International Journal of Mechanics and Applications

International Journal of Mechanics and Applications publishes refereed articles on original research, short communications and reviews covering mechanics and applications of industrial materials. In addition to regular issues, special issues on specific subjects are published. These special issues contain invited reviews by eminent researchers in the specific field.


Chunsheng Lu

Editorial Board Member of International Journal of Mechanics and Applications

Senior Lecturer, Curtin University, Australia

Research Areas

Nano-mechanics and nano-structured materials (nanocomposites), Statistical fracture mechanics, scaling and size effects, Mechanics of thin films and coatings, Multi-scale mechanics and numerical simulations, Natural hazard risk analysis and modelling

Education

1993Ph.DSolid Mechanics, Institute of Mechanics of the Chinese Academy of Sciences, China
1986M.ScEngineering Mechanics, China University of Mining and Technology (Beijing), China
1984B.ScMechanical Engineering, Henan Polytechnic University, China

Experience

2010-presentSenior Lecturer/Senior Research Fellow, Department of Mechanical Engineering, Curtin University, Australia
2006-2009Curtin Research & Teaching Fellow, Department of Mechanical Engineering, Curtin University of Technology, Australia
2003-2006Senior Research Associate, School of Aerospace, Mechanical and Mechatronic Engineering, The University of Sydney, Australia
2001-2003Lise Meitner Research Fellow, Institute of Structural and Functional Ceramics & Institute of Mechanics, University of Leoben, Austria
1997-2000Postdoctoral Fellow, School of Mathematical and Computing Sciences, Victoria University of Wellington, New Zealand
1996-1997Japan Society for the Promotion of Science (JSPS) Research Fellow, Graduate School of Information Sciences, Tohoku University, Japan
1991-1996Research Associate/Associate Professor, Institute of Mechanics, Chinese Academy of Sciences, China
1986-1988Assistant Professor, Department of Mechanical Engineering, Henan Polytechnic University, China

