유일환 사진
유일환
영문이름
You, IlHwan
연구분야
토목구조, 콘크리트구조(공학박사)
직위(직급)
조교수
전화번호
063-270-2521
이메일
ih-you@jbnu.ac.kr
사이트
https://sites.google.com/view/ace-lab-jbnu/home
담당과목
콘크리트공학, 공업역학, 농업토목재료학 및 실험, 농토목시공학 등
연구실
농업생명과학대학 본관 119호

학력사항

고려대학교 박사

고려대학교 석사

상명대학교 학사

경력사항

- 2023.03 ~ 현재 전북대학교 지역건설공학과 교수
- 2022.03 ~ 2023.02 한국건설기술연구원 박사후연구원YS
- 2020.09 ~ 2022.02 고려대학교 미래건설환경융합연구소 연구교수
- 2019.09 ~ 2020.08 고려대학교 건축사회환경공학과 연구교수
- 2019.09 ~ 2020.02 배재대학교 드론·철도건설공학과 강사
- 2018.01 ~ 2018.02 Department of Civil & Environmental Engineering (CEE) at University of Illinois at Urbana-Champaign, 방문연구원

주요 연구분야

- 친환경 건설재료 기술개발 (CCUS, cementless composite 등)
- 고성능 건설재료 기술개발 (UHPC 및 내구성 콘크리트)
- 기능성 건설재료 기술개발 (Self-sensing, energy harvesting 등)

연구과제 수행실적(최근)

- 2022.06 ~ 2024.08, 한국전력연구원, 전력구 종합성능평가 기준 수립 및 자동화 기술 개발
- 2023.09 ~ 2024.03, 한국전력공사, 전력구터널 레일 침목 및 가설통행로 전력구조물 FRP 개발 연구용역
- 2023.08 ~ 2023.10, 한국건설기술연구원, CO2 나노버블 용해수에 의한 시멘트 클링커의 탄산화 반응 특성 평가 실험 용역
- 2023.08 ~ 2023.12, 한국건설기술연구원, 일축 인장하중을 받는 변형 감응형 나노광학센서의 변색 정량분석에 관한 실험 용역
- 2023.08 ~ 2023.11, 한국철도기술연구원, 전도성 나노소재 혼입 그라우팅의 차수성능 확보를 위한 최적시스템 구성 도출 용역
- 2023.08 ~ 2023.12, ㈜제이스코리아, 격납건물 열화손상 및 누설 특성 평가

논문(최근)

