-added Carbide Materials (MXenes) from Recycled Oxides, Resour. Recycl., 33, 29 (2024)
[78] J. Lee, S. Park, S. Lee, S. Son, H. Kwon, S. Lee, J. Jung, Microstructural evolution and thermal stability of Al–Zn–Mg–Cu–Si–Zr alloy fabricated via spark plasma sintering, J. Mater. Res. Tech., 31, 205 (2024)
[77] J. Seo, J. Song, D. Lee, T. Park, H. Kwon, Effect of Al2O3 Content and Particle Size of Iron Ore on the Assimilation Characteristics of Sintered Ore, Korean J. Met. Mater., 62 [9] (2024)
[76] H. Kwon, J. Song, D. Lee, J. Seo, I. Choi, Effect of yttrium oxide addition on the microstructure and mechanical properties of WC–Ni composites fabricated from recycled WC and Ni. J. Asian Ceram. Soc., 12, 257 (2024)
[75] H. Kwon, J. Song, D. Lee, J. Jeon, J. Lee, Improvement of the Sintering and Mechanical Properties of SiC Utilizing the Increased Milling Efficiency of Si Source Recycled from Si Sludge, Mater. Trans., 65, 440 (2024)
[74] H. Kwon, Improvement of mechanical properties of hard metals for cutting tools, Ceramist, 26, 327 (2023)
[73] A. Iqbal, H. Kim, J. Oh, J. Chae, J. Kim, M. Kim, T. Hassan, Z. Gao, J. Lee, S. Kim, D. Kim, Y. Gogotsi, H. Kwon, C. Koo, Effect of Substitutional Oxygen on Properties of Ti3C2Tx MXene Produced Using Recycled TiO2 Source, Small methods, 7, 2201715 (2023)
[72] S. Choi, J. O, J. S. Meena, H. Kwon, S. Jung, J. Kim, Role of Oxygen in the Ti3AlC2 MAX Phase in the Oxide Formation and Conductivity of Ti3C2‑Based MXene Nanosheets, ACS Appl. Nano Mater., 15, 8393 (2023)
[71] J. Shin, J. Jung, J. Lee, N. Heo, H. Kwon, Y. Kim, T. Ryu, Recovery of lithium from LiAlO2 in waste box sagger through sulfation to produce Li2SO4 and sequential wet conversion to Li3PO4, LiCl and Li2CO3, Hydrometallurgy, 215, 105988 (2023)
[70] H. Kwon, M. Kim, J. Yoon, Synthesis of High-purity Silicon Carbide Powder using the Silicon Wafer Sludge, Resour. Recycl., 31, 60 (2022)
[69] H. Kwon, J. Shin, Preparation and Characterization of Tungsten Carbide Using Products of Hard Metal Sludge Recycling Process, Resour. Recycl., 31, 19 (2022)
[68] I. Choi, J. Oh, D. Kim, J. Kim, H. Kwon, Comparison of Phase evolution and Sintering Properties of Ti-10Mo Alloys Prepared using Bulk Scrap and Blended Elemental (BE) Powder, Korean J. Met. Mater., 60 [3], 180 (2022)
[67] H. Kwon, J. Shin, Sintering Behavior and Hardness of Tungsten Prepared by Hard Metal Sludge Recycling Process without Ammonium Paratungstate, Korean J. Met. Mater., 60 [1], 53 (2022)
[66] H. Kwon, Improvement of Mechanical Properties of Hard Metals Using Solid Solution Strengthening Metallic Binder (Co1-xWx), Korean J. Met. Mater., 60 [1], 14 (2022)
