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張楠

(山東大學教授)

鎖定
張楠,博士,教授,博士生導師,山東大學齊魯青年學者,山東省優秀青年科學基金項目(海外)獲得者。先後參與(合作主持)美國NSF、DOE及美國-秘魯政府間合作項目等基礎及重大科研攻關項目5項,發表學術論文40餘篇,其中第一/通訊作者SCI收錄20篇,授權發明及實用新型專利6項,並擔任岩土工程、土木工程材料等領域多個SCI國際期刊的審稿專家。2022年10月進入山東大學土建與水利學院工作,主要從事地聚物混凝土、結構新材料研發、固廢資源化、土-結構相互作用以及結構健康監測等方面的研究工作。 [2] 
中文名
張楠 [2] 
畢業院校
重慶交通大學 [2] 
畢業院校
河海大學 [2] 
美國俄勒岡州立大學 [2] 
學位/學歷
博士 [2] 

目錄

  1. 1 人物經歷
  2. 教育背景
  3. 工作經歷
  4. 2 研究方向
  5. 3 科研項目
  6. 4 發表論文

張楠人物經歷

張楠教育背景

  • 2013.09-2018.06 美國俄勒岡州立大學-土木與建築工程系,土木(岩土)工程,博士 導師: T. Matthew Evans 教授
  • 2010.09-2013.06 河海大學-水利水電學院,水工結構工程,工學碩士 導師:蘇懷智教授
  • 2006.09-2010.06 重慶交通大學-河海學院,水利水電工程,工學學士 [1] 

張楠工作經歷

  • 2022.10- 山東大學土建與水利學院,教授、博士生導師
  • 2019.06-2022.07 美國科羅拉多礦業大學土木與環境工程系,Research Associate
  • 2018.06-2019.05 美國俄勒岡州立大學太平洋海洋可再生能源研究中心(PMEC),博士後研究員
  • 2015.01-2016.01 美國俄勒岡州立大學土木與建築工程系,教學助理(兼職) [1] 

張楠研究方向

1. 固體廢物的資源化利用
2. 微觀岩土力學
3. 海洋岩土工程
4. 水工結構安全工程 [1] 

張楠科研項目

  1. Technological Solutions for Production of Construction Materials from Sulfidic Mine Tailings of La Libertad State, 秘魯政府及秘魯特魯希略國立大學,資助金額65萬美元, 主要參與人,執行時間: 04/01/2022-07/31/2022;
  2. Development of Sustainable and Innovative Solutions for Reuse of Arequipa Mine Tailings as Construction Materials, 秘魯政府及秘魯聖奧古斯丁國立大學,資助金額120萬美元, 主要參與人,執行時間: 01/01/2021-07/31/2022;
  3. Sustainable Mining through Transformation of Mining Liabilities into Benefits in Arequipa Region, Peru. 秘魯政府及秘魯聖奧古斯丁國立大學,資助金額40萬美元, 主要參與人,執行時間: 06/2019-12/2020;
  4. Advanced Laboratory and Field Arrays (ALFA) for Marine Energy (Part IV): Robust Models for Design of Offshore Anchoring Systems, 美國國家能源部,資助金額60萬美元,主要參與人, 執行時間:01/2015-05/2019;
  5. Development of Algorithms for the Quantification and Simulation of Three-Dimensional Microstructure in Granular Materials , 美國自然科學基金委員會,資助金額8萬美元,主要參與人,執行時間: 09/2013-12/2014. [1] 

