•B.S., Nanjing University of Aeronautics & Astronautics
•M.S., South China University of Technology
•Ph.D., The University of Sydney
•Mechanics of Composite Materials
•Mechanics of Nanostructured Materials
•Mechanical/Physical Properties of Heterogeneous Media
Composite materials are widely and increasingly used in today’s industry; for example, most advanced airplanes are largely made of composite materials. Mechanics of composite materials is concerned with the understanding and prediction of deformation, failure and properties of heterogeneous materials. Natural biomaterials are also inherently heterogeneous. Mechanics of biomaterials is coupled with their functions; and natural biomaterials are paradigms for design of engineering materials and structures with novel properties. Many fundamental and interesting problems of composite materials and biomaterials, which are essential to the design, good performance and integrity of modern engineering structures and products, remain to be explored.
The research of Jianxiang Wang group is focused on the following areas:
(1) prediction of effective mechanical properties such as elastic constants and overall stress-strain relations of composite materials and heterogeneous materials, including nanocomposites , particle-filled composites, short fibre-reinforced composites, and continuous fibre-reinforced composites;
(2) prediction of effective generalized conductivities (thermal, electric, etc) of heterogeneous media;
(3) microstructures and mechanics of biomaterials;
(4) damage and failure analyses of composite materials and structures in aerospace engineering and energy technology.
Professional Honors and Awards
•Excellent Teacher of Beijing (2009)
•Changjiang Scholar Professor of the State Education Ministry of China (since 2008)
•Outstanding Youth Science Fund, awarded by the National Natural Science Foundation of China (2005).
•Science and Technology Award for Young Investigators, awarded by the CSTAM (2002).
•Trans-Century Talent Fund, awarded by the State Education Ministry of China (2001).
•Member of Congress Committee of the International Union of Theoretical and Applied Mechanics (IUTAM)
•Secretary General: The 23rd International Congress of Theoretical and Applied Mechanics of IUTAM (ICTAM2012, Beijing)
•Secretary General (2007-2010): Chinese Society of Theoretical and Applied Mechanics (CSTAM)
•Secretary General (2007-2011): Beijing International Center for Theoretical and Applied Mechanics (BICTAM)
•Editorial Board: Acta Mechanica Sinica, International Journal of Applied Mechanics, Advanced Modeling and Simulation in Engineering Sciences (Associate Editor), Acta Mechanica Solida Sinica (Associate Editor)
1. Du, F., Huang, J.Y., Duan, H.L., Xiong, C.Y. and Wang, J. 2016. Surface stress of graphene layers supported on soft substrate. Scientific Reports 6, 25653.
2. Dong, H., Li, Z., Wang, J. and Karihaloo, B.L. 2016. A new fatigue failure theory for multidirectional fibre-reinforced composite laminates with arbitrary stacking sequence. International Journal of Fatigue 87, 294—300.
3. Wang, J., Tong, L. and Karihaloo, B. L. 2016. A bridging law and its application to the analysis of toughness of carbon nanotube-reinforced composites and pull-out of fibres grafted with nanotubes. Archives of Applied Mechanics 86, 361—373.
4. Du, F., Duan, H. L., Xiong, C. Y. and Wang, J. 2015. Substrate wettability requirement for the direct transfer of graphene. Applied Physics Letters 107, Art 143109.
5. Shi, Y., Ji, Y., Sun, H., Hui, F., Hu, J., Wu, Y., Fang, J., Lin, H., Wang, J., Duan, H., and Lanza, M. 2015. Nanoscale characterization of PM2.5 airborne pollutants reveals high adhesiveness and aggregation capability of soot particles. Scientific Reports 5, Art 11232, DOi: 10.1038/srep11232.
6. Dong, H., Wang, J. and Rubin, M.B. 2015. A nonlinear Cosserat interphase model for residual stresses in an inclusion and the interphase that bonds it to an infinite matrix. International Journal of Solids and Structures 62, 186—206.
7. Dong, H., and Wang, J. 2015. A criterion for failure mode prediction of angle-ply composite laminates under in-plane tension. Composite Structures 128, 234—240.
8. Sun, T., Kang, W. and Wang, J. 2015. Impact of isotopic disorders on thermal transport properties of nanomaterials. Journal of Applied Physics 117, Art 035101.