[65] H. Lim, S. Choi, H. Kwon, J. Lim, C. Han, J. Oh, J. Kim, Development of a Highly Flexible Composite Electrode Comprised of Ti3C2-Based MXene Nanosheets and Ag Nanoparticles, Electron. Mater. Lett., 17, 513 (2021)
[64] T. Kim, H. Kwon, J. Lim, Evaluation of Oxygen Reduction and Surface Chemical State of Ti-48Al-2Cr-2Nb Powder by Ca Vapor, J. Korean Powder Metall. Inst., 28, 31 (2021)
[63] H. Kwon, J. Lim, Chipped Titanium Scraps as Raw Materials for Cutting Tools, Resour. Recycl., 30, 61 (2021)
[62] H. Kwon, C. Y. Suh, Hardening of Ti(CN)-Fe composites by microstructural refinement and solid solution strengthening of metallic phase, Ceram. Int., 47, 13927 (2021)
[61] H. Kwon, Improvement of the mechanical properties of titanium carbonitride-metal composites by modification, Ceramist, 23, 114 (2020)
[60] G. Cho, J. M. Oh, H. Kwon, J. W. Lim, Effect of α-lath size on the mechanical properties of Ti-6Al-4V using core time hydrogen heat treatment, Mater. Sci. Tech., 36, 858 (2020)
[59] H. Kwon, C. Y. Suh, Effects of Ni content and sintering temperature on the microstructure and mechanical properties of TiC-Ni composites fabricated by selective carburization of Ti-Ni alloys, J. Alloys Compd., 834, 155000 (2020)
[58] J. Kim, H. Kwon, B. S. Kim, Y. J. Suh, Finite temperature thermal expansion and elastic properties of (Hf1-xTax)C ultrahigh temperature ceramics, Ceram. Int., 45, 10805 (2019)
[57] H. Kwon, A. Moon, J. Kim, Prediction of solid solution characteristics of MC (M = Zr, Nb, and Ta) in TiC lattice using phase stability diagrams, J. Am. Ceram. Soc., 102, 4285 (2019)
[56] H. Kwon, A. Moon, J. Kim, Phase Stability Diagrams of Ti–M–O–C (M = Zr, Hf, Nb, and Ta) Systems at 1800 K, Met. Mat. Int., 25, 396 (2019)
[55] A. Moon, C. Y. Suh, J. Kim, H. Kwon, Fabrication of TiC–ZrC–Co composites with refined microstructure using ultrafine TiC–ZrC mixture powders, J. Alloys Compd., 740, 82 (2018)
[54] H. Kwon, A. Moon, W. Kim, J. Kim, Investigation of the conditions required for the formation of V(C,N) during carburization of vanadium or carbothermal reduction of V2O5 under nitrogen, Ceram. Int., 44, 2847 (2018)
[53] A. Moon, C. Y. Suh, H. Kwon, Microstructure and mechanical properties of ultrafine (Ti,Mo,W,Nb,Zr,Ta)(CN)–Ni composites prepared using the stabilized (Ti,Mo,W,Nb,Zr,Ta)(CN) phase, J. Alloys Compd., 732, 838 (2018)
[52] H. Kwon, S. Jung, C. Suh, W. Kim, Mechanical properties of (TixW1−x)C–Co cermet prepared by carbothermal reduction of high energy ball milled TiO2–WO3–C, Ceram. Int., 43, 1943 (2017)
[51] H. Kwon, W. Kim, J. Kim, Stability domains of (Ti,W)C and (Ti,W)(CN) during carbothermal reduction of TiO2/WO3 mixture at 1500 K, J. Eur. Ceram. Soc., 37, 1355 (2017)
