Seoul National Univ. DMSE
Notice

Seminar & Colloquium

Seminar & Colloquium
[세미나: 7월 10일(월), 오후 3시 ] Prof. Yong K. Kim, Bioengineering, University of Massachusetts Dartmouth

[세미나: 7월 10일(월), 오후 3시 ] Prof. Yong K. Kim, Bioengineering, University of Massachusetts Dartmouth

 

 

| Title | A Theoretical Modeling of Electro-Shear Behavior of Carbon Nanotubes Embedded Epoxy Nanocomposites

 

| Speaker | Prof. Yong K. Kim, Bioengineering, University of Massachusetts Dartmouth

 

 

 

* EDUCATION 

 

- 1981  Ph. D. in Fiber and Polymer Science, North Carolina State University

- 1974  M. S. in Textile Engineering, Seoul National University

- 1970  B. S. in Textile Engineering, Seoul National University

 

 

 

 

* EXPERIENCE

- 2003 ~ present.   Chancellor Professor, University of Massachusetts Dartmouth

- 1993 ~ 2003.  Full Professor, University of Massachusetts Dartmouth

- 1988 ~ 1993.  Associate Professor, University of Massachusetts Dartmouth

- 1981 ~ 1988.  Assistant Professor, University of Massachusetts Dartmouth

- Certified Textile Consultant and the Fellow of the Textile Institute (C Text, FTI)

- Full member of Sigma Xi, ASME, American Chemical Society, American Textile Chemist and Colorist (AATCC), the Fiber Society, AACSB, SAMPE and Imaging Science and Technology (IS&T))

 

 

 

| Date | Monday, July 10th, 2023

| Time | 15:00 ~

| Venue | 33동 228호(해동 오디토리움)

 

 

 

| Abstract |

 

Theoretical modeling and experimental validation for electro-shear behavior of carbon nanotubes (CNTs) embedded epoxy under quasi-static shear loading are performed. The theoretical modeling incorporates electron tunneling between CNTs and the electrical resistance change due to shear deformation of the epoxy matrix between CNTs. Two different contact types (head to head and overlap) and three different deformation connections (Type-I, Type-II, and Type-III) are considered to model the electrical network. Using the constitutive relations, the model relates the matrix deformation between the CNTs to the macroscale deformation of the composite. To validate the modeling results, experiments are performed using a four circumferential ring probe method. A parametric study is performed to investigate the effect of the total number of initial contact types, ratio of contact types, and number of potential Type-II deformation connections on electrical response. The theoretical predictions are validated with experiments for the first two stages of deformation and an optimal combination of deformation connections are obtained to have a close match with experimental findings. 

 

 

 

 

 

| Host |  ​​​​곽승엽​​​​​​ 교수 (02-880-2257)


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