SWCNT-thin-film-enabled fiber sensors for lifelong structural health monitoring of polymeric composites - From manufacturing to utilization to failure

Carbon

Volumn 76, Issue , 2014, Pages 321-329

  Luo, Sida ^a   Obitayo, Waris ^a   Liu, Tao ^a  

^a FLORIDA STATE UNIVERSITY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

BENDING (DEFORMATION); FIBERS; INDUSTRIAL ENGINEERING; LAMINATED COMPOSITES; MANUFACTURE; PRODUCTION ENGINEERING; REINFORCED PLASTICS; SCANNING ELECTRON MICROSCOPY; SINGLE-WALLED CARBON NANOTUBES (SWCN); STRUCTURAL HEALTH MONITORING; TENSILE TESTING;

DEFORMATION MODES; MANUFACTURING PROCESS; ORIENTATIONS AND LOCATIONS; PIEZO-RESISTIVE BEHAVIOR; POLYMERIC COMPOSITES; PREPREG LAMINATES; SENSING PERFORMANCE; SINGLEWALLED CARBON NANOTUBE (SWCNT);

SENSORS;

EID: 84901808608     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbon.2014.04.083     Document Type: Article

References (41)

1. C. Boller, F. Chang, and Y. Fujino Encyclopedia of Structural Health Monitoring 2009 Wiley Hoboken NJ
2. F. Chang Structural Health Monitoring 2013 - a Roadmap to Intelligent Structures 2013 DEStech Publications Inc. Lancaster PA
3. A.L. Window, and G.S. Holister Strain Gauge Technology 2nd ed. 1992 Elsevier Science Publishers Ltd New York NY
4. L. Moletn, and B. Aktepe Review of fatigue monitoring of agile military aircraft Fatigue Fract Eng Mater Struct 23 2000 767 785 (Pubitemid 32874932)
5. S.S. Kessler, S.M. Spearing, and C. Soutis Damage detection in composite materials using lamb wave methods Smart Mater Struct 11 2002 269 278 (Pubitemid 34474812)
6. X. Qing, S.J. Beard, A. Kumar, T.K. Ooi, and F. Chang Built-in sensor network for structural health monitoring of composite structure J Int Mat Sys Struct 18 2007 39 49 (Pubitemid 44975108)
7. N. Takeda Summary report of the structural health-monitoring project for smart composite structure systems Adv Comp Mat 10 2001 107 118 (Pubitemid 34138845)
8. G. Kister, L. Wang, B. Ralph, and G.F. Fernando Self-sensing E-glass fibers Opt Mat 21 2003 713 727
9. B. Lee Review of the present status of optical fiber sensors Opt Fiber Technol 9 2003 57 79 (Pubitemid 36544960)
10. B. Culshaw Optical fiber sensor technologies: opportunities and - perhaps - pitfalls J Lightwave Technol 22 2004 39 50
11. D. Placko, and I. Dufour A focused-field eddy current sensor for nondestructive testing IEEE Trans Mag 29 1993 3192 3194
12. D.J. Sadler, and C.H. Ahn On chip eddy current sensor for proximity sensing and crack detection Sens Actuator 91 2001 340 345
13. E. Kannan, B.W. Maxfield, and K. Balasubramaniam SHM of pipes using torsional waves generated by in situ magnetostrictive tapes Smart Mater Struct 16 2007 2505 2515 (Pubitemid 350175580)
14. R.J. Grow, Q. Wang, J. Cao, D.W. Wang, and H.J. Dai Piezoresistance of carbon nanotubes on deformable thin-film membranes Appl Phys Lett 86 2005 93104 93107
15. C. Stampfer, A. Jungen, R. Linderman, D. Obergfell, S. Roth, and C. Hierold Nano-electromechanical displacement sensing based on single-walled carbon nanotubes Nano Lett 6 2006 1449 1453 (Pubitemid 44195326)
16. E.D. Minot, Y. Yaish, V. Sazonova, J.Y. Park, M. Brink, and P.L. McEuen Tuning carbon nanotube band gaps with strain Phys Rev Lett 90 2003 156401
17. I. Kang, M.J. Schulz, J.H. Kim, V. Shanov, and D. Shi A carbon nanotube strain sensor for structural health monitoring Smart Mater Struct 15 2006 737 748 (Pubitemid 43781562)
18. K.J. Loh, J. Kim, J.P. Lynch, N.W.S. Kam, and N.A. Kotov Multifunctional layer-by-layer carbon nanotube-polyelectrolyte thin films for strain and corrosion sensing Smart Mater Struct 16 2007 429 438 (Pubitemid 46402804)
19. M.D. Rein, O. Breuer, and H.D. Wagner Sensors and sensitivity: carbon nanotube buckypaper films as strain sensing devices Compos Sci Technol 71 2011 373 381
