Publications
Nanostructured materials:
Carbone nanotube reinforced hybrid composites: computational modelling of environmental fatigue and their usability for wind blades, Composites B, (2015), pp. 349-360
Micromechanical modeling of MXene-polymer composites, Carbon, https://doi.org/10.1016/j.carbon.2020.02.070
Nanomorphology of graphene and CNT reinforced polymer and its effect on damage: Micromechanical numerical study, Composite B (2016), pp. 338-349
Nanocellulose reinforced polymer composites: Computational analysis of structure-mechanical properties relationships, Composite Structures, 2019, 111024
Hierarchical composites with secondary CNT nanoreinforcement: Computational modelling ICCM20 Presentation
Nanostructured titanium based materials for medical implants: Modeling and development, Materials Science & Engineering R: Reports.Vol. 81, 2014, pp. 1–19
Gradient ultrafine-grained titanium: computational study of mechanical and damage behavior, Acta materialia, Vol. 71, 2014, pp. 220-233
Graphene monolayer nanocomposites: 3D simulation of damage initiation and evolution, Computational Materials Science, doi: 10.1016/j.commatsci.2014.08.011
Carbon fiber/carbon nanotube based hierarchical composites: Effect of CNT distribution on shearing strength, Composites B, 2016, 88, 201-211
Carbon nanotube reinforced metal binders for diamond cutting tools, Materials and Design, 83, 2015, pp. 536-544
,Micromechanical modelling of nanocrystalline and ultrafine grained metals: A short overview,Computational Materials Science, (2015) pp. 365-373
Non-equilibrium grain boundaries in titanium nanostructured by severe plastic deformation: Computational study of sources of material strengthening,Computational Materials Science, Vol. 83, 2014, Pages 318–330
Martensitic transformations in nanostructured nitinol: FE modelling of grain size and distribution effects, Computational Materials Science, 2013, Vol.76,2013, pp.27-36,
Damage evolution in nanoclay-reinforcedpolymers: 3D computational study, Composites Science & Technology, 74 (2013) 67–77
Micromechanical analysis of nanocomposites using 3D voxel based material model, Composites Science & Technology, 72 (2012) 1167–1177. Another link is here
Nanoreinforced polymer composites: 3D FEM modeling with effective interface concept, Composites Scie & Technol, Vol. 71, No. 7, 2011, pp- 980-988... and link here
Hierarchical and hybrid materials and wood:
Hybrid and hierarchical nanoreinforced polymer composites: Computational modelling of structure-properties relationships, Composite Structures, 117 (2014) 156–168
Nanostructured interfaces for enhancing mechanical properties of materials: Computational micromechanical studies, Composites Part B, Vol. 68, 2015, pp. 75–84
Micromechanics of hierarchical materials: a brief overview, Reviews on Advanced Materials Science, 30 (2012) 60-72
Hierarchical materials: Background and perspectives, MRS Bulletin on “Hierarchical Materials,” MRS Bulletin, Volume 41, September 2016, pp. 661-664
Hybrid carbon/glass fiber composites: Micromechanical analysis of structure–damage resistance relationships, Computational Materials Science, Vol. 81, 2014, pp. 630–640
Fatigue of multiscale composites with secondary nanoplatelet reinforcement: 3D computational analysis, Composites Science and Technology, in print
Hierarchical composites: Analysis of damage evolution based on fiber bundle model, Composites Sci & Technol, 71 (2011) 450–460. Another link is here.
H. Qing, L. Mishnaevsky Jr., Fatigue modelling of materials with complex microstructures, Computational Materials Science, Vol.50, N.5, 2011, pp. 1644-1650
A 3D multilevel model of damage and strength of wood, Mechanics of Materials, 43 (2011) 487–495
3D hierarchical computational model of wood as a cellular material with fibril reinforced, heterogeneous multiple layers, Mechanics of Materials, Vol. 41, 9, 2009, pp. 1034-1049
Composites: Gradient, Interpentrating, MMC....
Functionally gradient metal matrix composites: numerical analysis of the microstructure-strength relationships, Composites Sci. & Technology, 2006, 66/11-12, pp 1873-1887
Automatic voxel based generation of 3D microstructural FE models and its application to the damage analysis of composites, Matls Science & Engineering A, Vol. 407, No. 1-2, 2005, pp.11-23
Three-dimensional numerical testing of microstructures of particle reinforced composites, Acta Materialia, 2004, Vol. 52/14, pp.4177-4188
Effect of microstructures of particle reinforced composites on the damage evolution: probabilistic and numerical analysis, Composites Sci. & Technology, Vol. 64, No 12 , 2004, pp. 1805-1818
Maintenance and repair of wind turbine blades:
Leading edge erosion of wind turbine blades: Computational modelling of multiaxial fatigue, Wind Energy, 2020,
Repair of wind turbine blades: Review of methods and related computational mechanics problems, Renewable Energy, Vol. 140, 2019, pp. 828-839
Micromechanisms of leading edge erosion of wind turbine blades: X-Ray tomography analysis and computational studies Wind Energy 2019;1–16.
Costs of repair of wind turbine blades: Influence of technology aspects, Wind Energ, 2020
Toolbox for optimizing anti-erosion protective coatings of wind turbine blades: Overview of mechanisms and technical solutions, Wind Energy 2019;1–18.
Micromechanical model of surface erosion of polyurethane coatings on wind turbine blades, Polymer Degradation and Stability Vol. 166, 2019, pp.283-289
Multiscale molecular dynamics-FE modeling of polymeric nanocomposites reinforced with carbon nanotubes and graphene, Composite Structures, 217, 2019, pp. 27-36
Rain erosion of wind turbine blades: Computational analysis of parameters controlling the surface degradation, Meccanica, 55, 725–743(doi:10.1007/s11012-019-01089-x)
Materials for wind energy:
Composite materials for wind energy applications: Micromechanical modelling and future directions, Computational Mechanics Vol.50, No. 2, 2012, pp. 195-207
Materials of large wind turbine blades: Recent results in testing and modelling, Wind Energy, Vol. 15, No.1, pp, 83–97, 2012
Small wind turbines with timber blades for developing countries: Materials choice, development, installation and experiences, Renewable Energy, Vol.36, No. 8, 2011, pp. 2128-2138
Selection of Nepalese timber for small wind turbine blade construction, J Wind Engineering, Vol. 34, No. 3, 2010, pp. 263-276
Composite materials in wind energy technology, in Encyclopedia of Life Support Systems (EOLSS), UNESCO, Eolss Publishers, Oxford
Composites and modelling:
Statistical modelling of compression and fatigue damage of unidirectional fiber reinforced composites, Composites Sci & Technol, Vol. 69, 3-4, 2009, pp. 477-484
Microscale damage mechanisms and degradation of fiber reinforced composites for wind energy applications: Results of Danish-Chinese collaborative investigations, J. Composite Materials, September 26, 2013, doi: 10.1177/0021998313503876
Unidirectional high fiber content composites: Automatic 3D FE model generation and damage simulation, Computational Materials Science, Vol. 47, 2, 2009, pp. 548-555
Micromechanisms of damage in unidirectional fiber reinforced composites: 3D computational analysis,Composites Sci & Technol, Vol. 69, No.7-8, 2009, pp. 1036-1044
Moisture-related mechanical properties of softwood: 3D micromechanical modeling, Computational Materials Science, Vol. 46, No. 2, 2009, pp.310-320
Compressive damage mechanism of GFPR composites under off-axis loading: Experimental and numerical investigations, Composites Part B, Vol.55, 2013, pp. 119-127