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プロフィール詳細
プロジェクトを作成
★★★★★
☆☆☆☆☆
Dr. Leon M.に依頼
Denmark

Expert in advanced materials and technologies, wind energy, nanotechnology

プロフィール概要
専門分野
サービス
Writing Technical Writing
Research Meta-Research, Feasibility Study
Consulting Scientific and Technical Consulting, Manufacturing Consulting
Product Development Concept Development
職務経験

Technical University of Denmark

- 現在

Privatdozent

Technical University of Darmstadt

11月 2023 - 現在

Senior Researcher

Technical University of Denmark

1月 2006 - 現在

Scientist, then - Heisenberg Fellow

Universität Stuttgart

1月 1996 - 12月 2005

Postdoc

Technische Universität Wien

4月 1994 - 5月 1995

学歴

Habilitation (Maschinenbau)

Technische Universitat Darmstadt

- 12月 2005

認定資格
  • Habilitation

    TU Darmstadt

    9月 2005 - 現在

出版物
JOURNAL ARTICLE
Antonios Tempelis, Kristine Munk Jespersen, Leon Mishnaevsky, Jr. (2025). Fatigue damage mechanics approach to predict the end of incubation and breakthrough of leading edge protection coatings for wind turbine blades . International Journal of Fatigue.
Antonios Tempelis, Kristine Munk Jespersen, Leon Mishnaevsky Jr.(2025). Fatigue damage mechanics approach to predict the end of incubation and breakthrough of leading edge protection coatings for wind turbine blades . International Journal of Fatigue. 190. Elsevier
Ayush Varshney, Daniel Paul, Puneet Mahajan, Leon Mishnaevsky, Jr. (2024). Cure-induced residual stresses and viscoelastic effects in repaired wind turbine blades: Analytical-numerical investigation . Composites Part C: Open Access.
Shrirang M. Pathak, V. Praveen Kumar, Venkataramana Bonu, Leon Mishnaevsky, Jr., R.V. Lakshmi, Parthasarathi Bera, Harish C. Barshilia (2024). Enhancing wind turbine blade protection: Solid particle erosion resistant ceramic oxides-reinforced epoxy coatings . Renewable Energy.
Yi Chen, Leon Mishnaevsky, Jr. (2024). Modeling the Solvolysis of Composite Materials of Wind Turbine Blades . Advanced Engineering Materials.
Quaiyum M. Ansari, Fernando Sánchez, Leon Mishnaevsky, Jr., Trevor M. Young (2024). Evaluation of offshore wind turbine blades coating thickness effect on leading edge protection system subject to rain erosion . Renewable Energy.
Quaiyum M. Ansari, Fernando Sánchez, Leon Mishnaevsky Jr., Trevor M. Young(2024). Evaluation of offshore wind turbine blades coating thickness effect on leading edge protection system subject to rain erosion . Renewable Energy. 226. Pergamon Press
Antonios Tempelis, Kristine Munk Jespersen, Kirsten Dyer, Ashley Clack, Leon Mishnaevsky Jr.(2024). How leading edge roughness influences rain erosion of wind turbine blades? . Wear. 552-553. Elsevier
Recent Progress in the Development and Evaluation of Rain and Solid Particle Erosion Resistant Coatings for Leading Edge Protection of Wind Turbine Blades @article{7912edca030746e5af8519f8adadbfc4, title = "Recent Progress in the Development and Evaluation of Rain and Solid Particle Erosion Resistant Coatings for Leading Edge Protection of Wind Turbine Blades", abstract = "In recent years, wind energy has gained widespread attention and has been regarded as one of the renewable energy resources for the future. However, surface erosion of wind turbine blades, which are key components of wind turbines, can degrade the aerodynamic properties of blades, thereby, reducing the energy efficiency and service life. It has been estimated that wind turbine blade erosion can reduce annual energy production by 20–25% with severe erosion. In this sense, understanding and mitigating of leading edge erosion of wind turbine blades caused by rain and solid particles are critical to develop efficient technologies for wind turbine blades. To protect the wind turbine blades, various types of polymer-based coatings have been developed. In general, polymer composites offer excellent strength, durability, flexibility, ease of fabrication, and low cost. This comprehensive review is aimed to provide broad information and recent developments about the characteristics of leading edge erosion by rain and solid particles, their mechanisms, testing methods and associated standards, and development of erosion protection coatings for wind turbines. Updated advances in characteristics of polymeric protective coatings, process of coating development, coating materials, coating types, and simulation for the coating development against rain and solid particle erosions have also been addressed in this review.", keywords = "Wind energy, Turbine blade, Leading edge erosion, Protective coating, Rain erosion, Solid particle erosion", author = "Parthasarathi Bera and R.V. Lakshmi and Pathak, {Shrirang M.} and Venkataramana Bonu and {Mishnaevsky Jr.}, Leon and Barshilia, {Harish C.}", year = "2024", doi = "10.1080/15583724.2023.2270050", language = "English", volume = "64", journal = "Polymer Reviews", issn = "1558-3716", publisher = "Taylor and Francis Group", number = "2", } . Polymer Reviews.
Yi Chen, Leon Mishnaevsky Jr.(2024). Modeling the Solvolysis of Composite Materials of Wind Turbine Blades . Advanced Engineering Materials. 26. (16). Wiley - V C H Verlag GmbH & Co. KGaA
Ayush Varshney, Daniel Paul, Puneet Mahajan, Leon Mishnaevsky Jr.(2024). Cure-induced residual stresses and viscoelastic effects in repaired wind turbine blades: Analytical-numerical investigation . Composites Part C: Open Access. 15. Elsevier
Leon Mishnaevsky Jr. (2023). How to Repair the Next Generation of Wind Turbine Blades . Energies.
Leon Mishnaevsky Jr. (2023). How to Repair the Next Generation of Wind Turbine Blades . Energies.
Leon Mishnaevsky, Jr., Antonios Tempelis, Nikesh Kuthe, Puneet Mahajan (2023). Recent developments in the protection of wind turbine blades against leading edge erosion: Materials solutions and predictive modelling . Renewable Energy.
Antonios Tempelis, Leon Mishnaevsky Jr. (2023). Erosion modelling on reconstructed rough surfaces of wind turbine blades . Wind Energy.
Leon Mishnaevsky, Jr., Mohsen Jafarpour, Johanna Krüger, Stanislav N. Gorb (2023). A New Concept of Sustainable Wind Turbine Blades: Bio-Inspired Design with Engineered Adhesives . Biomimetics.
Leon Mishnaevsky Jr., Mohsen Jafarpour, Johanna Krüger, Stanislav Gorb (2023). A New Concept of Sustainable Wind Turbine Blades: Bio-Inspired Design with Engineered Adhesives . Biomimetics.
Antonios Tempelis, Leon Mishnaevsky, Jr (2023). Surface roughness evolution of wind turbine blade subject to rain erosion . Materials & Design.
Daniel Paul, Ayush Varshney, Puneet Mahajan, Leon Mishnaevsky, Jr. (2023). Post-repair residual stresses and microstructural defects in wind turbine blades: Computational modelling . International Journal of Adhesion and Adhesives.
Shrirang M. Pathak, V. Praveen Kumar, Venkataramana Bonu, Leon Mishnaevsky, Jr., R. V. Lakshmi, Parthasarathi Bera, Harish C. Barshilia (2023). Development of Cellulose-Reinforced Polyurethane Coatings: A Novel Eco-Friendly Approach for Wind Turbine Blade Protection . Energies.
Shrirang Pathak, V. Praveen Kumar, Venkataramana Bonu, Leon Mishnaevsky Jr., R. V. Lakshmi, Parthasarathi Bera, Harish C. Barshilia, Ph. D. (2023). Development of Cellulose-Reinforced Polyurethane Coatings: A Novel Eco-Friendly Approach for Wind Turbine Blade Protection . Energies.
Shrirang M. Pathak, V. Praveen Kumar, Venkataramana Bonu, Leon Mishnaevsky Jr., R. V. Lakshmi, Parthasarathi Bera, Harish C. Barshilia(2023). Development of Cellulose-Reinforced Polyurethane Coatings: A Novel Eco-Friendly Approach for Wind Turbine Blade Protection . Energies. 16. (4). M D P I AG
V.B. Pandey, Nikesh Kuthe, Puneet Mahajan, Leon Mishnaevsky Jr.(2023). Continuum damage mechanics based computational framework for prediction of the lifetime and degradation of wind turbine coatings with defects . Engineering Failure Analysis. 154. Pergamon Press
High rate response of elastomeric coatings for wind turbine blade erosion protection evaluated through impact tests and numerical models @article{383b5e7129b94394b7ef0787be1a3f25, title = "High rate response of elastomeric coatings for wind turbine blade erosion protection evaluated through impact tests and numerical models", abstract = "The high strain rate (above ~ 104/s) behavior of an elastomer is characterized using low strain rate (below ~ 101/s) dynamic mechanical thermal analysis and time–temperature superposition. This approach is validated using high strain rate ball impact experiments and finite element predictions of ball deformations and rebound speeds. The ball impact experiments are performed by shooting 6 mm rubber balls with a controlled impact speed of 50–170 m/s at steel and polyurethane targets. An explicit axisymmetric finite element model of the ball impact experiment is established in the commercial code Abaqus. The validated material properties are used to model the viscously dissipated energy and the corresponding temperature increase in the polyurethane target. The region with the largest dissipated energy in the target material is predicted to be in a ring around the impact center with a radius of approximately 1 mm. This region corresponds well to locations of early damage initiation observed in the impact fatigue experiments for similar materials. The predictions are confirmed by the observed temperature distributions using thermal camera imaging of the rubber ball impact experiment. The experimental setup was developed for impact fatigue testing of anti-erosion coatings for the leading-edges of wind turbine blades.", keywords = "Wind turbine blades, Leading-edge erosion, Viscoelastic materials, High strain rates", author = "Jespersen, {Kristine Munk} and Mohammadali Eftekhar and {Frost-Jensen Johansen}, Nicolai and Bech, {Jakob Ilsted} and {Mishnaevsky Jr.}, Leon and Mikkelsen, {Lars Pilgaard}", year = "2023", doi = "10.1016/j.ijimpeng.2023.104643", language = "English", volume = "179", journal = "International Journal of Impact Engineering", issn = "0734-743X", publisher = "Pergamon Press", } . International Journal of Impact Engineering.
Leon Mishnaevsky Jr.(2023). Recycling of wind turbine blades: Recent developments . Current Opinion in Green and Sustainable Chemistry. 39. Elsevier
Leon Mishnaevsky Jr.(2023). How to Repair the Next Generation of Wind Turbine Blades . Energies. 16. (23). M D P I AG
Antonios Tempelis, Leon Mishnaevsky Jr.(2023). Surface roughness evolution of wind turbine blade subject to rain erosion . Materials and Design. 231. Elsevier
Antonios Tempelis, Leon Mishnaevsky Jr.(2023). Erosion modelling on reconstructed rough surfaces of wind turbine blades . Wind Energy. 26. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1017--1026. JohnWiley & Sons Ltd.
Daniel Paul, Ayush Varshney, Puneet Mahajan, Leon Mishnaevsky Jr.(2023). Post-repair residual stresses and microstructural defects in wind turbine blades: Computational modelling . International Journal of Adhesion and Adhesives. 123. Elsevier
Leon Mishnaevsky Jr., Antonios Tempelis, Nikesh Kuthe, Puneet Mahajan(2023). Recent developments in the protection of wind turbine blades against leading edge erosion: Materials solutions and predictive modelling . Renewable Energy. 215. Pergamon Press
Leon Mishnaevsky Jr., Mohsen Jafarpour, Johanna Krüger, Stanislav N. Gorb(2023). A New Concept of Sustainable Wind Turbine Blades: Bio-Inspired Design with Engineered Adhesives . Biomimetics. 8. (6). Multidisciplinary Digital Publishing Institute (MDPI)
Kadhirvel Boopathi, Leon Mishnaevsky, Jr, Bose Sumantraa, S. Anthonyraj Premkumar, Krishnaraj Thamodharan, Kannan Balaraman(2022). Failure mechanisms of wind turbine blades in India: Climatic, regional, and seasonal variability . Wind Energy. 25. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 968--979. Wiley
Leon Mishnaevsky, Jr.(2022). Root Causes and Mechanisms of Failure of Wind Turbine Blades: Overview . Materials. 15. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2959. {MDPI} {AG}
Leon Mishnaevsky, Jr., Nicolai Frost-Jensen Johansen, Anthony Fraisse, Søren Fæster, Thomas Jensen, Brian Bendixen (2022). Technologies of Wind Turbine Blade Repair: Practical Comparison . Energies.
Leon Mishnaevsky Jr., Nicolai Frost-Jensen Johansen, Anthony Fraisse, Søren Fæster, Thomas Jensen, Brian Bendixen (2022). Technologies of Wind Turbine Blade Repair: Practical Comparison . Energies.
Krzysztof Grabowski, Shreyas Srivatsa, Aniruddh Vashisth, Leon Mishnaevsky, Jr., Tadeusz Uhl(2022). Recent advances in MXene-based sensors for Structural Health Monitoring applications: A review . Measurement. 189. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 110575. Elsevier {BV}