1. You, I., Park, J.-J., Lee, N., Ryu, G.-S., Kwark, J.-W. (2024.05) “Use of electric arc furnace oxidizing slag (EOS) and electric arc furnace reducing slag (ERS) powders in cement pastes for CO2 sequestrations”, Journal of Building Engineering, 108631.
2. Yoo, D.-Y., Banthia, N., You, I.*, and Lee, S.-J. (2024.04), “Recent developments in cementless ultra-high-performance concrete based on alkali-activated materials and industrial byproducts: A review”, Cement and Concrete Composites, 105470.
3. Lee, S., Kim, G., Oh, T., You, I., Wang, X., and Yoo, D.-Y. (2023.09.01), “The microstructure and mechanical properties of cementless ultra-high-performance geopolymer concrete considering geometrical properties of steel fiber”, Cement and Concrete Composites, 142, 105209.
4. Lee, Y., Seo, S., You, I., Yun, T., and Zi, G. (2023.04.01), “Prediction of calcium leaching resistance of fly ash blended cement composites using artificial neural network”, Computers and Concrete, 31(4), 315-325.
5. You, I., Seo, S., Kim, M., Lee, Y*. and Yoo, D.-Y. (2023.05), “ASR potential of alkali-activated soda-lime glass powder in the absence of calcium source”, Cement and Concrete Composites, 139, 105027.
6. You, I., Yoo, D.-Y., Lee, S.-J., Lee, Y. and Zi, G. (2023.03.10). "A combination of liquid display glass powder and slag in alkali-activated material". Construction and Building Materials, 369, 130527.
7. You, I., Lee, Y., Yoo, D.-Y.*, and Zi, G. (2022.10.01), “Influence of liquid crystal display glass powder on the tensile performance of ultra-high-performance fiber-reinforced concrete”, Journal of Building Engineering, 104901.
8. Yoo, D.-Y.*, You, I*., Banthia, N. and Zi. G. (2022.07), “Utilization of liquid crystal display (LCD) glass waste in concrete: A review”, Cement and Concrete Composites, 130, 104542.
9. Yoo, D.-Y.*, Lee, S., K., You, I.*, Oh, T., Lee, Y. and Zi. G. (2022.05.09), “Development of strain-hardening geopolymer mortar based on liquid-crystal display (LCD) glass and blast furnace slag”, Construction and Building Materials, 331, 127334.
10. Jiarui, L., Doh, J.-H., Dinh, H., Dominic E., Zi, G., and You, I. (2022.04.25.). " Effect of Si/Al molar ratio on the strength behavior of geopolymer derived from various industrial waste: A current state of the art review." Construction and Building Materials, 329, 127134.
11. Lee, S.-J., You, I.*, Kim, S., Shin, H.-O. and Yoo, D.-Y*. (2022.01), “Self-sensing capacity of ultra-high-performance fiber-reinforced concrete containing conductive powders in tension”, Cement and Concrete Composites, 125, 104331.
12. Lee, Y., Kim, D. S., Jin, S. W., Lee, H., Jeong, Y. R., You, I., Zi, G. and Ha, J. S. (2022.01), “Stretchable Array of CdSe/ZnS Quantum-Dot Light Emitting Diodes for Visual Display of Bio-signals”, Chemical Engineering Journal, 427, 130858.
13. Ra. Y.*, You, I.*, Kim, M., Jang, S., Cho, S., Kam, D., Lee, S.-J. and Choi, D. (2021.11), “Toward Smart Net Zero Energy Structures: Development of Cement-based Structural Energy Material for Contact Electrification driven Energy Harvesting and Storage”, Nano Energy, 89, Part A, 106389. * represents that they contributed to this publication equally.
14. Oh, T., You, I., Banthia, N. and Yoo, D.-Y. (2021.09), “Deposition of nanosilica particles on fiber surface for improving interfacial bond and tensile performances of ultra-high-performance fiber-reinforced concrete”, Composite Part B, 221(15), 109030.
15. You, I., Yoo, D.-Y., Doh, J.-H., and Zi, G. (2021.04), “Performance of glass-blended cement produced by intergrinding and separate grinding methods”, Cement and Concrete Composites, 118, 103937.
16. Yoo, D.-Y., You, I.* and Zi, G. (2021.01.10), “Effects of waste liquid-crystal display glass powder and fiber geometry on the mechanical properties of ultra-high-performance concrete”, Construction and Building Materials, 266, 120938.
17. Yoo, D.-Y. and You, I.* (2021.01), “Liquid crystal display glass powder as a filler for enhancing steel fiber pullout resistance in ultra-high performance concrete”, Journal of Building Engineering, 33, 101846.
18. You, I., Lee, S.-J. Zi, G. and Lim. D. (2020.12.16), “Influence of Carbon Fiber Incorporation on Electrical Conductivity of Cement Composites” Applied Science, 10, pp. 8993.
19. Lee, S.-J, Ahn, D., You, I., Yoo, D.-Y. and Kang, Y.-S. (2020.11), “Wireless cement-based sensor for self-monitoring of railway concrete infrastructures”, Automation in Construction, 119.
20. You, I., Yoo, D, David A. Lange and Zi, G. (2019.11.1), “Durability of Concrete Containing Liquid Crystal Display Glass Powder for Pavement.”, ACI Materials Journal, 116(6), pp. 87-94.
21. Yoo, D., Kim, S., Lee, J., You, I.* and Lee, S.-J. (2019.08.30). "Implication of calcium sulfoaluminate-based expansive agent on tensile behavior of ultra-high-performance fiber-reinforced concrete", Construction Building Materials, 217(30), pp. 679-693.
22. Zhu, X., Zi, G., Sun, L. and You, I. (2019.04) “A simplified probabilistic model for the combined action of carbonation and chloride ingress”, Magazine of Concrete Research, 71(7), pp. 327-340.
23. Yoo, D., You, I., Zi, G. and Lee, S.-J. (2019.02). "Effects of carbon nanomaterial type and amount on self-sensing capacity of cement paste", Measurement, 134, pp.750-761.
24. Yoo, D., You, I., Youn, H. and Lee, S.-J. (2018.03.21) “Electrical and piezoresistive properties of cement composites with carbon nanomaterials”, Journal of composites materials, 52(24), pp. 3325-3340.
25. Yoo, D., You, I. and Lee, S.-J. (2018.02) “Electrical and piezoresistive sensing capacities of cement paste with multi-walled carbon nanotubes”, Archives of Civil and Mechanical Engineering 18(2), pp. 371-384.
26. Lee, S.-J., You, I., Zi, G. and Yoo, D.-Y., (2017.11.02) “Experimental investigation of the piezoresistive properties of cement composites with hybrid carbon fibers and nanotubes”, Sensors 17(11), 2516.
27. You, I., Yoo, D., Kim S., Kim M-J. and Zi, G., (2017.10.29) “Electrical and self-sensing properties of ultra-high-performance fiber-reinforced concrete with carbon nanotubes.”, Sensors 17(11), 2481
28. Yoo, D., You, I. and Lee, S.-J. (2017.05.08), “Electrical Properties of Cement-Based Composites with Carbon Nanotubes, Graphene, and Graphite nanofibers”, Sensors 17(5), 1064.
29. Hong, S. Y., Lee, Y. H., Part, H., Jin, S. W., Jeong, Y. R., Yun, J., You, I., Zi, G., and Ha, J. S. (2016.02.03). "Stretchable active matrix temperature sensor array of polyaniline nanofibers for electronic skin." Advanced Materials 28(5), 930-935.
30. You, I., Choi, J., Lange, D. A., and Zi, G. (2016.02.01). "Pozzolanic reaction of the waste glass sludge incorporating precipitation additives." Computers and concrete 17(2), 255-269.