9. Sun, T., Wang, J. and Kang, W. 2014. Heat transfer in heterogeneous nanostructures can be described by a simple chain model. Physical Chemistry Chemical Physics 16, 16914—16918.
10. Dong, H., Wang, J. and Karihaloo, B.L. 2014. An improved Puck's failure theory for fiber-reinforced composite laminates including the in situ strength effect. Composites Science and Technology 98? 86—92.
11. Sun, T., Wang, J. and Kang, W. 2014. Ubiquitous thermal rectification induced by non-diffusive weak scattering at low temperature in one-dimensional materials: Revealed with a non-reflective heat reservoir. EPL-Europhysics Letters 105, Art 16004.
12. Dong, H., Wang, J. and Rubin, M.B. 2014. Cosserat interphase models for elasticity with application to the interphase bonding a spherical inclusion to an infinite matrix. International Journal of Solids and Structures 51?426—477.
13. Karihaloo, B.L., Zhang, K. and Wang, J. 2013. Honeybee combs: How the circular cells transform into rounded hexagons. Journal of the Royal Society Interface 10, 20130299. (Reported at http://www.nature.com/news/how-honeycombs-can-build-themselves-1.13398; http://news.discovery.com/animals/insects/secret-to-honeycomb-revealed-130717.htm; http://www.livescience.com/38242-why-honeybee-honeycombs-are-perfect.html; http://www.abc.net.au/science/articles/2013/07/18/3805894.htm; http://www.huffingtonpost.com/2013/07/17/honeycombs-build-themselves-physics-bees_n_3611825.html; http://www.futurity.org/heater-bees-key-to-crafting-honeycomb-cells/)
14. Sun, T., Wang, J. and Kang, W. 2013. Van der Waals interaction-tuned heat transfer in nanostructures. Nanoscale 5, 128–133.
15. Zhang, K., Zhao, X.W., Duan, H.L., Karihaloo, B.L. and Wang, J. 2011. Pattern transformations in periodic cellular solids under external stimuli. Journal of Applied Physics 109, Art. 084907.
16.Wang, J., Huang, Z. P., Duan, H. L., Yu, S. W., Feng, X. Q., Wang, G. F., Zhang, W. X. & Wang, T. J. 2011. Surface stress effect in mechanics of nanostructured materials. Acta Mechanica Solida Sinica 24, 52—82.
17.Zhang, K., Han, T., Duan, H. L. & Wang, J. 2010 A theoretical study of possible shape and phase changes of carbon nanotube crystals during contraction and expansion. Carbon 48, 2948—2952.
18.Zhang, K., Duan, H. L., Karihaloo, B. L. & Wang, J. 2010 Hierarchical, multilayered cell walls reinforced by recycled silk cocoons enhance the structural integrity of honeybee combs. Proceedings of the National Academy of Sciences of the United States of America, 107 (21), 9502—9506.
19.Zhang, K., Si, F .W., Duan, H. L. & Wang, J. 2010 Microstructures and mechanical properties of silks of silkworm and honeybee. Acta Biomaterialia 6, 2165—2171.
20.Shao, L. H., Luo, R. Y., Bai, S. L. & Wang, J. 2009 Prediction of effective moduli of carbon nanotube-reinforced composites with waviness and debonding. Composite Structures 87, 274—281.
21.Duan, H. L., Wang, J. & Karihaloo, B. L. 2009 Theory of elasticity at the nano-scale. Advances in Applied Mechanics 42, 1-68.
22.Duan, H.L., Yi, X., Huang, Z.P. & Wang, J. 2007b A unified scheme for prediction of effective moduli of multiphase composites with interface effects: Part II – application and scaling laws. Mechanics of Materials 39, 94—103.
23.Duan, H.L., Yi, X., Huang, Z.P. & Wang, J. 2007a A unified scheme for prediction of effective moduli of multiphase composites with interface effects: Part I – theoretical framework. Mechanics of Materials 39, 81—93.
24.Duan, H. L., Wang, J., Karihaloo, B. L. & Huang, Z. P. 2006 Nanoporous materials can be made stiffer than non-porous counterparts by surface modification. Acta Materialia 54, 2983—2990.
25.Wang, J., Duan, H. L. & Yi, X. 2006 Bounds on effective conductivities of heterogeneous media with graded constituents. Physical Review B 73, Art. 104208.