Nikesh Kuthe, Puneet Mahajan, Suhail Ahmad, Leon Mishnaevsky Jr.(2022). Engineered anti-erosion coating for wind turbine blade protection: Computational analysis . Materials Today Communications. 31. Elsevier
Leon Mishnaevsky Jr., Nicolai Frost-Jensen Johansen, Anthony Fraisse, Søren Fæster, Thomas Jensen, Brian Bendixen(2022). Technologies of Wind Turbine Blade Repair: Practical Comparison . Energies. 15. (5). M D P I AG
Krzysztof Grabowski, Shreyas Srivatsa, Aniruddh Vashisth, Leon Mishnaevsky Jr., Tadeusz Uhl(2022). Recent advances in MXene-based sensors for Structural Health Monitoring applications: A review . Measurement: Journal of the International Measurement Confederation. 189. Elsevier
Solid particle erosion studies of ceramic oxides reinforced water-based PU nanocomposite coatings for wind turbine blade protection @article{021552a477084f29b4295829bf96239f, title = "Solid particle erosion studies of ceramic oxides reinforced water-based PU nanocomposite coatings for wind turbine blade protection", abstract = "Wind energy has been regarded to be one of the renewable energies to rely on for the future. In tropical countries like India maintenance of wind turbine blades is a challenging task. Solid particle erosion is one of the root causes of wind turbine blade damage resulting in reduction in energy production. In the present study, in-house synthesized ceramic oxide nanoparticles such as Al2O3, ZrO2, and CeO2 are used as fillers for reinforcement of water-based polyurethane (PU) coatings on glass fibre reinforced polymer (GFRP) substrates for solid particle erosion resistance for the first time. Al2O3, ZrO2, and CeO2 nanoparticles have been prepared by solution combustion synthesis method using urea, glycine, and oxalyl dihydrazide, respectively, as fuels. These ceramic nanoparticles are found to crystallize in corundum, tetragonal, and cubic structures, respectively, as confirmed by X-ray diffraction studies. Field emission scanning electron microscopy shows the porous microstructure of the oxide products due to the release of gases in course of preparation. Transmission electron microscopy studies of these nanoparticles show corresponding lattice fringes in their high-resolution images. Observed Al–O, Zr–O, and Ce–O vibrational modes in Raman spectra confirm the formation of corresponding oxides. The oxidation states of Al, Zr, and Ce in the respective oxides are found to be +3, +4, and +4 as demonstrated by X-ray photoelectron spectroscopy (XPS). The nanocomposite coatings consisting of PU and Al2O3, ZrO2, and CeO2 nanoparticles have been developed by a simple spray method on GFRP substrates. The solid particle erosion resistance tests of coatings have been studied at varied concentrations of Al2O3, ZrO2, and CeO2 nanoparticles at impinging angles of 30° and 90°. It has been observed that ZrO2, and CeO2 nanoparticles reinforced PU coatings show better solid particle erosion resistance compared to Al2O3-reinforced coating. Among different concentrations studied here, coatings with 15 wt% filler concentrations offer a relatively low erosion rate than the other concentrations at both impinging angles. However, GFRP substrate and PU coating are observed to show much higher erosion rate compared to nanoparticles reinforced PU coatings.", keywords = "Wind turbine blade, Al2O3, ZrO2, and CeO2 nanoparticles, Polyurethane, Coatings, Solid particle erosion", author = "Pathak, {Shrirang M.} and Kumar, {V. Praveen} and Venkataramana Bonu and S. Latha and {Mishnaevsky Jr.}, Leon and R.V. Lakshmi and Parthasarathi Bera and Barshilia, {Harish C.}", year = "2022", doi = "10.1016/j.ceramint.2022.07.143", language = "English", volume = "48", pages = "35788--35798", journal = "Ceramics International", issn = "0272-8842", publisher = "Pergamon Press", number = "23, Part B", } . Ceramics International.
Leon Mishnaevsky Jr.(2022). Root Causes and Mechanisms of Failure of Wind Turbine Blades: Overview . Materials. 15. (9). Molecular Diversity Preservation International, MDPI
Graphene/sol–gel modified polyurethane coating for wind turbine blade leading edge protection: Properties and performance @article{8ada258b016b41068743782780e7d7bc, title = "Graphene/sol–gel modified polyurethane coating for wind turbine blade leading edge protection: Properties and performance", abstract = "The development of two novel elastomeric erosion resistant coatings for the protection of wind turbine blades is presented. The coatings are prepared by modifying polyurethane (PU) with (i) hydroxyl functionalised graphene nanoparticles (f-GNP) and (ii) f-GNP and a hydrophobic silica-based sol–gel (SG). Tensile, monotonic and cyclic compression and tearing tests have been conducted on the neat PU and the two newly developed elastomeric PU nanocomposites (PU + GNP and PU + GNP + SG) to allow their properties to be compared. The test results showed that the mechanical properties of PU and the modified PUs have strong dependency on temperature, strain rate and nanoparticles loading and addition of GNP and SG to PU improved the mechanical properties. Compared to PU, Young{\textquoteright}s modulus and modulus of toughness of PU + GNP + SG increased 95% and 124%, respectively. The PU + GNP nanocomposite displayed the highest tearing strength and the PU + GNP + SG nanocomposite showed the highest elongation at break. An investigation of the microstructures of the modified PUs by FTIR, field emission scanning electron microscope (FESEM) and energy-dispersive X-ray spectroscopy (EDX) are discussed. Hydrophobicity of the PU and developed PU nanocomposites are reported by measuring their water droplet contact angles and their free surface energies.", keywords = "Graphene, Sol-gel, Silica, Polyurethane, Erosion resistance, Wind turbine blade", author = "Arash Dashtkar and Johansen, {Nicolai Frost-Jensen} and Leon Mishnaevsky and Williams, {Neil A.} and Hasan, {Shadi W.} and Wadi, {Vijay S.} and Alessio Silvello and Homayoun Hadavinia", year = "2022", doi = "10.1177/09673911221074197", language = "English", volume = "30", journal = "Polymers and Polymer Composites", issn = "0967-3911", publisher = "Smithers Rapra", } . Polymers and Polymer Composites.
Søren Fæster, Nicolai Frost‐Jensen Johansen, Leon Mishnaevsky, Jr, Yukihiro Kusano, Jakob Ilsted Bech, Martin Bonde Madsen (2021). Rain erosion of wind turbine blades and the effect of air bubbles in the coatings . Wind Energy.
Nicolai Frost-Jensen Johansen, Leon Mishnaevsky, Jr., Arash Dashtkar, Neil A. Williams, Søren Fæster, Alessio Silvello, Irene Garcia Cano, Homayoun Hadavinia(2021). Nanoengineered Graphene-Reinforced Coating for Leading Edge Protection of Wind Turbine Blades . Coatings. 11. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1104. {MDPI} {AG}
Nicolai Frost-Jensen Johansen, Leon Mishnaevsky Jr., Arash Dashtkar, Neil A. Williams, Søren Fæster, Alessio Silvello, Irene Garcia Cano, Homayoun Hadavinia (2021). Nanoengineered Graphene-Reinforced Coating for Leading Edge Protection of Wind Turbine Blades . Coatings.
Sigitas Kilikevičius, Saulė Kvietkaitė, Leon Mishnaevsky, Jr., Mária Omastová, Andrey Aniskevich, Daiva Zeleniakienė (2021). Novel Hybrid Polymer Composites with Graphene and MXene Nano-Reinforcements: Computational Analysis . Polymers.
Sigitas Kilikevičius, Saule Kvietkaite, Leon Mishnaevsky Jr., Maria Omastova, Andrey Aniskevich, Daiva Zeleniakiene (2021). Novel Hybrid Polymer Composites with Graphene and MXene Nano-Reinforcements: Computational Analysis . Polymers.
Leon Mishnaevsky(2021). Sustainable End-of-Life Management of Wind Turbine Blades: Overview of Current and Coming Solutions . Materials. 14. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1124. {MDPI} {AG}
Sigitas Kilikevičius, Saulė Kvietkaitė, Leon Mishnaevsky Jr., Mária Omastová, Andrey Aniskevich, Daiva Zeleniakienė(2021). Novel Hybrid Polymer Composites with Graphene and MXene Nano-Reinforcements: Computational Analysis . Polymers. 13. (7). M D P I AG
Leon Mishnaevsky Jr., Charlotte Bay Hasager, Christian Bak, Anna-Maria Tilg, Jakob Ilsted Bech, Saeed Doagou Rad, Søren Fæster(2021). Leading edge erosion of wind turbine blades: Understanding, prevention and protection . Renewable Energy. 169. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 953--969. Pergamon Press
Søren Fæster, Nicolai Frost-Jensen Johansen, Leon Mishnaevsky Jr., Yukihiro Kusano, Jakob Ilsted Bech, Martin Bonde Madsen(2021). Rain erosion of wind turbine blades and the effect of air bubbles in the coatings . Wind Energy. 24. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1071--1082. JohnWiley & Sons Ltd.
Vijendra Kumar Mohonee, Kheng Lim Goh, Leon Mishnaevsky Jr., Pooria Pasbakhsh(2021). Capsule based self-healing composites: New insights on mechanical behaviour based on finite element analysis . Computational Materials Science. 192. Elsevier
Nicolai Frost-Jensen Johansen, Leon Mishnaevsky Jr., Arash Dashtkar, Neil A. Williams, Søren Fæster, Alessio Silvello, Irene Garcia Cano, Homayoun Hadavinia(2021). Nanoengineered graphene-reinforced coating for leading edge protection of wind turbine blades . Coatings. 11. (9). M D P I AG
Lennart Mischnaewski, Leon Mishnaevsky Jr.(2021). Structural repair of wind turbine blades: Computational model for the evaluation of the effect of adhesive properties . Wind Energy. 24. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 402--408. JohnWiley & Sons Ltd.
Leon Mishnaevsky Jr.(2021). Sustainable End-of-Life Management of Wind Turbine Blades: Overview of Current and Coming Solutions . Materials. 14. (5). Molecular Diversity Preservation International, MDPI
Shreyas Srivatsa, Pawel Packo, Leon Mishnaevsky Jr., Tadeusz Uhl, Krzysztof Grabowski(2021). Micromechanical modeling of nacre-mimetic Ti3C2-MXene nanocomposites with viscoelastic polymer matrix . MRS Advances. 6. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 729--733. Cambridge University Press
Leon Mishnaevsky Jr.(2021). Current Challenges of Wind Energy Development: Materials Science Aspects . Physical Mesomechanics. 24. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 533--540. M A I K Nauka - Interperiodica
Leon Mishnaevsky, Jr., Kenneth Thomsen (2020). Costs of repair of wind turbine blades: Influence of technology aspects . Wind Energy.
Shreyas Srivatsa, Paweł Paćko, Leon Mishnaevsky, Jr., Tadeusz Uhl, Krzysztof Grabowski(2020). Deformation of Bioinspired MXene-Based Polymer Composites with Brick and Mortar Structures: A Computational Analysis . Materials. 13. (22). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 5189. {MDPI} {AG}
Shreyas Srivatsa, Pawel Packo, Leon Mishnaevsky Jr., Tadeusz Uhl, Krzysztof Grabowski (2020). Deformation of Bioinspired MXene-Based Polymer Composites with Brick and Mortar Structures: A Computational Analysis . Materials.
Leon Mishnaevsky, Jr, Søren Fæster, Lars P. Mikkelsen, Yukihiro Kusano, Jakob Ilsted Bech (2020). Micromechanisms of leading edge erosion of wind turbine blades: X‐ray tomography analysis and computational studies . Wind Energy.
G. Monastyreckis, Leon Mishnaevsky Jr., C.B. Hatter, A. Aniskevich, Y. Gogotsi, D. Zeleniakiene(2020). Micromechanical modeling of MXene-polymer composites . Carbon. 162. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 402--409. Pergamon Press
Saeed Doagou Rad, Leon Mishnaevsky Jr.(2020). Rain erosion of wind turbine blades: computational analysis of parameters controlling the surface degradation . Meccanica. 55. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 725--743. Springer Netherlands
Kristine Munk Jespersen, G. Monastyreckis, Leon Mishnaevsky Jr.(2020). On the potential of particle engineered anti-erosion coatings for leading edge protection of wind turbine blades: Computational studies . IOP Conference Series: Materials Science and Engineering. 942. (1). IOP Publishing
Leon Mishnaevsky Jr., Søren Fæster, Saeed Doagou Rad(2020). Mechanisms and computational analysis of leading edge erosion of wind turbine blades . IOP Conference Series: Materials Science and Engineering. 942. (1). IOP Publishing