[50] H. Kwon, A. Moon, W. Kim, J. Kim, Investigation of the conditions required for the formation of (Ti,W)(CN) during carburization of titanium under nitrogen, Mater. Lett., 209, 287 (2017)
[49] J. M. Oh, K. M. Roh, H. Kwon, J. W. Lim, Sintering properties of Ti-6Al-4V-xMo powder prepared by addition of Mo to Ti-6Al-4V scraps and subsequent pulverization, Met. Mat. Int., 23, 1139 (2017)
[48] J. Kim, H. Kwon, C. Kwon, Temperature dependent phase stability of Ti(C1−xNx) solid solutions using first-principles calculations, Ceram. Int., 43, 650 (2017)
[47] J. G. Ku, J. M. Oh, H. Kwon, J. W. Lim, K. M. Roh, High-temperature hydrogen-reduction process for the preparation of low-oxygen Mo powder from MoO3, Int. J. Hydrogen Energ., 42, 2139 (2017)
[46] H. Kwon, S. Jung, C. Suh, W. Kim, Microstructure and mechanical properties of W-reinforced Ti(CN) prepared by spark plasma sintering of premixed Ti(CN)-W powder, Ceram. Int., 42, 8750 (2016)
[45] J. M. Oh, I. H. Choi, C. Y. Suh, H. Kwon, J. W. Lim, K. M. Roh, Deoxidation and subsequent densification of sintered titanium by Ca deoxidizer, Met. Mat. Int., 22, 488 (2016)
[44] H. Kwon, J. Kim, W. Kim, Stability domains of NbC and Nb(CN) during carbothermal reduction of niobium oxide, J. Am. Ceram. Soc., 98, 315 (2015)
[43] H. Kwon, C. Y. Suh, W. Kim, Preparation of a highly toughened (Ti,W)C-20Ni cermet through in situ formation of solid solution and WC whiskers, Ceram. Int., 41, 4223 (2015)
[42] H. Kwon, S. A. Jung, C. Y. Suh, K. M. Roh, W. Kim, J. Kim, Highly Toughened Dense TiC-Ni Composite by in situ Decomposition of Nonequilibrium (Ti,Ni)C Solid Solution, Ceram. Int., 41, 4656 (2015)
[41] H. Kwon, S. A. Jung, W. Kim, (Ti,Cr)C synthesized in situ by spark plasma sintering of TiC/Cr3C2 powder mixtures, Mater. Trans., 56, 264 (2015)
[40] H. Kwon, C. Y. Suh, W. Kim, Microstructure and mechanical properties of (Ti,W)C-Ni cermet prepared using a nano-sized TiC-WC powder mixture, J. Alloy Compd., 639, 21 (2015)
[39] S. A. Jung, H. Kwon, K. M. Roh, C. Y. Suh, W. Kim, Ti-Based Solid Solution Carbonitrides Prepared from Ti-Alloy Scraps via a Hydrogenation-Dehydrogenation Process and High-Energy Milling, Met. Mat. Int., 21, 923 (2015)
[38] H. Kwon, J. H. Yoo, S. W. Cho, Hydrogen absorption/desorption property of (La,Ce,Pr)(Ni,Mn,Al)5 alloys, Int. J. Hydrogen Energ., 40, 11902 (2015)
[37] S. A. Jung, H. Kwon, C. Y. Suh, J. M. Oh, W. Kim, Preparation of a fine-structured TiC-Co composite by high-energy milling and subsequent heat treatment of a Ti-Co alloy, Ceram. Int., 41, 14326 (2015)
[36] J. M. Oh, B. K. Lee, C. Y. Suh, H. Kwon, J. W. Lim, K. M. Roh, W. Kim, Preparation of Ti-Mo-Si Alloy Powders with Enhanced High-temperature Oxidation Resistance using Ti-10Mo Scraps, Met. Mat. Int., 21, 521 (2015)
