WANG Kaifa
I am particularly interested in using modified continuum models to model and simulation of nanostructures.6 I have published 30 SCI papers in international journals, such as Energy, Composites Structure, IJMS,nanotechnology、Journal of Applied Physics, EPL, International Journal of Non-Linear Mechanics and Finite Elements in Analysis and Design, and gained more than 291 citations.
1. Using modified continuum models (such as surface elasticity model and nonlocal elasticity theory) to study the bending and vibration behaviors of nanobeams and nanoplates;
2. Nonlinear behaviors of nanostructures, such as nonlinear vibration and postbuckling of nanoplates and the nonlinear pull-in instability of nanoswitches;
3. Electromechanical coupling behavior of piezoelectric nanostructures;
4. Vibration-based energy harvesters.
Harbin Institute of Technology, Engineering Mechanics, PhD
Harbin Institute of Technology (Shenzhen)
1. K.F. Wang , B.L. Wang, Electrostatic potential in a bent piezoelectric nanowire with consideration of size-dependent piezoelectricity and semiconducting characterization, nanotechnology, accepted
2. K.F. Wanga, B.L. Wang, S. Zenga,Analysis of an array of flexoelectric layered nanobeams for vibration energy harvesting, Composite Structures, 2018, 187 48–57
3. K.F. Wang , B.L. Wang, Energy gathering performance of micro/nanoscale circular energy harvesters based on flexoelectric effect, Energy 149 (2018) 597-606
4. Z.G. Yan , B.L. Wang , K.F. Wang (通讯作者) Thermal effects on the structural response of planar serpentine interconnects, International Journal of Mechanical Sciences 135 (2018) 23–30
5. Wanga, K.F., Wanga, B.L.*, Xu, M.H. , Yu A.B. Influences of surface and interface energies on the nonlinear vibration of laminated nanoscale plates. Composite Structures, 2018,183 423–433
6. Wang K F, Zeng S, Wang B L. Large amplitude free vibration of electrically actuated nanobeams with surface energy and thermal effects. International Journal of Mechanical Sciences, 2017,131–132, 227–233
7. Wang, K.F.*, Wang, B.L. Non-linear flexoelectricity in energy harvesting. International Journal of Engineering Science 2017,116, 88–103
8. Wang,K.F.*, Wang, B., Zhang C. Surface energy and thermal stress effect on nonlinear vibration of electrostatically actuated circular micro-/nanoplates based on modified couple stress theory. Acta Mech. 2017, 228 (1), 129–140
9. Wang, K.F.*, Wang, B.L. An analytical model for nanoscale unimorph piezoelectric energy harvesters with flexoelectric effect, Composite Structures, 2016, 153:253-261
10. Wang, K.F.*, Wang, B.L. Nonlinear fracture mechanics analysis of nano-scale piezoelectric double cantilever beam specimens with surface effect. European Journal of Mechanics - A/Solids, 2016, 56: 12-18
11. Wang, K.F.*, Wang, B.L., Kitamura, T. A review on the application of modified continuum models in modeling and simulation of nanostructures, Acta Mechanica Sinica, 2016,32(1):83-100.
12. Wang, K.F.*, Wang, B.L. Zeng,S. Small scale effect on the pull‑in instability and vibration of graphene sheets, Microsyst Technol, 2016,doi 10.1007/s00542-016-2914-3
13. Wang, K.F., Wang, B.L.* Vibration modeling of carbon nanotube based biosensors incorporating thermal and nonlocal effects, Journal of Vibration and Control, 2016, 22(5):1405-1414.
14. Wang, K.F.*, Wang, B.L. A general model for nano-cantilever switches with consideration of surface effects and nonlinear curvature, Physica E, 2015, 66,197–208.
15. Wang, K.F.*, Wang, B.L. Timoshenko beam model for the vibration analysis of a cracked nanobeam with surface energy, Journal of Vibration and Control, 2015, 21(12), 2452-2464
16. Wang, K.F.*, Kitamura, T., Wang, B.L. Nonlinear pull-in instability and free vibration of micro/nanoscale plates with surface energy- A modified couple stress theory model, International Journal of Mechanical Sciences, 2015, 99: 288–296.
17. Wang, K.F., Wang, B.L.* Influence of surface energy on the non-linear pull-in instability of nano-switches, International Journal of Non-Linear Mechanics, 2014, 59, 69-75 .
18. Wang, K.F.*, Wang, B.L. Effect of surface energy on the sensing performance of bridged nanotube-based micro-mass sensors, Journal of Intelligent Material Systems and Structures, 2014, 25(17), 2177–2186.
19. Wang, K.F.*, Wang, B.L. Surface effects on the energy-generating performance of piezoelectric circular nanomembrane energy harvesters under pressure loading, EPL, 2014, 108(1),17001
20. Wang, B.L.*, Wang, K.F. Vibration analysis of embedded nanotubes using nonlocal continuum theory, Composites: Part B, 2013, 47: 96–101.
21. Wang, B.L., Wang, K.F.* Effect of surface residual stress on the fracture of double cantilever beam fracture toughness specimen, Journal of Applied Physics, 2013, 113(15):153502.
22. Wang, K.F., Wang, B.L.* Effect of surface energy on the non-linear postbuckling behavior of nanoplates, International Journal of Non-Linear Mechanics, 2013,55, 19-24.
23. Wang, K.F., Wang, B.L.* A finite element model for the bending and vibration of nanoscale plates with surface effect, Finite Elements in Analysis and Design, 2013, 74,22-29
24. Wang, K.F., Wang, B.L.* Effects of surface and interface energies on the bending behavior of nanoscale multilayered beams, Physica E, 2013, 54: 197–201.
25. Wang, K.F., Wang, B.L.*. The electromechanical coupling behavior of piezoelectric nanowires: Surface and small-scale effects, EPL, 2012, 97(6), 66005.
26. Wang, K.F., Wang, B.L.*Effects of residual surface stress and surface elasticity on the nonlinear free vibration of nanoscale plates, Journal of Applied Physics, 2012, 112(1), 013520
27. Wang, K.F., Wang, B.L.* Vibration of nanoscale plates with surface energy via nonlocal elasticity, Physica E, 2011, 44(2), 448-453.
28. Wang, K.F., Wang, B.L.* Combining effects of surface energy and non-local elasticity on the buckling of nanoplates, Micro & Nano Letters, 2011, 6(11):941-943.
K.F. Wang, B.L. Wang. Surface Effects on the Buckling of Piezoelectric Nanobeams. International Conference on Nanotechnology Technology and Advanced Materials (ICNTAM 2012), April 12-13, 2012, Hong Kong, Advanced Materials Research Vol. 486 (2012) pp 519-523.(EI)