Micromechanisms of leading edge erosion of wind turbine blades: X‐ray tomography analysis and computational studies @article{29e36a4d1dfc478483bed2f0e50e2d6c, title = "Micromechanisms of leading edge erosion of wind turbine blades: X‐ray tomography analysis and computational studies", abstract = "Micromechanisms of leading edge erosion of wind turbine blades are studied with the use of X‐ray tomography and computational micromechanics simulations. Computational unit cell micromechanical models of the coatings taking into account their microscale and nanoscale structures have been developed and compared with microscopy studies. It was observed that the heterogeneities, particles, and voids in the protective coatings have critical effect on the crack initiation in the coatings under multiple liquid impact. The damage criterion for the formation of initial defects in the top coating is determined, and it is maximum principal stress criterion. Porosity or stiff particles in the coatings change the damage initiation sites, moving it from the contact surface to the pores or particles closest to the surface. Increasing the thickness of the polymer coatings allows reducing the stress amplitude, thus delaying the damage.", keywords = "Coatings, Leading edge erosio, Modeling, Wind energy", author = "Leon Mishnaevsky and S{\o}ren F{\ae}ster and Mikkelsen, {Lars Pilgaard} and Yukihiro Kusano and Bech, {Jakob Ilsted}", year = "2020", doi = "10.1002/we.2441", language = "English", volume = "23", pages = "547--562", journal = "Wind Energy", issn = "1095-4244", publisher = "JohnWiley & Sons Ltd.", number = "3", } . Wind Energy.
Malcolm McGugan, Leon Mishnaevsky Jr.(2020). Damage mechanism based approach to the structural health monitoring of wind turbine blades . Coatings. 10. (12). M D P I AG
Shreyas Srivatsa, Paweł Paćko, Leon Mishnaevsky Jr., Tadeusz Uhl, Krzysztof Grabowski(2020). Deformation of bioinspired MXene-based polymer composites with brick and mortar structures: A computational analysis . Materials. 13. (22). Molecular Diversity Preservation International, MDPI
Leon Mishnaevsky, Jr.(2019). Repair of wind turbine blades: Review of methods and related computational mechanics problems . Renewable Energy. 140. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 828--839. Elsevier {BV}
Leon Mishnaevsky, Jr., Jan Sütterlin(2019). Micromechanical model of surface erosion of polyurethane coatings on wind turbine blades . Polymer Degradation and Stability. 166. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 283--289. Elsevier {BV}
S. Doagou-Rad, J.S. Jensen, A. Islam, Leon Mishnaevsky, Jr. (2019). Multiscale molecular dynamics-FE modeling of polymeric nanocomposites reinforced with carbon nanotubes and graphene . Composite Structures.
S. Vorotilo, P. Loginov, L. Mishnaevsky, D. Sidorenko, E. Levashov(2019). Nanoengineering of metallic alloys for machining tools: Multiscale computational and in situ TEM investigation of mechanisms . Materials Science and Engineering: A. 739. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 480--490. Elsevier {BV}
Leon Mishnaevsky Jr., Jan Sütterlin(2019). Micromechanical model of surface erosion of polyurethane coatings on wind turbine blades . Polymer Degradation and Stability. 166. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 283--289. Elsevier
Leon Mishnaevsky Jr.(2019). Repair of wind turbine blades: Review of methods and related computational mechanics problems . Renewable Energy. 140. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 828--839. Pergamon Press
Saeed Doagou Rad, Jakob Søndergaard Jensen, Aminul Islam, Leon Mishnaevsky Jr.(2019). Multiscale molecular dynamics-FE modeling of polymeric nanocomposites reinforced with carbon nanotubes and graphene . Composite Structures. 217. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 27--36 . Elsevier
Leon Mishnaevsky Jr.(2019). Toolbox for optimizing anti-erosion protective coatings of wind turbine blades: Overview of mechanisms and technical solutions . Wind Energy. 22. (11). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1636--1653. JohnWiley & Sons Ltd.
S. Vorotilo, P. Loginov, Leon Mishnaevsky Jr., D. Sidorenko, E. Levashov(2019). Nanoengineering of metallic alloys for machining tools: Multiscale computational and in situ TEM investigation of mechanisms . Materials Science and Engineering: A - Structural Materials: Properties, Microstructure and Processing. 739. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 480--490. Elsevier
Leon Mishnaevsky Jr., Lars Pilgaard Mikkelsen, Andre N. Gaduan, Koon-Yang Lee, Bo Madsen(2019). Nanocellulose reinforced polymer composites: Computational analysis of structure-mechanical properties relationships . Composite Structures. 224. Elsevier
P.A. Loginov, D.A. Sidorenko, E.A. Levashov, M.I. Petrzhik, M.Ya. Bychkova, L. Mishnaevsky, Jr.(2018). Hybrid metallic nanocomposites for extra wear-resistant diamond machining tools . International Journal of Refractory Metals and Hard Materials. 71. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 36--44. Elsevier {BV}
P.A. Loginov, D.A. Sidorenko, E.A. Levashov, M.I. Petrzhik, M.Ya. Bychkova, Leon Mishnaevsky Jr.(2018). Hybrid metallic nanocomposites for extra wear-resistant diamond machining tools . International Journal of Refractory Metals and Hard Materials. 71. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 36--44. Elsevier
Leon Mishnaevsky Jr., Christian Linder, WaiChing (Steve) Sun(2018). Preface: Multiscale Computational Analysis of Complex Materials . International Journal for Multiscale Computational Engineering. 16. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString V--VI. Begell House
Anthony Fraisse, Jakob Ilsted Bech, Kaj Kvisgaard Borum, Vladimir Fedorov, Nicolai Frost-Jensen Johansen, Malcolm McGugan, Leon Mishnaevsky Jr., Yukihiro Kusano(2018). Impact fatigue damage of coated glass fibre reinforced polymer laminate . Renewable Energy. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1102--1112. Pergamon Press
Leon Mishnaevsky, Kim Branner, Helga Petersen, Justine Beauson, Malcolm McGugan, Bent Sørensen (2017). Materials for Wind Turbine Blades: An Overview . Materials.
Leon Mishnaevsky Jr., Lars Mikkelsen(2017). Computational Modelling of Materials for Wind Turbine Blades: Selected DTU Wind Energy Activities . Materials. 10. (11). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1278. {MDPI} {AG}
Daria Sidorenko, Pavel Loginov, Leon Mishnaevsky, Evgeny Levashov (2017). Nanocomposites for Machining Tools . Materials.
Lars Pilgaard Mikkelsen, Leon Mishnaevsky Jr.(2017). Computational Modelling of Materials for Wind Turbine Blades: Selected DTUWind Energy Activities . Materials. 10. (11). Molecular Diversity Preservation International, MDPI
H. W. Zhou, H. Y. Yi, Leon Mishnaevsky Jr., R. Wang, Z. Q. Duan, Q. Chen(2017). Deformation analysis of polymers composites: rheological model involving time-based fractional derivative . Mechanics of Time Dependent Materials. 21. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 151--161. Springer Netherlands
Daria Sidorenko, Pavel Loginov, Leon Mishnaevsky Jr., Evgeny Levashov(2017). Nanocomposites for Machining Tools . Materials. 10. (10). Molecular Diversity Preservation International, MDPI
Leon Mishnaevsky Jr., Kim Branner, Helga Nørgaard Petersen, Justine Beauson, Malcolm McGugan, Bent F. Sørensen(2017). Materials for Wind Turbine Blades: An Overview . Materials. 10. (11). Molecular Diversity Preservation International, MDPI
Alessandro Pontefisso, Leon Mishnaevsky, Jr.(2016). Nanomorphology of graphene and CNT reinforced polymer and its effect on damage: Micromechanical numerical study . Composites Part B: Engineering. 96. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 338--349. Elsevier {BV}
H.W. Zhou, L. Mishnaevsky, Jr., H.Y. Yi, Y.Q. Liu, X. Hu, A. Warrier, G.M. Dai(2016). Carbon fiber/carbon nanotube reinforced hierarchical composites: Effect of CNT distribution on shearing strength . Composites Part B: Engineering. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 201--211. Elsevier {BV}
Daria Sidorenko, Pavel Loginov, Evgeny Levashov, Leon Mishnaevsky Jr.(2016). Hierarchical machining materials and their performance . M R S Bulletin. 41. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 678--682. Cambridge University Press
H. W. Zhou, Leon Mishnaevsky Jr., H. Y. Yi, Y. Q. Liu, X. Hu, A. Warrier, Gaoming Dai(2016). Carbon fiber/carbon nanotube reinforced hierarchical composites: Effect of CNT distribution on shearing strength . Composites Part B: Engineering. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 201--211. Pergamon Press
Zhou, H.W., Mishnaevsky, L., Yi, H.Y., Liu, Y.Q., Hu, X., Warrier, A., Dai, G.M.(2016). Carbon fiber/carbon nanotube reinforced hierarchical composites: Effect of CNT distribution on shearing strength . Composites Part B: Engineering. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 201-211.
Alessandro Pontefisso, Leon Mishnaevsky Jr.(2016). Nanomorphology of graphene and CNT reinforced polymer and its effect on damage: Micromechanical numerical study . Composites Part B: Engineering. 96. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 338--349. Pergamon Press
Pavel Loginov, Leon Mishnaevsky, Jr, Evgeny Levashov, Mikhail Petrzhik(2015). Diamond and cBN hybrid and nanomodified cutting tools with enhanced performance: Development, testing and modelling . Materials & Design. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310--319. Elsevier {BV}
Leon Mishnaevsky, Jr., Evgeny Levashov (2015). Micromechanical modelling of nanocrystalline and ultrafine grained metals: A short overview . Computational Materials Science.
Leon Mishnaevsky, Jr.(2015). Nanostructured interfaces for enhancing mechanical properties of composites: Computational micromechanical studies . Composites Part B: Engineering. 68. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 75--84. Elsevier {BV}
Dai, G., Mishnaevsky, L.(2015). Carbon nanotube reinforced hybrid composites: Computational modeling of environmental fatigue and usability for wind blades . Composites Part B: Engineering. 78. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 349-360.
Mishnaevsky, L.(2015). Damage Mechanisms of Hierarchical Composites: Computational Modelling . Physical Mesomechanics. 18. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 416-423.
Leon Mishnaevsky Jr.(2015). Nanostructured interfaces for enhancing mechanical properties of composites: Computational micromechanical studies . Composites Part B: Engineering. 68. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 75--84. Pergamon Press
Mishnaevsky, L., Levashov, E.(2015). Micromechanical modelling of nanocrystalline and ultrafine grained metals: A short overview . Computational Materials Science. 96. (PA). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 365-373.
Pavel Loginov, Leon Mishnaevsky Jr., Evgeny Levashov, Mikhail Petrzhik(2015). Diamond and cBN hybrid and nanomodified cutting tools with enhanced performance: Development, testing and modelling . Materials & Design. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310--319. Elsevier
Gaoming Dai, Leon Mishnaevsky Jr.(2015). Carbon nanotube reinforced hybrid composites: Computational modeling of environmental fatigue and usability for wind blades . Composites Part B: Engineering. 78. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 349--360. Pergamon Press
Mishnaevsky, L.(2015). Nanostructured interfaces for enhancing mechanical properties of composites: Computational micromechanical studies . Composites Part B: Engineering. 68. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 75-84.
Leon Mishnaevsky Jr., Evgeny Levashov(2015). Micromechanical modelling of nanocrystalline and ultrafine grained metals: A short overview . Computational Materials Science. 96. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 365--373. Elsevier
Sidorenko, D., Mishnaevsky, L., Levashov, E., Loginov, P., Petrzhik, M.(2015). Carbon nanotube reinforced metal binder for diamond cutting tools . Materials and Design. 83. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 536-544.
Loginov, P., Mishnaevsky, L., Levashov, E., Petrzhik, M.(2015). Diamond and cBN hybrid and nanomodified cutting tools with enhanced performance: Development, testing and modelling . Materials and Design. 88. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310-319.
Daria Sidorenko, Leon Mishnaevsky Jr., Evgeny Levashov, Pavel Loginov, Mikhail Petrzhik(2015). Carbon nanotube reinforced metal binder for diamond cutting tools . Materials & Design. 83. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 536--544. Elsevier
Hongsheng Liu, Leon Mishnaevsky, Jr.(2014). Gradient ultrafine-grained titanium: Computational study of mechanical and damage behavior . Acta Materialia. 71. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 220--233. Elsevier {BV}