20. E.T. Thostenson, and T.W. Chou Real-tim in situ sensing of damage evolution in advanced fiber composites using carbon nanotube networks Nanotech 19 2008 215713
21. E.T. Thostenson, and T.W. Chou Carbon nanotube networks: sensing of distributed strain and damage for life prediction and self healing Adv Mater 18 2006 2837 2841 (Pubitemid 44759486)
22. L. Gao, E.T. Thostenson, Z. Zhang, and T.W. Chou Sensing of damage mechanisms in fiber-reinforced composites under cyclic loading using carbon nanotubes Adv Funct Mater 19 2009 123 130
23. H. Zhao, Y. Zhang, P.D. Bradford, Q. Zhou, Q. Jia, and F. Yuan et al. Carbon nanotube yarn strain sensors Nanotechnology 21 2010 305502
24. J.L. Abot, Y. Song, M.S. Vatsavaya, S. Medikonda, Z. Kier, and C. Jayasinghe et al. Delamination detection with carbon nanotube thread in self-sensing composite materials Compos Sci Technol 70 2010 1113 1119
25. J. Sebastian, N. Schehl, M. Bouchard, M. Boehle, L. Li, and A. Lagounov et al. Health monitoring of structural composites with embedded carbon nanotube coated glass fiber sensors Carbon 66 2014 191 200
26. J. Zhang, J. Liu, R. Zhuang, E. Mader, G. Heinrich, and S. Gao Single MWNT-glass fiber as strain sensor and switch Adv Mater 23 2011 3392 3397
27. S. Luo, and T. Liu Structure-property-processing relationships of single-wall carbon nanotube thin film piezoresistive sensors Carbon 59 2013 315 324
28. S. Luo, and T. Liu SWCNT/graphite nanoplatelet hybrid thin films for self-temperature-compensated, highly sensitive, and extensible piezoresistive sensors Adv Mater 25 39 2013 5650 5657
29. M. Hayaty, M.H. Beheshty, and M. Esfandeh Cure kinetics of a glass/epoxy prepreg by dynamic differential scanning calorimetry J Appl Polym Sci 120 2011 62 69
30. T. Liu, S. Luo, Z. Xiao, C. Zhang, and B. Wang Preparative ultracentrifuge method for characterization of carbon nanotube dispersions J Phys Chem C 112 49 2008 19193 19202
31. S. Luo, T. Liu, and B. Wang Comparison of ultrasonication and microfluidization for high throughput and large-scale processing of SWCNT dispersions Carbon 48 10 2010 2992 2994
32. T. Liu, Z. Xiao, and S. Luo In-situ structural characterization of single-walled carbon nanotubes in dispersion S. Yellampalli, Carbon nanotubes - synthesis, characterization, applications 2011 InTech 241 264
33. S. Luo, T. Liu, S.M. Benjamin, and J.S. Brooks Variable range hopping in single-wall carbon nanotube thin films: a processing-structure-property relationship study Langmuir 29 27 2013 8694 8702
34. M.S. Dresselhaus, G. Dresselhaus, R. Saito, and A. Jorio Raman spectroscopy of carbon nanotubes Phys Rep 409 2005 47 99 (Pubitemid 40317386)
35. J.R. Wood, Q. Zhao, M.D. Frogley, E.R. Meurs, A.D. Prins, and T. Peijs et al. Carbon nanotubes: from molecular to macroscopic sensors Phys Rev B 62 2000 7571 7575 (Pubitemid 32323652)
36. U.D. Venkateswaran, E.A. Brandsen, U. Schlecht, A.M. Rao, E. Richter, and I. Loa et al. High pressure studies of the Raman-active phonons in carbon nanotubes Phys Status Solidi b 223 2001 225 236
37. P.K. Mallick Fiber-reinforced composites: materials, manufacturing, and design 3rd ed. 2007 Marcel Dekker New York, NY
38. K.G. Bang, J.W. Kwon, D.G. Lee, and J.W. Lee Measurement of the degree of cure of glass fiber-epoxy composites using dielectrometry J Mater Process Tech 113 2001 209 214 (Pubitemid 32518369)
39. N. Hu, Y. Karube, M. Arai, T. Watanabe, C. Yan, and Y. Li et al. Investigation on sensitivity of polymer/carbon nanotube composite strain sensor Carbon 48 2010 680 687
40. Hu.N. Alamusi, H. Fukunaga, S. Atobe, Y. Liu, and J. Li Piezoresistive strain sensors made from carbon nanotubes based polymer nanocomposites Sensors 11 2011 10691 10723
41. T.C. Theodosiou, and D.A. Saravanos Numerical investigation of mechanisms affecting the piezoresistive properties of CNT-doped polymers using multi-scale models Compos Sci Technol 70 2010 1312 1320