Publications: Journals

[1]  J. Wang, C. Lu, Q. Wang, P. Xiao, F.J. Ke, Y.L. Bai, Y.G. Shen, X.Z. Liao, and H.J. Gao, Understanding large plastic deformation of SiC nanowires at room temperature, Europhysics Letters, 95(6) (2011), 63003.
[2]  L. Yang, Y.C. Zhou, and C. Lu, Damage evolution and rupture time prediction in thermal barrier coatings subjected to cyclic heating and cooling: an acoustic emission method, Acta Materialia, 59(17) (2011), 6519-6529.
[3]  Y.L. Huang, X.F. Liu, Y.C. Zhou, Z.S. Ma, and C. Lu, Mathematical analysis on the uniqueness of reverse algorithm for measuring elastic-plastic properties by sharp indentation, Journal of Materials Science & Technology, 27(7) (2011), 577-584.
[4]  C. Lu, Fracture statistics of brittle materials at micro-and nano-scales, International Journal of Materials Research, 102(6) (2011), 627-633.
[5]  W.G. Mao, Y.G. Shen, and C. Lu, Nanoscale elastic-plastic deformation and stress distributions on the C plane of sapphire single crystal during nanoindentation, Journal of the European Ceramic Society, 31(10) (2011), 1865-1871.
[6]  W.G. Mao, Y.G. Shen, and C. Lu, Deformation behaviour and mechanical properties of poly-crystalline and single crystal alumina during nanoindentation, Scripta Materialia, 65(2) (2011), 127-130.
[7]  L.M. Jiang, J. Peng, Y.G. Liao, Y.C. Zhou, J. Liang, H.X. Hao, and C. Lu, A modified layer removal method for residual stress measurement in electrodeposited nickel films, Thin Solid Films, 519(10) (2011), 3249-3253.
[8]  D.J. Wu, W.G. Mao, Y.C. Zhou, and C. Lu, Digital image correlation approach to cracking and decohesion in a brittle coating/ductile substrate system, Applied Surface Science, 257(14) (2011), 6040-6043.
[9]  W.G. Mao, J.P. Jiang, Y.C. Zhou, and C. Lu, Effect of substrate curvature radius, deposition temperature and coating thickness on the residual stress field of cylindrical thermal barrier coatings, Surface & Coatings Technology, 205(8-9) (2011), 3093-3102.
[10]  L.M. Jiang, Y.C. Zhou, H.X. Hao, Y.G. Liao, and C. Lu, Characterization of the interface adhesion of elastic-plastic thin film/rigid substrate systems using a pressurized blister test numerical model, Mechanics of Materials, 42(10) (2010), 908-915.
[11]  R.M. Lin and C. Lu, Modelling of interfacial friction damping of carbon nanotube-based nanocomposites, Mechanical Systems and Signal Processing, 24(8) (2010), 2996-3012.
[12]  W.G. Mao, Q. Chen, C.Y. Dai, L. Yang, Y.C. Zhou, and C. Lu, Effects of piezo-spectroscopic coefficients of 8 wt.% Y2O3 stabilized ZrO2 on residual stress measurement of thermal barrier coatings by Raman spectroscopy, Surface & Coatings Technology, 204(21-22) (2010), 3573-3577.
[13]  Q. Chen, W.G. Mao, Y.C. Zhou, and C. Lu, Effect of Young's modulus evolution on residual stress measurement of thermal barrier coatings by X-ray diffraction, Applied Surface Science, 256(23) (2010), 7311-7315.
[14]  C. Lu, Statistics for quantifying the mechanical properties of nanomaterials, Materials Science Forum, 654-656 (2010), 1578-1581.
[15]  C. Lu, On the nano-filler percolation network in polymer nanocomposites, Materials Forum, 34 (2010), 148-150.
[16]  L.M. Yin, X.P. Zhang, and C. Lu, Size and volume effects on the strength of microscale lead-free solder joints, Journal of Electronic Materials, 38(10) (2009), 2179-2183.
[17]  Y.G. Zheng, H.W. Zhang, Z. Chen, C. Lu, and Y.-W. Mai, Roles of grain boundary and dislocations at different deformation stages of nanocrystalline copper under tension, Physics Letters A, 373(5) (2009), 570-574.