Leon Mishnaevsky Jr., Gaoming Dai(2014). Hybrid carbon/glass fiber composites: Micromechanical analysis of structure–damage resistance relationships . Computational Materials Science. 81. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 630--640. Elsevier
Mishnaevsky Jr., L., Dai, G.(2014). Hybrid and hierarchical nanoreinforced polymer composites: Computational modelling of structure-properties relationships . Composite Structures. 117. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 156-168.
Liu, H., Mishnaevsky Jr., L.(2014). Gradient ultrafine-grained titanium: Computational study of mechanical and damage behavior . Acta Materialia. 71. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 220-233.
Dai, G., Mishnaevsky, L.(2014). Graphene reinforced nanocomposites: 3D simulation of damage and fracture . Computational Materials Science. 95. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 684-692.
Dai, G., Mishnaevsky, L.(2014). Fatigue of multiscale composites with secondary nanoplatelet reinforcement: 3D computational analysis . Composites Science and Technology. 91. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 71-81.
Mishnaevsky, L., Dai, G.(2014). Hybrid carbon/glass fiber composites: Micromechanical analysis of structure-damage resistance relationships . Computational Materials Science. 81. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 630-640.
R. T. De Silva, Pooria Pasbakhsh, K. L. Goh, Leon Mishnaevsky Jr.(2014). 3-D computational model of poly (lactic acid)/halloysite nanocomposites: Predicting elastic properties and stress analysis . Polymer. 55. (24). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 6418--6425. Elsevier
Microscale damage mechanisms and degradation of fiber-reinforced composites for wind energy applications: results of Danish–Chinese collaborative investigations @article{3f5c438c65b941e384630e92193012d6, title = "Microscale damage mechanisms and degradation of fiber-reinforced composites for wind energy applications: results of Danish–Chinese collaborative investigations", abstract = "Recent research works in the area of experimental and computational analyses of microscale mechanisms of strength, damage and degradation of glass fiber polymer composites for wind energy applications, which were carried out in the framework of a series of Sino–Danish collaborative research projects, are summarized in this article. In a series of scanning electron microscopy in situ experimental studies of composite degradation under off-axis tensile, compressive and cyclic loadings as well as three-dimensional computational experiments based on micromechanics of composites and damage mechanics, typical damage mechanisms of wind turbine blade composites were clarified. It was demonstrated that the damage mechanisms in the composites strongly depend on the orientation angle of the applied loading with the fiber direction. The matrix cracking was observed to be the main damage mechanism for tensile axial (or slightly off-axis axial) loading; for all other cases (off-axis tensile, compressive and cyclic tensile loadings), the interface debonding and shear control the damage mechanisms.", keywords = "Composites, Wind blades, Damage, Compression", author = "Leon Mishnaevsky and H.W. Zhou and H.Y. Yi and R.D. Peng and H.W. Wang and Gaoming Dai and L.L. Gui and X. Zhang", year = "2014", doi = "10.1177/0021998313503876", language = "English", volume = "48", pages = "2977--2991", journal = "Journal of Composite Materials", issn = "0021-9983", publisher = "SAGE Publications", number = "24", } . Journal of Composite Materials.
Mishnaevsky, L., Zhou, H.W., Yi, H.Y., Peng, R.D., Wang, H.W., Dai, G.M., Gui, L.L., Zhang, X.(2014). Microscale damage mechanisms and degradation of fiber-reinforced composites for wind energy applications: Results of Danish-Chinese collaborative investigations . Journal of Composite Materials. 48. (24). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2977-2991.
Dai, G., Mishnaevsky, L.(2014). Fatigue of hybrid glass/carbon composites: 3D computational studies . Composites Science and Technology. 94. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 71-79.
De Silva, R.T., Pasbakhsh, P., Goh, K.L., Mishnaevsky, L.(2014). 3-D computational model of poly (lactic acid)/halloysite nanocomposites: Predicting elastic properties and stress analysis . Polymer (United Kingdom). 55. (24). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 6418-6425.
Hongsheng Liu, Leon Mishnaevsky Jr., Wolfgang Pantleon(2014). Non-equilibrium grain boundaries in titanium nanostructured by severe plastic deformation: Computational study of sources of material strengthening . Computational Materials Science. 83. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 318--330. Elsevier
Leon Mishnaevsky Jr., Evgeny Levashov, Ruslan Z. Valiev, Javier Segurado, Ilchat Sabirov, Nariman Enikeev, Sergey Prokoshkin, Andrey V. Solov'yov, Andrey Korotitskiy, Elazar Gutmanas, et al.(2014). Nanostructured titanium-based materials for medical implants: Modeling and development . Materials Science and Engineering R: Reports. 81. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1--19. Elsevier
Liu, H., Pantleon, W., Mishnaevsky Jr., L.(2014). Non-equilibrium grain boundaries in titanium nanostructured by severe plastic deformation: Computational study of sources of material strengthening . Computational Materials Science. 83. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 318-330.
Gaoming Dai, Leon Mishnaevsky Jr.(2014). Fatigue of multiscale composites with secondary nanoplatelet reinforcement: 3D computational analysis . Composites Science and Technology. 91. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 71--81. Elsevier
Mishnaevsky Jr., L., Levashov, E., Valiev, R.Z., Segurado, J., Sabirov, I., Enikeev, N., Prokoshkin, S., Solov'Yov, A.V., Korotitskiy, A., Gutmanas, E., et al.(2014). Nanostructured titanium-based materials for medical implants: Modeling and development . Materials Science and Engineering R: Reports. 81. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1-19.
Gaoming Dai, Leon Mishnaevsky Jr.(2014). Graphene reinforced nanocomposites: 3D simulation of damage and fracture . Computational Materials Science. 95. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 684--692. Elsevier
Hongsheng Liu, Leon Mishnaevsky Jr.(2014). Gradient ultrafine-grained titanium: Computational study of mechanical and damage behavior . Acta Materialia. 71. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 220--233. Elsevier
Leon Mishnaevsky Jr., Gaoming Dai(2014). Hybrid and hierarchical nanoreinforced polymer composites: Computational modelling of structure–properties relationships . Composite Structures. 117. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 156--168. Elsevier
Fatigue of hybrid glass/carbon composites: 3D computational studies @article{1135d08f7b0541a799e1d4c627e6a52b, title = "Fatigue of hybrid glass/carbon composites: 3D computational studies", abstract = "3D computational simulations of fatigue of hybrid carbon/glass fiber reinforced composites is carried out using X-FEM and multifiber unit cell models. A new software code for the automatic generation of unit cell multifiber models of composites with randomly misaligned fibers of various properties and geometrical parameters is developed. With the use of this program code and the X-FEM method, systematic investigations of the effect of microstructure of hybrid composites (fraction of carbon versus glass fibers, misalignment, and interface strength) and the loading conditions (tensile versus compression cyclic loading effects) on fatigue behavior of the materials are carried out. It was demonstrated that the higher fraction of carbon fibers in hybrid composites is beneficial for the fatigue lifetime of the composites under tension-tension cyclic loading, but might have negative effect on the lifetime under compression-compression, and has mixed effect for the tension-compression cyclic loading. Further, it was observed that while the fiber misalignment has some potential for increasing the fracture toughness of the hybrid composites, it speeds up the fiber damage and leads to the shortening of fatigue life. {\textcopyright} 2014 Elsevier Ltd.", keywords = "Polymer–matrix composites (PMCs), Fatigue, Modeling, Hybrid composites", author = "Gaoming Dai and Leon Mishnaevsky", year = "2014", doi = "10.1016/j.compscitech.2014.01.014", language = "English", volume = "94", pages = "71--79", journal = "Composites Science and Technology", issn = "0266-3538", publisher = "Elsevier", } . Composites Science and Technology.
Martensitic transformations in nanostructured nitinol: Finite element modeling of grain size and distribution effects @article{5a0fd4e6081f4d44afae75805e1b8ee2, title = "Martensitic transformations in nanostructured nitinol: Finite element modeling of grain size and distribution effects", abstract = "A computational model of martensitic phase transformation in nanostructured nitinol is developed which takes into account the grain size effect. On the basis of the theoretical analysis of the thermodynamic transformation criterion and the energy barrier for phase transformation, it was demonstrated that the energy barrier for martensitic phase transformation in nanocrystalline nitinol increase drastically with decreasing the grain size. Finite element simulations of phase transformations and structure evolution in nanocrystalline nitinol under mechanical (tensile) loading are carried out for different structures of the materials. It was observed that the volume content of martensitic phase decreases drastically with reducing the grain size. When the grain size is smaller than some critical value (around 50–80nm, both in our simulations and in experimental data), the martensitic phase transformation are totally suppressed. Graded and localized distributions of grain sizes of nitinol were compared with nitinol samples with homogeneous grain size distribution. In the materials with localized region of small grains, it was observed that the martensite rich regions form first on the border between the coarse and fine grained regions, and expand inside the region with small grains along the shear band direction.", keywords = "Martensitic phase transformations, Nanostructured nitinol, Finite element", author = "Hong-Sheng Liu and Leon Mishnaevsky", note = "Selected Publication of the EU FP7 project VIRTUAL NANOTITANIUM (VINAT) {"}Theoretical analysis and virtual testing of titanium-based nanomaterials{"}", year = "2013", doi = "10.1016/j.commatsci.2012.11.032", language = "English", volume = "76", pages = "27--36", journal = "Computational Materials Science", issn = "0927-0256", publisher = "Elsevier", } . Computational Materials Science.
H. W. Zhou, C. P. Wang, Leon Mishnaevsky Jr., Z. Q. Duan, J. Y. Ding(2013). A fractional derivative approach to full creep regions in salt rock . Mechanics of Time Dependent Materials. 17. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 413--425. Springer Netherlands
Leon Mishnaevsky Jr., H.W. Zhou, R.D. Peng, Gaoming Dai, H.W. Wang(2013). Polymer Nanocomposites for Wind Energy Applications: Perspectives and Computational Modeling . Nanomaterials: Applications & Properties. International Conference Proceedings. 2. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 04NEA07. Sumy State University
Dai, G., Mishnaevsky, L.(2013). Damage evolution in nanoclay-reinforced polymers: A three-dimensional computational study . Composites Science and Technology. 74. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 67-77.
Gaoming Dai, Leon Mishnaevsky Jr.(2013). Damage evolution in nanoclay-reinforced polymers: A three-dimensional computational study . Composites Science and Technology. 74. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 67--77. Elsevier