[35] J. M. Oh, K. M. Roh, H. Kwon, B. K. Lee, C. Y. Suh, J. W. Lim, Preparation of Ti Ternary Alloys by Addition of Si to Ti-Mo Alloy Scraps for Carbonitride Application, Mater. Trans., 56, 167 (2015)
[34] J. M. Oh, K. M. Roh, B. K. Lee, C. Y. Suh, W. Kim, H. Kwon, J. W. Lim, Preparation of low oxygen content alloy powder from Ti binary alloy scrap by hydrogenation-dehydrogenation and deoxidation process, J. Alloy Compd., 593, 61 (2015)
[33] I. J. Shon, H. G. Jo, H. Kwon, Properties of nanostructured TiC and TiC-TiAl3 hard materials rapidly sintered by the pulsed current activated heating, Int. J. Refract. Met. H., 48, 187 (2015)
[32] J. Oh, C. Suh, H. Kwon, J. Lim, K. Roh, Preparation of Low Oxygen Content Powder from Ti-6Al-4V and Ti-8Al-1Mo-1V Alloy Scraps with Deoxidation in Solid State Process, Resour. Recycl., 24, 21 (2015)
[31] H. Kwon, J. Kim, S. A. Jung, C. Y. Suh, D. S. Kil, K. M. Roh, W. Kim, J. W. Lim, Premixed TiC-Ni composite powder prepared by mechanical milling of Ti-Ni alloy/graphite mixture and subsequent heat treatment, Powder Technol., 253, 681 (2014)
[30] H. Kwon, J. Kim, S. A. Jung, C. Y. Suh, D. S. Kil, K. M. Roh, W. Kim, (Ti,W)C-Ni cermet prepared by high-energy ball milling and subsequent carbothermal reduction of TiO2-Ti-WO3-C mixture, Ceram. Int., 40, 7607 (2014)
[29] H. Kwon, J. Kim, W. Kim, Stability domains of Nb(CN) during the carburization/nitridation of metallic niobium, Ceram. Int., 40, 8911 (2014)
[28] H. Kwon, S. A. Jung, C. Y. Suh, K. M. Roh, W. Kim, Mechanical properties of (Ti,V)C-Ni composite prepared using ultrafine solid-solution (Ti,V)C phase, Ceram. Int., 40, 12579 (2014)
[27] H. Kwon, J. Kim, S. W. Cho, J. H. Yoo, K. M. Roh, W. Kim, The effect of Sc addition on the hydrogen storage capacity of Ti0.32Cr0.43V0.25 alloy, Int. J. Hydrogen Energ., 39, 10600 (2014)
[26] H. Kwon, S. Jung, Solid Solution Cermet: (Ti,Nb)(CN)–Ni Cermet, J. Nanosci. Nanotechnol., 14, 8823 (2014)
[25] I. J. Shon, H. Kwon, H. G. Jo, Properties and Rapid Consolidation of Nanostructured TiC and TiC-TiAl Hard Materials by High-Frequency Induction Heating, Mater. Trans., 55, 1363 (2014)
[24] I. J. Shon, H. G. Jo, H. Kwon, Mechanochemical Synthesis and Rapid Consolidation of Binderless Nanostructured (Ti,V)C by Pulsed Current Activated Heating and Its Mechanical Properties, Korean J. Met. Mater., 52, 343 (2014)
[23] J. Kim, H. Kwon, J. H. Kim, K. M. Roh, D. Y. Shin, H. D. Jang, Elastic and electronic properties of partially ordered and disordered Zr(C1-xNx) solid solution compounds: A first principles calculation study, J. Alloy Compd., 619, 788 (2014)
[22] K. M. Roh, C. Y. Suh, J. M. Oh, W. Kim, H. Kwon, J. W. Lim, Comparison of deoxidation capability for preparation of low oxygen content powder from TiNi alloy scraps, Powder Technol., 253, 266 (2014)