[18]  C. Lu, On the bending strength of ZnO nanowires, Physics Letters A, 372(39) (2008), 6113-6115.
[19]  L. Yang, Y.C. Zhou, W.G. Mao, and C. Lu, Real-time acoustic emission testing based on wavelet transform for the failure process of thermal barrier coatings, Applied Physics Letters, 93(23) (2008), 231906.
[20]  C. Lu, Y.H. Lu, Y.G. Shen, and Y.-W. Mai, Log-normal nanograin-size distributions in nano-structured composites, Philosophical Magazine Letters, 88(11) (2008), 829-836.
[21]  C. Lu, Comment on "On the tensile strength distribution of multiwalled carbon nanotubes", Applied Physics Letters, 92(20) (2008), 206101.
[22]  C. Lu and Y.-W. Mai, Anomalous electrical conductivity and percolation in carbon nanotube composites, Journal of Materials Science, 43(17) (2008), 6012-6015.
[23]  C. Lu, Statistical analysis of the tensile strength of carbon nanotubes, Advanced Materials Research, 41-42 (2008), 27-32.
[24]  C. Lu, A reassessment of the strength distributions of advanced ceramics, Journal of the Australasian Ceramic Society, 44(2) (2008), 38-41.
[25]  C. Lu, Y.-W. Mai, P.L. Tam, and Y.G. Shen, Nanoindentation-induced elastic-plastic transition and size effect in -Al2O3(0001), Philosophical Magazine Letters, 87(6) (2007), 409-415.
[26]  C. Lu and Y.-W. Mai, Permeability modelling of polymer-layered silicate nanocomposites, Composites Science and Technology, 67(14) (2007), 2895-2902.
[27]  Y.G. Shen, Z.J. Liu, Y.H. Lu, C. Lu, and Y.-W. Mai, Monte Carlo simulation of microstructure and grain growth in nc-Ti(N, B)/a-(TiB2, BN) nanocomposite films, Key Engineering Materials, 312 (2006), 357-362.
[28]  C. Lu, Y.-W. Mai, and Y.G. Shen, Indentation size effect on hardness of nanostructured thin films, Key Engineering Materials, 312 (2006), 363-368.
[29]  C. Lu, Y.-W. Mai, and Y.G. Shen, Recent advances on understanding the genesis of superhardness in nanocomposite coatings: a critical review, Journal of Materials Science, 41(3) (2006), 937-950.
[30]  Y.G. Zheng, C. Lu, Y.-W. Mai, Y.X. Gu, H.W. Zhang, and Z. Chen, Monte Carlo simulation of grain growth in two-phase nanocrystalline materials, Applied Physics Letters, 88(14) (2006), 144103.
[31]  C. Lu and Y.-W. Mai, Breaking up the whole into parts: the microstructure and barrier properties of polymer-clay nanocomposites, Physics, 35(7) (2006), 550-552. (in Chinese)
[32]  Y.G. Zheng, C. Lu, Y.-W. Mai, H.W. Zhang, and Z. Chen, Grain growth as a stochastic and curvature-driven process, Philosophical Magazine Letters, 86(12) (2006), 787-794.
[33]  Y.G. Zheng, C. Lu, Y.-W. Mai, H.W. Zhang, and Z. Chen, Model-based simulation of normal grain growth in a two-phase nanostructured system, Science and Technology of Advanced Materials, 7(8) (2006), 812-818.
[34]  C. Lu, The degree of predictability of earthquakes in several regions of China: statistical analysis of historical data, Journal of Asian Earth Sciences, 25(2) (2005), 379-385.
[35]  C. Lu, Y.-W. Mai, and Y.G. Shen, Optimum information in crackling noise, Physical Review E, 72(2) (2005), 027101.
[36]  C. Lu and Y.-W. Mai, Influence of aspect ratio on barrier properties of polymer-clay nanocomposites, Physical Review Letters, 95(8) (2005), 088303.
[37]  C. Lu, Y.-W. Mai, and H. Xie, A sudden drop of fractal dimension: a likely precursor of catastrophic failure in disordered media, Philosophical Magazine Letters, 85(1) (2005), 33-40.
[38]  C. Lu, Y.-W. Mai, and Y. Bai, Fractals and scaling in fracture induced by microcrack coalescence, Philosophical Magazine Letters, 85(2) (2005), 67-75.