Compressive damage mechanism of GFRP composites under off-axis loading: Experimental and numerical investigations @article{5df8ff85be144368a8205704170e1535, title = "Compressive damage mechanism of GFRP composites under off-axis loading: Experimental and numerical investigations", abstract = "Experimental and computational studies of the microscale mechanisms of damage formation and evolution in unidirectional glass fiber reinforced polymer composites (GFRP) under axial and off-axis compressive loading are carried out. A series of compressive testing of the composites with different angles between the loading vector and fiber direction were carried out under scanning electron microscopy (SEM) in situ observation. The damage mechanisms as well as stress strain curves were obtained in the experiments. It was shown that the compressive strength of composites drastically reduces when the angle between the fiber direction and the loading vector goes from 0° to 45° (by 2.3–2.6 times), and then slightly increases (when the angle approaches 80–90°). At the low angles between the fiber and the loading vector, fiber buckling and kinking are the main mechanisms of fiber failure. With increasing the angle between the fiber and applied loading, failure of glass fibers is mainly controlled by shear cracking. For the computational analysis of the damage mechanisms, 3D multifiber unit cell models of GFRP composites and X-FEM approach to the fracture modeling were used. The computational results correspond well to the experimental observations.{\textcopyright} 2013 Elsevier Ltd. All rights reserved.", keywords = "Polymer–matrix composites (PMCs), Strength, Finite element analysis (FEA), Computational modeling, Electron microscopy", author = "H.W. Zhou and H.Y. Li and L.L. Gui and Gaoming Dai and R.D. Peng and H.W. Wang and Leon Mishnaevsky", year = "2013", doi = "10.1016/j.compositesb.2013.06.007", language = "English", volume = "55", pages = "119--127", journal = "Composites Part B: Engineering", issn = "1359-8368", publisher = "Pergamon Press", } . Composites Part B: Engineering.
Mishnaevsky Jr., L., Levashov, E.(2013). Editorial . Computational Materials Science. 76. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1-2.
Zhou, H.W., Wang, C.P., Mishnaevsky Jr., L., Duan, Z.Q., Ding, J.Y.(2013). A fractional derivative approach to full creep regions in salt rock . Mechanics of Time-Dependent Materials. 17. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 413-425.
Henrik Stensgaard Toft, Kim Branner, Leon Mishnaevsky Jr., John Dalsgaard Sørensen(2013). Uncertainty modelling and code calibration for composite materials . Journal of Composite Materials. 47. (14). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1729--1747. SAGE Publications
Toft, H.S., Branner, K., Mishnaevsky, L., Sørensen, J.D.(2013). Uncertainty modelling and code calibration for composite materials . Journal of Composite Materials. 47. (14). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1729-1747.
Toft, H. S. and Branner, K. and Mishnaevsky, L. and Sorensen, J. D.(2013). Uncertainty modelling and code calibration for composite materials . Journal of Composite Materials. 47. (14). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1729-1747. Sage Publications
ZHOU, HongWei and YI, HaiYang and XUE, DongJie and DUAN, ZhiQiang and ZHANG, ChunHua and MISHNAEVSKY, Jr. L.(2013). Influence of fibers' orientation angle on failure mechanism of glass fiber reinforced polymer composites . Scientia Sinica Physica, Mechanica & Astronomica. 43. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 167. Science in China Press
Liu, H.S., Mishnaevsky, L.(2013). Martensitic transformations in nanostructured nitinol: Finite element modeling of grain size and distribution effects . Computational Materials Science. 76. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 27-36.
Zhou, H.W., Yi, H.Y., Gui, L.L., Dai, G.M., Peng, R.D., Wang, H.W., Mishnaevsky Jr., L.(2013). Compressive damage mechanism of GFRP composites under off-axis loading: Experimental and numerical investigations . Composites Part B: Engineering. 55. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 119-127.
Micromechanical analysis of nanocomposites using 3D voxel based material model @article{572869f9281841949b151d7976ec1517, title = "Micromechanical analysis of nanocomposites using 3D voxel based material model", abstract = "A computational study on the effect of nanocomposite structures on the elastic properties is carried out with the use of the 3D voxel based model of materials and the combined Voigt–Reuss method. A hierarchical voxel based model of a material reinforced by an array of exfoliated and intercalated nanoclay platelets surrounded by interphase layers is developed. With this model, the elastic properties of the interphase layer are estimated using the inverse analysis. The effects of aspect ratio, intercalation and orientation of nanoparticles on the elastic properties of the nanocomposites are analyzed. For modeling the damage in nanocomposites with intercalated structures, “four phase” model is suggested, in which the strength of “intrastack interphase” is lower than that of “outer” interphase around the nanoplatelets. Analyzing the effect of nanoreinforcement in the matrix on the failure probability of glass fibers in hybrid (hierarchical) composites, using the micromechanical voxel-based model of nanocomposites, it was observed that the nanoreinforcement in the matrix leads to slightly lower fiber failure probability.", keywords = "Nano composites, Strength, Stress transfer", author = "Leon Mishnaevsky", year = "2012", doi = "10.1016/j.compscitech.2012.03.026", language = "English", volume = "72", pages = "1167--1177", journal = "Composites Science and Technology", issn = "0266-3538", publisher = "Elsevier", number = "10", } . Composites Science and Technology.
Peng, R.D., Zhou, H.W., Wang, H.W., Mishnaevsky Jr., L.(2012). Modeling of nano-reinforced polymer composites: Microstructure effect on Young's modulus . Computational Materials Science. 60. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 19-31.
Leon Mishnaevsky Jr., Povl Brøndsted, Rogier Nijssen, D.J. Lekou, T.P. Philippidis(2012). Materials of large wind turbine blades: Recent results in testing and modeling . Wind Energy. 15. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 83--97. JohnWiley & Sons Ltd.
Mishnaevsky, L.(2012). Micromechanical analysis of nanocomposites using 3D voxel based material model . Composites Science and Technology. 72. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1167-1177.
Mishnaevsky Jr., L.(2012). Micromechanics of hierarchical materials: A brief overview . Reviews on Advanced Materials Science. 30. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 60-72.
Brondsted, P., Lekou, D. J., Mishnaevsky, L., Nijssen, R., Philippidis, T. P.(2012). Materials of large wind turbine blades: recent results in testing and modeling . Wind Energy. 15. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 83-97.
Leon Mishnaevsky Jr.(2012). Micromechanics of hierarchical materials . Reviews on Advanced Materials Science. 30. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 60--72. Rossiiskaya Akademiya Nauk Institut Problem Mashinovedeniya
Leon Mishnaevsky Jr.(2012). Composite materials for wind energy applications: micromechanical modeling and future directions . Computational Mechanics. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 195--207. Springer
Mishnaevsky, L.(2012). MICROMECHANICS OF HIERARCHICAL MATERIALS: A BRIEF OVERVIEW. Reviews on Advanced Materials Science. 30. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 60-72.
Mishnaevsky, L., Peng, R. D., Wang, H. W., Zhou, H. W.(2012). Modeling of nano-reinforced polymer composites: Microstructure effect on Young's modulus . Computational Materials Science. 60. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 19-31.
Mishnaevsky, L.(2012). Composite materials for wind energy applications: Micromechanical modeling and future directions . Computational Mechanics. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 195-207.
Mishnaevsky, L.(2012). Composite materials for wind energy applications: micromechanical modeling and future directions . Computational Mechanics. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 195-207.
Mishnaevsky, L.(2012). Micromechanical analysis of nanocomposites using 3D voxel based material model . Composites Science and Technology. 72. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1167-1177.
Modeling of nano-reinforced polymer composites: Microstructure effect on Young’s modulus @article{434a3433ee634bf8b5084e9e7127aac9, title = "Modeling of nano-reinforced polymer composites: Microstructure effect on Young{\textquoteright}s modulus", abstract = "A computational numerical-analytical model of nano-reinforced polymer composites is developed taking into account the interface and particle clustering effects. The model was employed to analyze the interrelationships between microstructures and mechanical properties of nanocomposites. An improved effective interface model which is based on Mori–Tanaka approach and includes the nanoparticle geometry and clustering effects was developed. A program code for the automatic generation of two-dimensional multiparticle unit cell models of nanocomposites and finite element meshes on the basis of “grid method” algorithm was developed in the ABAQUS Scripting Interface. In the computational studies, it was observed that the elastic modulus increases with the increasing the aspect ratio of nanoparticles. The thickness and properties of effective interface layers and the shape and degree of particles clustering have strong influence on the mechanical properties of nanocomposite.", keywords = "Nanocomposite, Modeling, Interface, Finite elements, Elastic properties, Nano-reinforced polymer, Microstructure FE models, Clustering", author = "R.D. Peng and H.W. Zhou and H.W. Wang and Mishnaevsky, {Leon, Jr.}", year = "2012", doi = "10.1016/j.commatsci.2012.03.010", language = "English", volume = "60", pages = "19--31", journal = "Computational Materials Science", issn = "0927-0256", publisher = "Elsevier", } . Computational Materials Science.
Hierarchical composites: Analysis of damage evolution based on fiber bundle model @article{58a8068b6eaf49cc942010d425d8dfb7, title = "Hierarchical composites: Analysis of damage evolution based on fiber bundle model", abstract = "A computational model of multiscale composites is developed on the basis of the fiber bundle model with the hierarchical load sharing rule, and employed to study the effect of the microstructures of hierarchical composites on their damage resistance. Two types of hierarchical materials were considered: “hierarchical tree” (bundles-of-bundles of fibers) and self-similar particle and fiber reinforced composite (in which reinforcements at each scale level represents composites in turn consisting of lower level reinforcements and matrix). For the case of the hierarchical tree (“bundle-of-bundles” material), it was observed that the increase in the amount of hierarchy levels leads to the lower strength of material. In the self-similar fiber reinforced matrix materials, as differed from the hierarchical trees, the damage resistance of the hierarchical materials increases with increasing the amount of hierarchy levels. The effect of mixed fiber and particle reinforcement on the damage resistance of the hierarchical composites is investigated as well.", keywords = "Light strong materials for energy purposes, Lette st{\ae}rke materialer til energiform{\aa}l", author = "Leon Mishnaevsky", year = "2011", doi = "10.1016/j.compscitech.2010.12.017", language = "English", volume = "71", pages = "450--460", journal = "Composites Science and Technology", issn = "0266-3538", publisher = "Elsevier", number = "4", } . Composites Science and Technology.
Abhilash, A.S., Joshi, S.P., Mukherjee, A., Mishnaevsky, L.(2011). Micromechanics of diffusion-induced damage evolution in reinforced polymers . Composites Science and Technology. 71. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 333-342.
Kushch, V.I., Shmegera, S.V., Mishnaevsky, L.(2011). Explicit modeling the progressive interface damage in fibrous composite: Analytical vs. numerical approach . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 989-997.
Wang, H.W., Zhou, H.W., Peng, R.D., Mishnaevsky, L.(2011). Nanoreinforced polymer composites: 3D FEM modeling with effective interface concept . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 980-988.
Mishnaevsky, L.(2011). Hierarchical composites: Analysis of damage evolution based on fiber bundle model . Composites Science and Technology. 71. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 450-460.
Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2011). Elastic interaction of partially debonded circular inclusions. II. Application to fibrous composite . International Journal of Solids and Structures. 48. (16-17). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2413-2421.
Hai Qing, Leon Mishnaevsky Jr.(2011). Fatigue modeling of materials with complex microstructures . Computational Materials Science. 50. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1644--1650. Elsevier