[21] I. J. Shon, H. Kwon, H. S. Oh, Effect of Milling on Properties and Consolidation of AlN by High-Frequency Induction Heated Sintering, Electron. Mater. Lett., 10, 337 (2014)
[20] J. M. Oh, H. Kwon, W. Kim, J. W. Lim, Oxygen behavior during non-contact deoxidation of titanium powder using calcium vapor, Thin Solid Films, 551, 98 (2014)
[19] H. S. Kang, H. Kwon, I. J. Shon, Rapid Consolidation and Mechanical Properties of Binderless Nanostructured (W,Ti)C by High-Frequency Induction Heating, Mater. Trans., 54, 2301 (2014)
[18] H. Kwon, S. Jung, S. W. Cho, D. S. Kil, K. M. Roh, J. W. Lim, Solid-Solution Nanocrystallite Formation by High-Energy Milling, J. Nanosci. Nanotechnol., 13, 6165 (2013)
[17] H. Kwon, J. Kim, J. H. Yoo, S. W. Cho, Control of hydrogen storage properties of (La,Ce,Nd,Pr)(Ni,Co,Mn,Al)5 alloys with microstructural parameters, J. Alloy Compd., 570, 114 (2013)
[16] N. R. Park, K. I. Na, H. Kwon, J. W. Lim, I. J. Shon, Effect of NiAl3 on Mechanical Properties and Sintering of (W,Ti)C Hard Materials, Korean J. Met. Mater., 51, 753 (2013)
[15] H. G. Jo, H. Kwon, I. J. Shon, Simultaneous Synthesis and Rapid Consolidation of Nanostructured (Ti,Mo)C and Its Mechanical Properties, Kor. J. Mater. Res., 23, 620 (2013)
[14] I. J. Shon, H. S. Oh, H. Kwon, Mechanochemical Synthesis and Rapid Consolidation of Nanostructured (Ti,Al,V)C by Pulsed Current Activated Heating and Its Mechanical Properites, Mater. Trans., 54, 2155 (2013)
[13] I. J. Shon, H. S. Oh, J. W. Lim, H. Kwon, Mechanical properties and consolidation of binderless nanostructured (Ti,Cr)C from mechanochemically-synthesized powder by high-frequency induction heating sintering, Ceram. Int., 39, 9721 (2013)
[12] I. J. Shon, C. Y. Suh, S. Lee, K. M. Roh, H. Kwon, S. W. Cho, W. Kim, Bulk (Ti,Cr)N consolidated by pulsed current activated sintering and its mechanical properties, Ceram. Int., 39, 3441 (2013)
[11] J. Oh, H. Kwon, J. Lim, Recycling and Applications of Titanium Alloy Scraps, Clean Technol., 19, 75-83 (2013)
[10] H. Kwon, S. Kang, Stability domain of Ti(CN) in Ti-TiC-TiN, Mater. Lett., 68, 426 (2012)
[9] H. Kwon, J. H. Yoo, K. M. Roh, C. Y. Suh, W. B. Kim, S. W. Cho, Effect of particle size and microstructure on the hydrogen storage property in a V-Ti-Cr solid solution system, J. Alloy Compd., 535, 87 (2012)
[8] W. Kim, C. Y. Suh, S. W. Cho, K. M. Roh, H. Kwon, K. Song, A new method for the identification and quantification of magnetite–maghemite mixture using conventional X-ray diffraction technique, Talanta, 94, 348 (2012)
[7] 권한중, 유정현, 조성욱, 배터리용 희토합금의 개발 동향과 시장 현황, 정밀화학(한국정밀화학회지), 신년호, 31 (2012)
[6] H. Kwon, S. Kang, Microstructure and mechanical properties of TiC-WC-(Ti,W)C-Ni cermets, Mater. Sci. & Eng. A, 520, 75 (2009)