[39]  C. Lu, R. Danzer, and F.D. Fischer, Scaling of fracture strength in ZnO: effects of pore/grain-size interaction and porosity, Journal of the European Ceramic Society, 24(14) (2004), 3643-3651.
[40]  C. Lu, R. Danzer, and F.D. Fischer, Influence of threshold stress on the estimation of the Weibull statistics, Journal of the American Ceramic Society, 85(6) (2002), 1640-1642.
[41]  C. Lu, R. Danzer, and F.D. Fischer, Fracture statistics of brittle materials: Weibull or normal distribution, Physical Review E, 65(6) (2002), 067102.
[42]  C. Lu and D. Vere-Jones, Statistical analysis of synthetic earthquake catalogues generated by models with various levels of fault zone disorder, Journal of Geophysical Research, 106(B6) (2001) 11115-11125.
[43]  C. Lu and D. Vere-Jones, Application of linked stress release model to historical earthquake data: comparison between two kinds of tectonic seismicity, Pure and Applied Geophysics, 157(11-12) (2000) 2351-2364.
[44]  C. Lu, D. Vere-Jones, and H. Takayasu, Avalanche behaviour and statistical properties in a microcrack coalescence process, Physical Review Letters, 82(2) (1999) 347-350.
[45]  C. Lu, D. Harte, and M. Bebbington, A linked stress release model for historical Japanese earthquakes: coupling among major seismic regions, Earth, Planets and Space, 51(9) (1999) 907-916.
[46]  C. Lu, D. Vere-Jones, H. Takayasu, A. Tretyakov, and M. Takayasu, Spatio-temporal seismicity in an elastic block lattice model, Fractals, 7(3) (1999) 301-311.
[47]  C. Lu, H. Takayasu, A. Tretyakov, M. Takayasu, and S. Yumoto, Self-organized criticality in a block lattice model of the brittle crust, Physics Letters A, 242(6) (1998) 349-354.
[48]  C. Lu, Some problems in the research of fractal fractured surfaces, Advances in Mechanics, 26(3) (1996) 353-361. (in Chinese)
[49]  C. Lu, Failure theory of disordered media, Mechanics and Practice, 18(3) (1996) 8-12. (in Chinese)
[50]  C. Lu, W.S. Han, Y.L. Bai, M.F. Xia, and F.J. Ke, Fractal mechanism of spallation and relation between fractal dimension and coalescence threshold, Acta Mechanica Sinica, 27(1) (1995) 28-37. (in Chinese)
[51]  C. Lu, F.J. Ke, Y.L. Bai, and M.F. Xia, Numerical simulation of evolution induced catastrophe, Science in China A, 25(1) (1995) 54-60 (in Chinese); 38(4) (1995) 462-471.
[52]  C. Lu, Discussion of "Scaling laws and renormalization groups for strength and toughness of disordered materials", International Journal of Solids and Structure, 32(22) (1995) 3373-3374.
[53]  C. Lu, On the validity of the slit islands analysis in the measure of fractal dimension of fracture surfaces, International Journal of Fracture, 69(4) (1995) R77-R80.
[54]  C. Lu and H.P. Xie, A physical limit of Weibull modulus in rock fracture, International Journal of Fracture, 72(3) (1995) R55-R58.
[55]  Y.L. Bai, C. Lu, F.J. Ke, and M.F. Xia, Evolution induced catastrophe, Physics Letters A, 185(2) (1994) 196-200.
[56]  C. Lu, Y.L. Bai, Z. Ling, M.F. Xia, and F.J. Ke, Cascade coalescence of microcracks and critical failure, Shanghai Journal of Mechanics, 15(4) (1994) 1-7. (in Chinese)
[57]  Y.L. Bai, M.F. Xia, F.J. Ke, C. Lu, and Z. Ling, Analysis and simulation of evolution induced catastrophe, Chinese Physics Letters, 10(3) (1993) 155-158.
[58]  C. Lu and Y.L. Bai, Renormalization group theory and possible implications for earthquake prediction, Recent Developments in World Seismology, 3(1) (1991) 34-35. (in Chinese)
[59]  C. Lu and Y.L. Bai, Fractal behaviour in damage and fracture of materials, Advances in Mechanics, 20(4) (1990) 468-477. (in Chinese)