V. Kushch, S.V. Shmegera, Povl Brøndsted, Leon Mishnaevsky Jr.(2011). Numerical simulation of progressive debonding in fiber reinforced composite under transverse loading . International Journal of Engineering Science. 49. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 17--29. Elsevier
H.W. Wang, H.W. Zhou, R.D. Peng, Leon Mishnaevsky Jr.(2011). Nanoreinforced polymer composites: 3D FEM modeling with effective interface concept . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 980--988. Elsevier
Acharya, P., Freere, P., Manandhar, P., Mishnaevsky, L., Shrestha, R., Sinha, R.(2011). Small wind turbines with timber blades for developing countries: Materials choice, development, installation and experiences . Renewable Energy. 36. (8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2128-2138.
Qing, H., Mishnaevsky Jr., L.(2011). Fatigue modeling of materials with complex microstructures . Computational Materials Science. 50. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1644-1650.
Mishnaevsky, L., Peng, R. D., Wang, H. W., Zhou, H. W.(2011). Nanoreinforced polymer composites: 3D FEM modeling with effective interface concept . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 980-988.
Micromechanics of diffusion-induced damage evolution in reinforced polymers @article{3947c3df1daa47e2ba6053cb3572fecc, title = "Micromechanics of diffusion-induced damage evolution in reinforced polymers", abstract = "In this work we numerically investigate the nucleation and evolution of micromechanical damage in reinforced glassy polymers under transient hygro-mechanical loading. In particular, we demonstrate the role that fiber distribution plays in the evolution of overall damage due to fiber–matrix interfacial debonding under moisture ingress. The heterogeneity of fiber distribution (clustering) is characterized by the coefficient of variation Cv of the center-to-center distances between interacting fibers, determined by identifying a cut-off radius around a typical fiber. The initial moisture diffusion-induced damage provides synergistic conditions for the rapid evolution of debonding under subsequent mechanical loading. The results indicate that microstructural heterogeneity strongly affects the moisture diffusion characteristics that in turn hurt the overall load carrying capacity of a composite due to aggravated damage. The strong dependence of the moisture-induced damage evolution on the fiber arrangement suggests that one should not resort to using simplistic unit cell models that assume regular fiber arrangements in such cases.", keywords = "Materials and energy storage, Light strong materials for energy purposes, Lette st{\ae}rke materialer til energiform{\aa}l, Materialer og energilagring", author = "A.S. Abhilash and Joshi, {Shailendra P.} and Abhijit Mukherjee and Leon Mishnaevsky", year = "2011", doi = "10.1016/j.compscitech.2010.11.027", language = "English", volume = "71", pages = "333--342", journal = "Composites Science and Technology", issn = "0266-3538", publisher = "Elsevier", number = "3", } . Composites Science and Technology.
Mishnaevsky, L., Freere, P., Sinha, R., Acharya, P., Shrestha, R., Manandhar, P.(2011). Small wind turbines with timber blades for developing countries: Materials choice, development, installation and experiences . Renewable Energy. 36. (8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2128-2138.
Mishnaevsky, L.(2011). Hierarchical composites: Analysis of damage evolution based on fiber bundle model . Composites Science and Technology. 71. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 450-460.
V.I. Kushch, S.V. Shmegera, Leon Mishnaevsky Jr.(2011). Elastic interaction of partially debonded circular inclusions. II. Application to fibrous composite . International Journal of Solids and Structures. 48. (16-17). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2413--2421. Pergamon Press
Brondsted, P., Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2011). Numerical simulation of progressive debonding in fiber reinforced composite under transverse loading . International Journal of Engineering Science. 49. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 17-29.
Leon Mishnaevsky Jr., Peter Freere, Rakesh Sinha, Parash Acharya, Rakesh Shrestha, Pushkar Manandhar(2011). Small wind turbines with timber blades for developing countries: Materials choice, development, installation and experiences . Renewable Energy. 36. (8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2128--2138. Pergamon Press
Kushch, V.I., Shmegera, S.V., Mishnaevsky Jr., L.(2011). Elastic interaction of partially debonded circular inclusions. II. Application to fibrous composite . International Journal of Solids and Structures. 48. (16-17). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2413-2421.
Hai Qing, Leon Mishnaevsky Jr.(2011). A 3D multilevel model of damage and strength of wood: Analysis of microstructural effects . Mechanics of Materials. 43. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 487--495. Elsevier
V.I. Kushch, S.V. Shmegera, Leon Mishnaevsky Jr.(2011). Explicit modeling the progressive interface damage in fibrous composite: Analytical vs. numerical approach . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 989--997. Elsevier
Leon Mishnaevsky Jr., Povl Brøndsted, V. Kushch, S. Shmegera, H. Zhou, R. Peng, A. Mukherjee, S. Joshi(2011). Mechanisms and micromechanics of degradation of wind blade composites: Results of UPWIND.TTC project . Proceedings of the Risø International Symposium on Materials Science. 32. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 393--398. Ris{\o} National Laboratory
Abhilash, A. S., Joshi, S. P., Mishnaevsky, L., Mukherjee, A.(2011). Micromechanics of diffusion-induced damage evolution in reinforced polymers . Composites Science and Technology. 71. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 333-342.
Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2011). Explicit modeling the progressive interface damage in fibrous composite: Analytical vs. numerical approach . Composites Science and Technology. 71. (7). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 989-997.
Mishnaevsky, L., Qing, H.(2011). Fatigue modeling of materials with complex microstructures . Computational Materials Science. 50. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1644-1650.
Qing, H., Mishnaevsky Jr., L.(2011). A 3D multilevel model of damage and strength of wood: Analysis of microstructural effects . Mechanics of Materials. 43. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 487-495.
Mishnaevsky, L., Qing, H.(2011). A 3D multilevel model of damage and strength of wood: Analysis of microstructural effects . Mechanics of Materials. 43. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 487-495.
Kushch, V.I., Shmegera, S.V., Brøndsted, P., Mishnaevsky Jr., L.(2011). Numerical simulation of progressive debonding in fiber reinforced composite under transverse loading . International Journal of Engineering Science. 49. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 17-29.
Mishnaevsky, L., Qing, H.(2010). 3D constitutive model of anisotropic damage for unidirectional ply based on physical failure mechanisms . Computational Materials Science. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 479-486.
Brondsted, P., Gui, L. L., Mishnaevsky, L., Tan, J. B., Zhou, H. W.(2010). SEM in situ laboratory investigations on damage growth in GFRP composite under three-point bending tests . Chinese Science Bulletin. 55. (12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1199-1208.
3D multiscale micromechanical model of wood: From annual rings to microfibrils @article{34c5c5b111f84b2cb7893c7ce3f57564, title = "3D multiscale micromechanical model of wood: From annual rings to microfibrils", abstract = "A 3D micromechanical analytical-computational model of softwood, which takes into account the wood microstructures at four scale levels, from microfibrils to annual rings, is developed. For the analysis of the effect of the annual rings structure on the properties of softwood, an improved rule-of-mixture model, based on 3D orthotropic stress–strain relations and taking into account the compatibility of deformations at the interface of two phases and equilibrium of tractions at phase boundaries, is proposed. The improved rule of mixture model (IRoM) was compared with the classical rule-of-mixture (RoM) and finite element method (FEM) simulations. It was shown that IRoM gives almost as good results as FEM. The analytical model of annual rings is combined with the 3D finite element model of softwood as cellular material with multilayered, microfibril reinforced cell walls, developed by (Qing and Mishnaevsky, 2009a) and (Qing and Mishnaevsky, 2009b). Using the combined four-level model, the effect of wood density, microfibril angle (MFA) and cell shape angle (CSA) on the Young{\textquoteright}s moduli, Poisson{\textquoteright}s ratios and shrinkage properties of softwood has been investigated in numerical experiments. The simulations were verified by comparison with experimental data.", keywords = "Materials and energy storage, Light strong materials for energy purposes, Lette st{\ae}rke materialer til energiform{\aa}l, Materialer og energilagring", author = "Hai Qing and Leon Mishnaevsky", year = "2010", doi = "10.1016/j.ijsolstr.2010.01.014", language = "English", volume = "47", pages = "1253--1267", journal = "International Journal of Solids and Structures", issn = "0020-7683", publisher = "Pergamon Press", number = "9", } . International Journal of Solids and Structures.
Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2010). Elastic interaction of partially debonded circular inclusions. I. Theoretical solution . International Journal of Solids and Structures. 47. (14-15). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1961-1971.
Hong Wei Zhou, Leon Mishnaevsky Jr., Povl Brøndsted, JinBiao Tan, LeLe Gui(2010). SEM in situ laboratory investigations on damage growth in GFRP composite under three-point bending tests . Chinese Science Bulletin. 55. (12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1199--1208.
Mishnaevsky Jr., L., Habil, Wood, D.(2010). Wind Engineering: Editorial . Wind Engineering. 34. (3).
Mishnaevsky, Leon and Habil and Wood, David(2010). Editorial . Wind Engineering. 34. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString i-iv. Multiscience
Sinha, R., Acharya, P., Freere, P., Sharma, R., Ghimire, P., Mishnaevsky Jr., L.(2010). Selection of Nepalese timber for small wind turbine blade construction . Wind Engineering. 34. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 263-276.
V.I. Kushch, S.V. Shmegera, Leon Mishnaevsky Jr.(2010). Elastic interaction of partially debonded circular inclusions. I. Theoretical solution . International Journal of Solids and Structures. 47. (14-15). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1961--1971. Pergamon Press
Hai Qing, Leon Mishnaevsky Jr.(2010). 3D constitutive model of anisotropic damage for unidirectional ply based on physical failure mechanisms . Computational Materials Science. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 479--486. Elsevier
Qing, H., Mishnaevsky Jr., L.(2010). 3D multiscale micromechanical model of wood: From annual rings to microfibrils . International Journal of Solids and Structures. 47. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1253-1267.
R. Sinha, Parash Acharya, Peter Freere, Ranjan Sharma, Pramod Ghimire, Leon Mishnaevsky Jr.(2010). Selection of Nepalese Timber for Small Wind Turbine Blade Construction . Wind Engineering. 34. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 263--276. SAGE Publications
Zhou, H.W., Mishnaevsky Jr., L., Brøndsted, P., Tan, J.B., Gui, L.L.(2010). SEM in situ laboratory investigations on damage growth in GFRP composite under three-point bending tests . Chinese Science Bulletin. 55. (12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1199-1208.
Leon Mishnaevsky Jr., Povl Brøndsted, Hai Qing, Huaiwen Wang, Rasmus C. Østergaard, Bent F. Sørensen(2010). Computational micromechanics of wind blade materials: Recent activities at the Materials Research Division, Risø DTU . Proceedings of the Risø International Symposium on Materials Science. 31. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 345--352. Ris{\o} National Laboratory
Kushch, V.I., Shmegera, S.V., Mishnaevsky Jr., L.(2010). Elastic interaction of partially debonded circular inclusions. I. Theoretical solution . International Journal of Solids and Structures. 47. (14-15). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1961-1971.