[5] H. Kwon, S. Kang, Stability Domains of TiO2-Ti3O5-Ti2O3-TiC/Ti(CN) Systems During Reduction Process, J. Am. Ceram. Soc., 92, 272 (2009)
[4] H. Kwon, S. Kang, Carbothermal reduction of Titanium monoxide (TiO), J. Ceram. Soc. Jpn., 116, 1154 (2008)
[3] H. Kwon, S. Kang, Effect of Milling on the Carbothermal Reduction of Oxide Mixture for (Ti,W)C-Ni, Mater. Trans., 49, 1594 (2008)
[2] S. Park, Y. J. Kang, H. Kwon, S. Kang, Synthesis of (Ti,M1,M2)(CN)–Ni nanocrystalline powders, Int. J. Refract. Met. H., 24, 115 (2006)
[1] H. Kwon, S. Kang, Instability of solid-liquid interface in transitional metal-carbide systems, J. Mater. Sci., 41, 4649 (2006)
[43] 원료 내 타이타늄이 배제된 2차원 맥신 제조용 맥스 분말 및 이에 의해 제조된 맥스 분말
[42] 경도 및 파괴인성이 향상된 초경합금 및 이의 제조방법
[41] 저온 탄화공정을 이용한 탄화규소 분말의 제조방법 및 이에 의해 제조된 탄화규소
[40] 점토 광물-맥신 복합체 및 이의 제조방법
[39] 산소 함량 4,000 ppm 이하이며 탄소 함량 15 wt% 미만인 바나듐 탄화물
[38] 바나듐 탄화물을 사용한 맥스와 맥신 및 이의 제조방법
[37] 저산소 바나듐 탄화물 및 이의 제조방법 (10-2611243)
[36] 산소함량이 감소한 맥스 전구체 및 맥신의 제조방법
[35] 맥스 전구체 및 맥신 나노 잉크의 제조방법 (10-2528394)
[34] 초경합금용 금속 바인더, 이의 제조방법 및 이를 이용하여 제조된 초경합금 (10-2551898)
[33] 니켈-레늄계 합금스크랩 전처리방법 (10-1825927)
[32] 하드 텅스텐 카바이드(WC) 스크랩의 파쇄 방법 (10-1549413)
[31] 무산소 분위기하에서의 하드 텅스텐 카바이드(WC) 스크랩의 파쇄 방법 (10-1572507)
[30] 밀스케일을 활용한 폐탈질촉매로부터 유가금속 분리 회수방법, 철 합금 제조방법 및 이에 따라 제조된 철 합금 (10-1780473)
[29] 폐탈질촉매로부터 유가금속 분리 회수방법, 알루미늄 합금 제조방법 및 이에 따라 제조된 알루미늄 합금 (10-1779348)
[28] 다공성 흡착 성형체 및 그 제조방법 (10-2059860)
[27] 일메나이트로부터 페로티타늄 제조방법 및 페로티타늄 제조용 조성물 (10-1923386)
[26] CDI를 이용한 고효율 리튬 회수 시스템 및 방법 (10-2285849)
[25] 금속 산화물의 환원 및 탄질화 열처리용 도가니 (10-1944524)
[24] 기계적 특성이 향상된 3원계 티타늄 탄질화물 소결체의 제조방법 및 이에 따라 제조되는 3원계 티타늄 탄질화물 소결체 (10-1450661)
[23] 저비용 AB5계 수소저장용 합금 및 이의 제조방법 (10-1441498)
[22] 저온 소결 공정을 이용한 TiC-Ni 서멧의 제조방법 (10-13646008)
[21] 바인더가 포함된 탄화물 및 탄질화물 분말 합성 방법 및 이에 따라 얻어지는 서멧트 (US9,238,854, JP5647284, 10-1248996)
[20] 평탄압을 제어할 수 있는 저비용 조성의 AB5계 수소 저장 합금의 제조 방법 (10-1299434)
[19] 평탄압의 제어가 가능한 AB5계 수소 저장 합금의 조성 설계 방법 (10-1268370)
[18] 서멧트용 탄화물 및 탄질화물 혼합 분말 합성 방법 및 이에 따라 얻어진 서멧트 (10-1249000)
[17] ZrC 첨가에 의해 입자 억제된 TiC-ZrC-Ni 서메트의 제조방법 (10-1790967)
[16] 탄질화티타늄-텅스텐 소결체 제조방법 및 이에 따라 제조된 탄질화티타늄-텅스텐 소결체 (10-1694528)
[15] 티타늄 스크랩 재활용 방법 및 이에 따라 제조되는 티타늄 탄질화물 (10-1705174)
[14] 단일 상의 복합 티타늄 탄질화물 제조방법 및 이에 따라 제조된 단일 상의 복합 티타늄 탄질화물 (10-1743132)
[13] 저산소와 고밀도를 갖는 티타늄 또는 티타늄 합금 소결체의 제조방법 (10-1431731)
[12] Ti-Mo 합금 스크랩을 이용한 3원계 티타늄 합금 분말의 제조방법 (10-1435481)
[11] 전류 밀도가 개선된 전해 셀, 및 이 셀을 포함하는 전해조의 제조 방법 (10-1284571)
[10] 전해용 양극 일체 셀 및 이것을 포함하는 전해조 (10-1261211)
[9] 티타늄 합금 스크랩으로부터 저산소 합금 분말의 제조 방법 (10-1259434)
[8] 페로바나듐을 활용한 티타늄 합금의 제조방법 및 이에 의해 제조된 티타늄 합금 (10-1488195)
[7] MH 합금 탱크 해석용 수치모델의 알고리즘 (10-1306584)
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