Publications: Conferences/Workshops/Symposiums

[1]  J. Wang, C. Lu, Q. Wang, P. Xiao, F.J. Ke, Y.L. Bai, Y.G. Shen, X.Z. Liao, and H.J. Gao, Understanding large plastic deformation of SiC nanowires at room temperature, Europhysics Letters, 95(6) (2011), 63003.
[2]  L. Yang, Y.C. Zhou, and C. Lu, Damage evolution and rupture time prediction in thermal barrier coatings subjected to cyclic heating and cooling: an acoustic emission method, Acta Materialia, 59(17) (2011), 6519-6529.
[3]  Y.L. Huang, X.F. Liu, Y.C. Zhou, Z.S. Ma, and C. Lu, Mathematical analysis on the uniqueness of reverse algorithm for measuring elastic-plastic properties by sharp indentation, Journal of Materials Science & Technology, 27(7) (2011), 577-584.
[4]  C. Lu, Fracture statistics of brittle materials at micro-and nano-scales, International Journal of Materials Research, 102(6) (2011), 627-633.
[5]  W.G. Mao, Y.G. Shen, and C. Lu, Nanoscale elastic-plastic deformation and stress distributions on the C plane of sapphire single crystal during nanoindentation, Journal of the European Ceramic Society, 31(10) (2011), 1865-1871.
[6]  W.G. Mao, Y.G. Shen, and C. Lu, Deformation behaviour and mechanical properties of poly-crystalline and single crystal alumina during nanoindentation, Scripta Materialia, 65(2) (2011), 127-130.
[7]  L.M. Jiang, J. Peng, Y.G. Liao, Y.C. Zhou, J. Liang, H.X. Hao, and C. Lu, A modified layer removal method for residual stress measurement in electrodeposited nickel films, Thin Solid Films, 519(10) (2011), 3249-3253.
[8]  D.J. Wu, W.G. Mao, Y.C. Zhou, and C. Lu, Digital image correlation approach to cracking and decohesion in a brittle coating/ductile substrate system, Applied Surface Science, 257(14) (2011), 6040-6043.
[9]  W.G. Mao, J.P. Jiang, Y.C. Zhou, and C. Lu, Effect of substrate curvature radius, deposition temperature and coating thickness on the residual stress field of cylindrical thermal barrier coatings, Surface & Coatings Technology, 205(8-9) (2011), 3093-3102.
[10]  L.M. Jiang, Y.C. Zhou, H.X. Hao, Y.G. Liao, and C. Lu, Characterization of the interface adhesion of elastic-plastic thin film/rigid substrate systems using a pressurized blister test numerical model, Mechanics of Materials, 42(10) (2010), 908-915.
[11]  R.M. Lin and C. Lu, Modelling of interfacial friction damping of carbon nanotube-based nanocomposites, Mechanical Systems and Signal Processing, 24(8) (2010), 2996-3012.
[12]  W.G. Mao, Q. Chen, C.Y. Dai, L. Yang, Y.C. Zhou, and C. Lu, Effects of piezo-spectroscopic coefficients of 8 wt.% Y2O3 stabilized ZrO2 on residual stress measurement of thermal barrier coatings by Raman spectroscopy, Surface & Coatings Technology, 204(21-22) (2010), 3573-3577.
[13]  Q. Chen, W.G. Mao, Y.C. Zhou, and C. Lu, Effect of Young's modulus evolution on residual stress measurement of thermal barrier coatings by X-ray diffraction, Applied Surface Science, 256(23) (2010), 7311-7315.
[14]  C. Lu, Statistics for quantifying the mechanical properties of nanomaterials, Materials Science Forum, 654-656 (2010), 1578-1581.
[15]  C. Lu, On the nano-filler percolation network in polymer nanocomposites, Materials Forum, 34 (2010), 148-150.
[16]  L.M. Yin, X.P. Zhang, and C. Lu, Size and volume effects on the strength of microscale lead-free solder joints, Journal of Electronic Materials, 38(10) (2009), 2179-2183.
[17]  Y.G. Zheng, H.W. Zhang, Z. Chen, C. Lu, and Y.-W. Mai, Roles of grain boundary and dislocations at different deformation stages of nanocrystalline copper under tension, Physics Letters A, 373(5) (2009), 570-574.
[18]  C. Lu, On the bending strength of ZnO nanowires, Physics Letters A, 372(39) (2008), 6113-6115.