Mishnaevsky, L., Qing, H.(2010). 3D multiscale micromechanical model of wood: From annual rings to microfibrils . International Journal of Solids and Structures. 47. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1253-1267.
Qing, H., Mishnaevsky Jr., L.(2010). 3D constitutive model of anisotropic damage for unidirectional ply based on physical failure mechanisms . Computational Materials Science. 50. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 479-486.
Sinha, Rakesh and Acharya, Parash and Freere, Peter and Sharma, Ranjan and Ghimire, Pramod and Mishnaevsky, Leon(2010). Selection of Nepalese Timber for Small Wind Turbine Blade Construction . Wind Engineering. 34. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 263-276. Multiscience
H.W. Wang, H.W. Zhou, Leon Mishnaevsky Jr., Povl Brøndsted, L.N. Wang(2009). Single fibre and multifibre unit cell analysis of strength and cracking of unidirectional composites . Computational Materials Science. 46. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 810--820. Elsevier
Leon Mishnaevsky Jr., Peter Freere, Ranjan Sharma, Povl Brøndsted, Hai Qing, Jakob Ilsted Bech, Rakesh Sinha, Parash Acharya, Robert Evans(2009). Strength and Reliability of Wood for the Components of Low-cost Wind Turbines: Computational and Experimental Analysis and Applications . Wind Engineering. 33. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 183--196. SAGE Publications
Statistical modelling of compression and fatigue damage of unidirectional fiber reinforced composites @article{6f7ec50aafdb4e78a98c4206a18d45b9, title = "Statistical modelling of compression and fatigue damage of unidirectional fiber reinforced composites", abstract = "A statistical computational model of strength and damage of unidirectional carbon fiber reinforced composites under compressive and cyclic compressive loading is presented in this paper. The model is developed on the basis of the Budiansky–Fleck fiber kinking condition, continuum damage mechanics concept and the Monte-Carlo method. The effects of fiber misalignment variability, fiber clustering, load sharing rules on the damage in composite are studied numerically. It is demonstrated that the clustering of fibers has a negative effect of the damage resistance of a composite. Further, the static compressive loading model is generalized for the case of cyclic compressive loading, with and without microdegradation of the matrix, and with and without random variations of loading. It was observed that the random variations of loading shorten the lifetime of the composite: the larger the variability of applied load, the shorter the lifetime.", keywords = "Materials research, Light strong materials for wind turbines and for transportation, Lette st{\ae}rke materialer til vindm{\o}ller og til transport, Materialeforskning", author = "Leon Mishnaevsky and Povl Br{\o}ndsted", year = "2009", doi = "10.1016/j.compscitech.2008.11.024", language = "English", volume = "69", pages = "477--484", journal = "Composites Science and Technology", issn = "0266-3538", publisher = "Elsevier", number = "3-4", } . Composites Science and Technology.
Mishnaevsky, L., Qing, H.(2009). Unidirectional high fiber content composites: Automatic 3D FE model generation and damage simulation . Computational Materials Science. 47. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 548-555.
Mishnaevsky Jr., L., Freere, P., Sharma, R., Brøndsted, P., Qing, H., Bech, J.I., Sinha, R., Acharya, P., Evans, R.(2009). Strength and reliability of wood for the components of low-cost wind turbines: Computational and experimental analysis and applications . Wind Engineering. 33. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 183-196.
Wang, H.W., Zhou, H.W., Mishnaevsky Jr., L., Brøndsted, P., Wang, L.N.(2009). Single fibre and multifibre unit cell analysis of strength and cracking of unidirectional composites . Computational Materials Science. 46. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 810-820.
Brondsted, P., Mishnaevsky, L.(2009). Statistical modelling of compression and fatigue damage of unidirectional fiber reinforced composites . Composites Science and Technology. 69. (3-4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 477-484.
Mishnaevsky Jr., L., Brøndsted, P.(2009). Statistical modelling of compression and fatigue damage of unidirectional fiber reinforced composites . Composites Science and Technology. 69. (3-4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 477-484.
Kushch, V.I., Shmegera, S.V., Mishnaevsky Jr., L.(2009). Statistics of microstructure, peak stress and interface damage in fiber reinforced composites . Journal of Mechanics of Materials and Structures. 4. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1089-1107.
Volodymyr I. Kushch, Sergii V. Shmegera, Leon Mishnaevsky Jr.(2009). Statistics of Microstructure, Peak Stress and Interface Damage in Fiber Reinforced Composites . Journal of Mechanics of Materials and Structures. 4. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1089--1107. Mathematical Sciences Publishers
Mishnaevsky Jr., L., Wood, D.(2009). Wind Engineering: Editorial . Wind Engineering. 33. (2).
Leon Mishnaevsky Jr., Povl Brøndsted(2009). Micromechanisms of damage in unidirectional fiber reinforced composites . Composites Science and Technology. 69. (7-8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1036--1044. Elsevier
Qing, H., Mishnaevsky Jr., L.(2009). Unidirectional high fiber content composites: Automatic 3D FE model generation and damage simulation . Computational Materials Science. 47. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 548-555.
Brondsted, P., Mishnaevsky, L., Wang, H. W., Wang, L. N., Zhou, H. W.(2009). Single fibre and multifibre unit cell analysis of strength and cracking of unidirectional composites . Computational Materials Science. 46. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 810-820.
Hai Qing, Leon Mishnaevsky Jr.(2009). Moisture-related mechanical properties of softwood: 3D micromechanical modeling . Computational Materials Science. 46. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310--320. Elsevier
Mishnaevsky Jr., L., Brøndsted, P.(2009). Micromechanisms of damage in unidirectional fiber reinforced composites: 3D computational analysis . Composites Science and Technology. 69. (7-8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1036-1044.
Mishnaevsky, L., Qing, H.(2009). Moisture-related mechanical properties of softwood: 3D micromechanical modeling . Computational Materials Science. 46. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310-320.
Mishnaevsky, L., Qing, H.(2009). 3D hierarchical computational model of wood as a cellular material with fibril reinforced, heterogeneous multiple layers . Mechanics of Materials. 41. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1034-1049.
Kushch, V. I., Mishnaevsky, L., Sevostianov, I.(2009). Effect of crack orientation statistics on effective stiffness of mircocracked solid . International Journal of Solids and Structures. 46. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1574-1588.
Qing, H., Mishnaevsky Jr., L.(2009). 3D hierarchical computational model of wood as a cellular material with fibril reinforced, heterogeneous multiple layers . Mechanics of Materials. 41. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1034-1049.
Brondsted, P., Mishnaevsky, L.(2009). Micromechanical modeling of damage and fracture of unidirectional fiber reinforced composites: A review . Computational Materials Science. 44. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1351-1359.
Hai Qing, Leon Mishnaevsky Jr.(2009). Unidirectional high fiber content composites: Automatic 3D FE model generation and damage simulation . Computational Materials Science. 47. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 548--555. Elsevier
Leon Mishnaevsky Jr., Povl Brøndsted(2009). Micromechanical modeling of damage and fracture of unidirectional fiber reinforced composites . Computational Materials Science. 44. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1351--1359. Elsevier
Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2009). STATISTICS OF MICROSTRUCTURE, PEAK STRESS AND INTERFACE DAMAGE IN FIBER REINFORCED COMPOSITES . Journal of Mechanics of Materials and Structures. 4. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1089-1107.
V.I. Kushch, I. Sevostianov, Leon Mishnaevsky Jr.(2009). Effect of crack orientation statistics on effective stiffness of mircocracked solid . International Journal of Solids and Structures. 46. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1574--1588. Pergamon Press
Qing, H., Mishnaevsky, L.(2009). Moisture-related mechanical properties of softwood: 3D micromechanical modeling . Computational Materials Science. 46. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 310-320.
Mishnaevsky Jr., L., Brøndsted, P.(2009). Micromechanical modeling of damage and fracture of unidirectional fiber reinforced composites: A review . Computational Materials Science. 44. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1351-1359.
3D hierarchical computational model of wood as a cellular material with fibril reinforced, heterogeneous multiple layers @article{7f9050eb2cb24cbca02352e84502635b, title = "3D hierarchical computational model of wood as a cellular material with fibril reinforced, heterogeneous multiple layers", abstract = "A 3D hierarchical computational model of deformation and stiffness of wood, which takes into account the structures of wood at several scale levels (cellularity, multilayered nature of cell walls, composite-like structures of the wall layers) is developed. At the mesoscale, the softwood cell is presented as a 3D hexagon-shape-tube with multilayered walls. The layers in the softwood cell are considered as considered as composite reinforced by microfibrils (celluloses). The elastic properties of the layers are determined with Halpin–Tsai equations, and introduced into mesoscale finite element cellular model. With the use of the developed hierarchical model, the influence of the microstructure, including microfibril angles (MFAs, which characterizes the orientation of the cellulose fibrils with respect to the cell axis), the thickness of the cell wall, the shape of the cell cross-section and the cell dimension (wood density), on the elastic properties of softwood was studied.", keywords = "Materials research, Light strong materials for wind turbines and for transportation, Lette st{\ae}rke materialer til vindm{\o}ller og til transport, Materialeforskning", author = "Hai Qing and Leon Mishnaevsky", year = "2009", doi = "10.1016/j.mechmat.2009.04.011", language = "English", volume = "41", pages = "1034--1049", journal = "Mechanics of Materials", issn = "0167-6636", publisher = "Elsevier", number = "9", } . Mechanics of Materials.
Kushch, V.I., Sevostianov, I., Mishnaevsky Jr., L.(2009). Effect of crack orientation statistics on effective stiffness of mircocracked solid . International Journal of Solids and Structures. 46. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1574-1588.
Leon Mishnaevsky Jr., Povl Brøndsted(2008). Three-dimensional numerical modelling of damage initiation in unidirectional fiber-reinforced composites with ductile matrix . Materials Science & Engineering: A. 498. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 81--86. Elsevier
Mishnaevsky Jr., L., Qing, H.(2008). Micromechanical modelling of mechanical behaviour and strength of wood: State-of-the-art review . Computational Materials Science. 44. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 363-370.
Kushch, V.I., Shmegera, S.V., Mishnaevsky Jr., L.(2008). Meso cell model of fiber reinforced composite: Interface stress statistics and debonding paths . International Journal of Solids and Structures. 45. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2758-2784.
Mishnaevsky Jr., L., Brøndsted, P.(2008). Three-dimensional numerical modelling of damage initiation in unidirectional fiber-reinforced composites with ductile matrix . Materials Science and Engineering A. 498. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 81-86.
Brondsted, P., Mishnaevsky, L.(2008). Three-dimensional numerical modelling of damage initiation in unidirectional fiber-reinforced composites with ductile matrix . Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing. 498. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 81-86.