張楠發表論文

  1. Zhang, N., Hedayat, A., Figueroa, L., Li, H., Bolaños Sosa, H., Tupa, N., Morales, I. Y., and Loza, R. S. C (2022). Experimental studies on the durability and leaching properties of the alkali-activated tailings subjected to different environmental conditions, Cement and Concrete Composites, 130 104531 (JCR一區)
  2. Zhang, N., Hedayat, A., Han, S., Ma, S., Bolaños Sosa, H., Tupa, N., Morales, I. Y., and Loza, R. S. C (2022). Fracture properties of tailings-based geopolymer incorporated with class F fly ash under mode I loading conditions, Engineering Fracture Mechanics, 271, 108646. (JCR一區)
  3. Zhang, N., Hedayat, A., Perera-Mercado, Y., Sosa, H. G. B., Bernal, R. P. H., Tupa, N., Morales, I. Y., and Loza, R. S. C. (2022). Including class F fly ash to improve the geopolymerization effects and the compressive strength of mine tailings-based geopolymer. Journal of Materials in Civil Engineering. 34(11), 04022313
  4. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., Morales, I. Y., Loza, R. S. C. (2021). On the incorporation of class F fly-ash to enhance the geopolymerization effects and the splitting tensile strength of the gold mine tailings-based geopolymer, Construction and Buildings Materials, 308, 125112. (JCR一區)
  5. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., Morales, I. Y., Loza, R. S. C. (2021). Fracture properties of the gold mine tailings-based geopolymer under mode I loading condition through semi-circular bend tests with digital image correlation, Theoretical and Applied Fracture Mechanics, 116, 103116. (JCR一區)
  6. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., Morales, I. Y., and Loza, R. S. C. (2021). Crack evolution in the Brazilian disks of the mine tailings-based geopolymers measured from digital image correlations: An experimental investigation considering the effects of class F fly ash additions. Ceramics International, 47(22), 32382-32396. (JCR一區)
  7. Zhang, N., Hedayat, A., Sosa, H. G. B., Cárdenas, J. J. G., Álvarez, G. E. S., and Rivera, V. B. A. (2021). Specimen size effects on the mechanical behaviors and failure patterns of the mine tailings-based geopolymer under uniaxial compression. Construction and Building Materials, 281, 122525. (JCR一區)
  8. Zhang, N., Hedayat, A., Sosa, H. G. B., Cárdenas, J. J. G., Álvarez, G. E. S., and Rivera, V. B. A. (2021). Damage evaluation and deformation behavior of mine tailing-based Geopolymer under uniaxial cyclic compression. Ceramics International, 47(8), 10773-10785. (JCR一區)
  9. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., and Morales, I. Y. (2022). Mixed-mode fracture of compacted tailing soils. I: Fracture toughness. Theoretical and Applied Fracture Mechanics. (Under Revision) (JCR一區)
  10. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., Morales, I. Y., and Loza, R. S. C. (2022). Mixed-mode fracture of compacted tailing soils. II: Crack properties from full-field displacement fields. Theoretical and Applied Fracture Mechanics (Under Revision) (JCR一區)
  11. Zhang, N., Hedayat, A., Sosa, H. G. B., Tupa, N., Morales, I. Y., and Loza, R. S. C. (2021). Mechanical and fracture behaviors of compacted gold mine tailings by semi-circular bending tests and digital image correlation. Construction and Building Materials, 306, 124841. (JCR一區)
  12. Zhang, N., Hedayat, A., Sosa, H., Tunnah, J., Cárdenas, J., and Álvarez, G. E. S. (2021). Estimation of the mode I fracture toughness and evaluations on the strain behaviors of the compacted mine tailings from full-field displacement fields via digital image correlation. Theoretical and Applied Fracture Mechanics, 114, 103014. (JCR一區)
  13. Zhang, N., Zhao, S., Evans, T.M, Du, Y. Wang, H. and Lian, Y. (2022). Micromechanical behaviors and fabric within the immediate influence zone of granular-continuum interfaces. European Journal of Environmental and Civil Engineering, 26(3), 1158-1181.
  14. Zhang, N., Hedayat, A., Han, S., Yang, R., Sosa, H. G. B., Cárdenas, J. J. G., and Álvarez, G. E. S.(2021). Isotropic compression behavior of granular assembly with non-spherical particles by X-ray computed tomography and discrete element modeling. Journal of Rock Mechanics and Geotechnical Engineering, 13, 972-984. (JCR一區)
  15. Zhang, N., T. M. Evans, Zhao, S., Du, Y., and Zhang, L. (2020). Discrete element method simulations on keying process of offshore plate anchor. Marine Georesources & Geotechnology, 38(6), 716-729.
  16. Zhang, N., and Evans, T. M. (2019). Discrete numerical simulations of torpedo anchor installation in granular soils. Computers and Geotechnics, 108, 40-52. (JCR一區)
  17. Evans, T.M. and Zhang, N.* (2019). Three dimensional simulations of plate anchor pullout in granular materials. International Journal of Geomechanics, 19(4), 04019004.
  18. Zhang, N. and T.M. Evans (2018) Three-dimensional discrete element method simulations of interface shear. Soils and Foundations, 58(4), 941-956.
  19. Zhao, S., Zhang, N., Zhou, X., and Zhang, L. (2017). Particle shape effects on fabric of granular random packing. Powder Technology. 310: 175-186.
  20. Zhang, N., Wang, H., Ma, S., Su, H., and Han, S. (2022). Seismic holding behaviors of inclined shallow plate anchor embedded in submerged coarse-grained soils. Geomechanics and Engineering, 28(2), 197-207.
  21. Su, H., Zhang, N. and Li, H. (2018). Concrete piezoceramic smart module pairs-based damage diagnosis of hydraulic structure. Composite Structures, 183, 582-593. (JCR一區)
  22. Zhang, N., and Su, H. (2017). Application assessments of concrete piezoelectric smart module in civil engineering. Smart Structures and Systems, 19(5), 499-512.
  23. Su, H., Zhang, N., Wen, Z., and Li, H. (2016). Experimental study on obtaining hydraulic concrete strength by use of concrete piezoelectric ceramic smart module pairs. Journal of Intelligent Material Systems and Structures, 27(5), 666-678.
  24. Su, H., Zhang, N., Yang, M., Wen, Z., and Xie, W. (2015). Experimental study on natural vibration frequency identification of hydraulic concrete structure using concrete piezoceramic smart module. Journal of Vibro-engineering, 17(7) [1] 
參考資料