[19]  L. Yang, Y.C. Zhou, W.G. Mao, and C. Lu, Real-time acoustic emission testing based on wavelet transform for the failure process of thermal barrier coatings, Applied Physics Letters, 93(23) (2008), 231906.
[20]  C. Lu, Y.H. Lu, Y.G. Shen, and Y.-W. Mai, Log-normal nanograin-size distributions in nano-structured composites, Philosophical Magazine Letters, 88(11) (2008), 829-836.
[21]  C. Lu, Comment on "On the tensile strength distribution of multiwalled carbon nanotubes", Applied Physics Letters, 92(20) (2008), 206101.
[22]  C. Lu and Y.-W. Mai, Anomalous electrical conductivity and percolation in carbon nanotube composites, Journal of Materials Science, 43(17) (2008), 6012-6015.
[23]  C. Lu, Statistical analysis of the tensile strength of carbon nanotubes, Advanced Materials Research, 41-42 (2008), 27-32.
[24]  C. Lu, A reassessment of the strength distributions of advanced ceramics, Journal of the Australasian Ceramic Society, 44(2) (2008), 38-41.
[25]  C. Lu, Y.-W. Mai, P.L. Tam, and Y.G. Shen, Nanoindentation-induced elastic-plastic transition and size effect in a-Al2O3(0001), Philosophical Magazine Letters, 87(6) (2007), 409-415.
[26]  C. Lu and Y.-W. Mai, Permeability modelling of polymer-layered silicate nanocomposites, Composites Science and Technology, 67(14) (2007), 2895-2902.
[27]  Y.G. Shen, Z.J. Liu, Y.H. Lu, C. Lu, and Y.-W. Mai, Monte Carlo simulation of microstructure and grain growth in nc-Ti(N, B)/a-(TiB2, BN) nanocomposite films, Key Engineering Materials, 312 (2006), 357-362.
[28]  C. Lu, Y.-W. Mai, and Y.G. Shen, Indentation size effect on hardness of nanostructured thin films, Key Engineering Materials, 312 (2006), 363-368.
[29]  C. Lu, Y.-W. Mai, and Y.G. Shen, Recent advances on understanding the genesis of superhardness in nanocomposite coatings: a critical review, Journal of Materials Science, 41(3) (2006), 937-950.
[30]  Y.G. Zheng, C. Lu, Y.-W. Mai, Y.X. Gu, H.W. Zhang, and Z. Chen, Monte Carlo simulation of grain growth in two-phase nanocrystalline materials, Applied Physics Letters, 88(14) (2006), 144103.
[31]  C. Lu and Y.-W. Mai, Breaking up the whole into parts: the microstructure and barrier properties of polymer-clay nanocomposites, Physics, 35(7) (2006), 550-552. (in Chinese)
[32]  Y.G. Zheng, C. Lu, Y.-W. Mai, H.W. Zhang, and Z. Chen, Grain growth as a stochastic and curvature-driven process, Philosophical Magazine Letters, 86(12) (2006), 787-794.
[33]  Y.G. Zheng, C. Lu, Y.-W. Mai, H.W. Zhang, and Z. Chen, Model-based simulation of normal grain growth in a two-phase nanostructured system, Science and Technology of Advanced Materials, 7(8) (2006), 812-818.
[34]  C. Lu, The degree of predictability of earthquakes in several regions of China: statistical analysis of historical data, Journal of Asian Earth Sciences, 25(2) (2005), 379-385.
[35]  C. Lu, Y.-W. Mai, and Y.G. Shen, Optimum information in crackling noise, Physical Review E, 72(2) (2005), 027101.
[36]  C. Lu and Y.-W. Mai, Influence of aspect ratio on barrier properties of polymer-clay nanocomposites, Physical Review Letters, 95(8) (2005), 088303.
[37]  C. Lu, Y.-W. Mai, and H. Xie, A sudden drop of fractal dimension: a likely precursor of catastrophic failure in disordered media, Philosophical Magazine Letters, 85(1) (2005), 33-40.
[38]  C. Lu, Y.-W. Mai, and Y. Bai, Fractals and scaling in fracture induced by microcrack coalescence, Philosophical Magazine Letters, 85(2) (2005), 67-75.
[39]  C. Lu, R. Danzer, and F.D. Fischer, Scaling of fracture strength in ZnO: effects of pore/grain-size interaction and porosity, Journal of the European Ceramic Society, 24(14) (2004), 3643-3651.
[40]  C. Lu, R. Danzer, and F.D. Fischer, Influence of threshold stress on the estimation of the Weibull statistics, Journal of the American Ceramic Society, 85(6) (2002), 1640-1642.