26.Duan, H.L., Karihaloo, B.L., Wang, J. & Yi, X. 2006 Effective conductivities of heterogeneous media containing multiple inclusions with various spatial distributions. Physical Review B 73, Art. 174203.
27.Duan, H. L., Jiao, Y., Yi, X., Huang, Z. P. & Wang, J. 2006 Solutions of inhomogeneity problems with graded shells and application to core-shell nanoparticles and composites. Journal of the Mechanics and Physics of Solids 54, 1401—1425.
28.Wang, J., Duan, H. L., Huang, Z. P. & Karihaloo, B. L. 2006 A scaling law for properties of nano-structured materials. Proceedings of the Royal Society A 462, 1355—1363.
29.Huang, Z.P. & Wang, J. 2006 Nonlinear mechanics of solids containing isolated voids. Applied Mechanics Reviews 59, 210—229.
30.Chu, H. J. & Wang, J. 2005 Strain distribution in arbitrarily shaped quantum dots with nonuniform composition. Journal of Applied Physics 98, Art. 034315.
31.Duan, H. L., Wang, J., Huang, Z. P. & Karihaloo, B. L. 2005 Eshelby formalism for nano-inhomogeneities. Proceedings of the Royal Society A 461, 3335--3353.
32.Duan, H. L., Wang, J., Huang, Z. P. & Karihaloo, B. L. 2005 Size-dependent effective elastic constants of solids containing nano-inhomogeneities with interface stress. Journal of the Mechanics and Physics of Solids 53, 1574--1596.
33.Duan, H. L., Wang, J., Huang, Z. P. & Zhong, Y. 2005 Stress fields of a spheroidal inhomogeneity with an interphase in an infinite medium under remote loadings. Proceedings of the Royal Society A 461, 1055--1080. ?
34.Zhong, Y., Wang, J., Wu, Y. M. & Huang, Z. P. 2004 Effective moduli of particle-filled composite with inhomogeneous interphase Part II: mapping method and evaluation. Composites Science and Technology 64, 1353--1362.
35.Wu, Y. M., Huang, Z. P., Zhong, Y. & Wang, J. 2004 Effective moduli of particle-filled composite with inhomogeneous interphase Part I: bounds. Composites Science and Technology 64, 1345--1351.
36. Wang, J., & Pyrz, R. 2004b Prediction of the overall moduli of layered silicate-reinforced nanocomposites Part II: analyses. Composites Science and Technology 64, 935--944.
37. Wang, J., & Pyrz, R. 2004a Prediction of the overall moduli of layered silicate-reinforced nanocomposites Part I: basic theory and formulas. Composites Science and Technology 64, 925--934.
38. Wang, J. 2002 Overall moduli and constitutive relations of bodies containing multiple bridged microcracks. International Journal of Solids & Structures 39, 2203--2214.
39. Wang, J., Fang, J. & Karihaloo, B. L. 2000 Asymptotic bounds on overall moduli of cracked bodies. International Journal of Solids & Structures 37, 6221--6237.
40. Wang, J., Fang, J. & Karihaloo, B. L. 2000 Asymptotics of multiple crack interactions and prediction of overall modulus. International Journal of Solids & Structures 37, 4261-4273.
41. Davies, G.A.O., Hitchings, D. & Wang, J. 2000 Prediction of threshold impact energy for onset of delamination in quasi-isotropic carbon/epoxy composite laminates under low-velocity impact. Composites Science and Technology 60, 1--7.
42. Wang, J., Andreasen, J. H. & Karihaloo, B. L. 2000 The solution of an inhomogeneity in a finite plane region and its application to composite materials. Composites Science and Technology 60, 75--82.
43. Karihaloo, B. L., Wang, J. & Grzybowski, M. 1996 Doubly periodic arrays of bridged cracks and short-fibre reinforced cementitious materials. Journal of the Mechanics and Physics of Solids 44, 1565--1586.
44. Wang, J. & Karihaloo, B. L. 19994b Mode II and mode III stress singularities and intensities at a crack tip terminating on a transversely isotropic-orthotropic bimaterial interface. Proceedings of the Royal Society A 444, 447--460.
45. Wang, J. & Karihaloo, B. L. 1994a Cracked composite laminates least prone to delamination. Proceedings of the Royal Society A 444, 17--35.