[41]  C. Lu, R. Danzer, and F.D. Fischer, Fracture statistics of brittle materials: Weibull or normal distribution, Physical Review E, 65(6) (2002), 067102.
[42]  C. Lu and D. Vere-Jones, Statistical analysis of synthetic earthquake catalogues generated by models with various levels of fault zone disorder, Journal of Geophysical Research, 106(B6) (2001) 11115-11125.
[43]  C. Lu and D. Vere-Jones, Application of linked stress release model to historical earthquake data: comparison between two kinds of tectonic seismicity, Pure and Applied Geophysics, 157(11-12) (2000) 2351-2364.
[44]  C. Lu, D. Vere-Jones, and H. Takayasu, Avalanche behaviour and statistical properties in a microcrack coalescence process, Physical Review Letters, 82(2) (1999) 347-350.
[45]  C. Lu, D. Harte, and M. Bebbington, A linked stress release model for historical Japanese earthquakes: coupling among major seismic regions, Earth, Planets and Space, 51(9) (1999) 907-916.
[46]  C. Lu, D. Vere-Jones, H. Takayasu, A. Tretyakov, and M. Takayasu, Spatio-temporal seismicity in an elastic block lattice model, Fractals, 7(3) (1999) 301-311.
[47]  C. Lu, H. Takayasu, A. Tretyakov, M. Takayasu, and S. Yumoto, Self-organized criticality in a block lattice model of the brittle crust, Physics Letters A, 242(6) (1998) 349-354.
[48]  C. Lu, Some problems in the research of fractal fractured surfaces, Advances in Mechanics, 26(3) (1996) 353-361. (in Chinese)
[49]  C. Lu, Failure theory of disordered media, Mechanics and Practice, 18(3) (1996) 8-12. (in Chinese)
[50]  C. Lu, W.S. Han, Y.L. Bai, M.F. Xia, and F.J. Ke, Fractal mechanism of spallation and relation between fractal dimension and coalescence threshold, Acta Mechanica Sinica, 27(1) (1995) 28-37. (in Chinese)
[51]  C. Lu, F.J. Ke, Y.L. Bai, and M.F. Xia, Numerical simulation of evolution induced catastrophe, Science in China A, 25(1) (1995) 54-60 (in Chinese); 38(4) (1995) 462-471.
[52]  C. Lu, Discussion of "Scaling laws and renormalization groups for strength and toughness of disordered materials", International Journal of Solids and Structure, 32(22) (1995) 3373-3374.
[53]  C. Lu, On the validity of the slit islands analysis in the measure of fractal dimension of fracture surfaces, International Journal of Fracture, 69(4) (1995) R77-R80.
[54]  C. Lu and H.P. Xie, A physical limit of Weibull modulus in rock fracture, International Journal of Fracture, 72(3) (1995) R55-R58.
[55]  Y.L. Bai, C. Lu, F.J. Ke, and M.F. Xia, Evolution induced catastrophe, Physics Letters A, 185(2) (1994) 196-200.
[56]  C. Lu, Y.L. Bai, Z. Ling, M.F. Xia, and F.J. Ke, Cascade coalescence of microcracks and critical failure, Shanghai Journal of Mechanics, 15(4) (1994) 1-7. (in Chinese)
[57]  Y.L. Bai, M.F. Xia, F.J. Ke, C. Lu, and Z. Ling, Analysis and simulation of evolution induced catastrophe, Chinese Physics Letters, 10(3) (1993) 155-158.
[58]  C. Lu and Y.L. Bai, Renormalization group theory and possible implications for earthquake prediction, Recent Developments in World Seismology, 3(1) (1991) 34-35. (in Chinese)
[59]  C. Lu and Y.L. Bai, Fractal behaviour in damage and fracture of materials, Advances in Mechanics, 20(4) (1990) 468-477. (in Chinese)

Publications: Books/Book Chapters

[1]  C. Lu and Y.-W. Mai, Modelling of permeability behaviour of polymer nanocomposites, in: Physical Properties and Applications of Polymer Nanocomposites, edited by S.C. Tjong and Y.-W. Mai, Woodhead Publishing Ltd., Cambridge (2010), pp. 431-453.
[2]  C. Lu and Y.-W. Mai, Modelling of permeability behaviour of polymer nanocomposites, in: Physical Properties and Applications of Polymer Nanocomposites, edited by S.C. Tjong and Y.-W. Mai, Woodhead Publishing Ltd., Cambridge (2010), pp. 431-453.