V.I. Kushch, S.V. Shmegera, Leon Mishnaevsky Jr.(2008). Meso cell model of fiber reinforced composite: Interface stress statistics and debonding paths . International Journal of Solids and Structures. 45. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2758--2784. Pergamon Press
Kushch, V. I., Mishnaevsky, L., Shmegera, S. V.(2008). Meso cell model of fiber reinforced composite: Interface stress statistics and debonding paths . International Journal of Solids and Structures. 45. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 2758-2784.
Leon Mishnaevsky Jr., Hai Qing(2008). Micromechanical modelling of mechanical behaviour and strength of wood . Computational Materials Science. 44. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 363--370. Elsevier
Kushch, V. I., Mishnaevsky, L., Sevostianov, I.(2008). Stress concentration and effective stiffness of aligned fiber reinforced composite with anisotropic constituents . International Journal of Solids and Structures. 45. (18-19). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 5103-5117.
V.I. Kushch, I. Sevostianov, Leon Mishnaevsky Jr.(2008). Stress concentration and effective stiffness of aligned fiber reinforced composite with anisotropic constituents . International Journal of Solids and Structures. 45. (18-19). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 5103--5117. Pergamon Press
Kushch, V.I., Sevostianov, I., Mishnaevsky Jr., L.(2008). Stress concentration and effective stiffness of aligned fiber reinforced composite with anisotropic constituents . International Journal of Solids and Structures. 45. (18-19). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 5103-5117.
Mishnaevsky, L., Qing, H.(2008). Micromechanical modelling of mechanical behaviour and strength of wood: State-of-the-art review . Computational Materials Science. 44. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 363-370.
Mishnaevsky Jr., L.(2007). A simple method and program for the analysis of the microstructure- stiffness interrelations of composite materials . Journal of Composite Materials. 41. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 73-87.
Mishnaevsky, L.(2007). A simple method and program for the analysis of the microstructure-stiffness interrelations of composite materials . Journal of Composite Materials. 41. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 73-87.
Leon Mishnaevsky Jr., Povl Brøndsted(2007). Modeling of fatigue damage evolution on the basis of the kinetic concept of strength . International Journal of Fracture. 144. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 149--158. Springer Netherlands
Mishnaevsky Jr., L., Broøndsted, P.(2007). Modeling of fatigue damage evolution on the basis of the kinetic concept of strength . International Journal of Fracture. 144. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 149-158.
Brondsted, P., Mishnaevsky, L.(2007). Modeling of fatigue damage evolution on the basis of the kinetic concept of strength . International Journal of Fracture. 144. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 149-158.
Mishnaevsky, L. L.(2006). Functionally gradient metal matrix composites: Numerical analysis of the microstructure-strength relationships . Composites Science and Technology. 66. (11-12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1873-1887.
Mishnaevsky, Leon(2006). Computational Analysis of the Effects of Microstructures on Damage and Fracture in Heterogeneous Materials . Key Engineering Materials. 306-308. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 489-494. Trans Tech Publications
Mishnaevsky Jr., L.L.(2006). Functionally gradient metal matrix composites: Numerical analysis of the microstructure-strength relationships . Composites Science and Technology. 66. (11-12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1873-1887.
Mishnaevsky Jr., L.L., Gross, D.(2005). Deformation and failure in thin films/substrate systems: Methods of theoretical analysis . Applied Mechanics Reviews. 58. (1-6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 338-353.
Mishnaevsky, L. L.(2005). Automatic voxel-based generation of 3D microstructural FE models and its application to the damage analysis of composites . Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing. 407. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 11-23.
Mishnaevsky Jr., L.L.(2005). Automatic voxel-based generation of 3D microstructural FE models and its application to the damage analysis of composites . Materials Science and Engineering A. 407. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 11-23.
Mishnaevsky, L.L., Gross, D.(2004). Micromechanisms and mechanics of damage and fracture in thin film/substrate systems . Prikladnaya Mekhanika. 40. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 33-51.
Mishnaevsky Jr., L., Weber, U., Schmauder, S.(2004). Numerical analysis of the effect of microstructures of particle-reinforced metallic materials on the crack growth and fracture resistance . International Journal of Fracture. 125. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 33-50.
Baptiste, D., Derrien, K., Gilchrist, M. D., Levesque, M., Mishnaevsky, L.(2004). A micromechanical model for nonlinear viscoelastic particle reinforced polymeric composite materials - undamaged state (vol 35, pg 905, 2004) . Composites Part a-Applied Science and Manufacturing. 35. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1233.
Lévesque, M., Derrien, K., Mishnaevsky Jr., L., Baptiste, D., Gilchrist, M.D.(2004). Erratum: A micromechanical model for the nonlinear viscoelastic particle reinforced polymeric composite materials - Undamaged state (Composites Part A: Applied Science and Manufacturing DOI: 10.1016/j.comositesa.2004.05.003) . Composites Part A: Applied Science and Manufacturing. 35. (10).
Baptiste, D., Derrien, K., Mishnaevsky, L.(2004). Effect of microstructure of particle reinforced composites on the damage evolution: probabilistic and numerical analysis . Composites Science and Technology. 64. (12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1805-1818.
Gross, D., Mishnaevsky, L. L.(2004). Micromechanisms and mechanics of damage and fracture in thin film/substrate systems . International Applied Mechanics. 40. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 140-155.
Mishnaevsky, L.L., Gross Jr., D.(2004). Micromechanisms and mechanics of damage and fracture in thin film/substrate systems . International Applied Mechanics. 40. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 140-155.
Mishnaevsky, L., Schmauder, S., Weber, U.(2004). Numerical analysis of the effect of microstructures of particle-reinforced metallic materials on the crack growth and fracture resistance . International Journal of Fracture. 125. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 33-50.
Mishnaevsky Jr., L., Derrien, K., Baptiste, D.(2004). Effect of microstructure of particle reinforced composites on the damage evolution: Probabilistic and numerical analysis . Composites Science and Technology. 64. (12). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1805-1818.
Mishnaevsky Jr, L. and Weber, U. and Schmauder, S.(2004). Numerical analysis of the effect of microstructures of particle-reinforced metallic materials on the crack growth and fracture resistance . International Journal of Fracture. 125. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 33-50. Springer-Verlag
Mishnaevsky, L. L.(2004). Three-dimensional numerical testing of microstructures of particle reinforced composites . Acta Materialia. 52. (14). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 4177-4188.
Mishnaevsky Jr., L.L.(2004). Three-dimensional numerical testing of microstructures of particle reinforced composites . Acta Materialia. 52. (14). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 4177-4188.
Lippmann, N., Mishnaevsky, L., Schmauder, S.(2003). Computational modeling of crack propagation in real microstructures of steels and virtual testing of artificially designed materials . International Journal of Fracture. 120. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 581-600.
Mishnaevsky Jr., L.L., Lippmann, N., Schmauder, S.(2003). Micromechanisms and modelling of crack initiation and growth in tool steels: Role of primary carbides . Zeitschrift fuer Metallkunde/Materials Research and Advanced Techniques. 94. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 676-681.
Mishnaevsky, L., Lippmann, N., Schmauder, S.(2003). Computational modeling of crack propagation in real microstructures of steels and virtual testing of artificially designed materials . International Journal of Fracture. 120. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 581-600.
Lippmann, N., Mishnaevsky, L. L., Schmauder, S.(2003). Micromechanisms and modelling of crack initiation and growth in tool steels: role of primary carbides. Zeitschrift Fur Metallkunde. 94. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 676-681.
Mishnaevsky Jr., L.L., Schmauder, S.(2001). Continuum mesomechanical finite element modeling in materials development: A state-of-the-art review . Applied Mechanics Reviews. 54. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 49-66.
Mishnaevsky, Leon L. and Schmauder, Siegfried(2001). Continuum Mesomechanical Finite Element Modeling in Materials Development: A State-of-the-Art Review . Applied Mechanics Reviews. 54. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 49. ASME International
Dong, M., Honle, S., Mishnaevsky, L., Schmauder, S.(1999). Computational mesomechanics of particle-reinforced composites . Computational Materials Science. 16. (1-4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 133-143.
Mishnaevsky Jr., L., Dong, M., Hönle, S., Schmauder, S.(1999). Computational mesomechanics of particle-reinforced composites . Computational Materials Science. 16. (1-4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 133-143.
Mishnaevsky Jr., L.L., Lippmann, N., Schmauder, S., Gumbsch, P.(1999). In-situ observation of damage evolution and fracture in AlSi7Mg0.3 cast alloys . Engineering Fracture Mechanics. 63. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 395-411.
Gumbsch, P., Lippmann, N., Mishnaevsky, L. L., Schmauder, S.(1999). In-situ observation of damage evolution and fracture in AlSi7Mg0.3 cast alloys . Engineering Fracture Mechanics. 63. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 395-411.
Mishnaevsky Jr., L.L., Schmauder, S.(1997). Damage evolution and heterogeneity of materials: Model based on fuzzy set theory . Engineering Fracture Mechanics. 57. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 625-636.
Mishnaevsky Jr., L. L. and Schmauder, S.(1997). Damage evolution and localization in heterogeneous materials under dynamical loading: stochastic modelling . Computational Mechanics. 20. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 89-94. Springer-Verlag
Mishnaevsky, L.L.(1997). Methods of the theory of complex systems in modelling of fracture: A brief review . Engineering Fracture Mechanics. 56. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 47-56. Elsevier
Mishnaevsky Jr., L.L.(1997). Methods of the theory of complex systems in modelling of fracture: A brief review . Engineering Fracture Mechanics. 56. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 47-56.
Mishnaevsky, L.L. and Schmauder, S.(1997). Damage evolution and heterogeneity of materials: Model based on fuzzy set theory . Engineering Fracture Mechanics. 57. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 625-636. Elsevier
Mishnaevsky Jr., L.L., Schmauder, S.(1997). Damage evolution and localization in heterogeneous materials under dynamical loading: Stochastic modelling . Computational Mechanics. 20. (1-2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 89-94.
Mishnaevsky, L.L.(1996). A new approach to the design of drilling tools . International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts. 33. (1). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 97-102. Elsevier
Mishnaevsky Jr., L.L.(1996). New approach to the design of drilling tools . International journal of rock mechanics and mining sciences & geomechanics abstracts. 33. (1).
Mishnaevsky Jr., L.L.(1996). Determination for the time-to-fracture of solids . International Journal of Fracture. 79. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 341-350.
Rossmanith, H.P., Knasmillner, R.E., Daehnke, A., Mishnaevsky Jr., L.(1996). Wave propagation, damage evolution, and dynamic fracture extension. Part I. Percussion drilling . Materials Science. 32. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 350-358.
Rossmanith, H.P., Knasmillner, R.E., Daehnke, A., Mishnaevsky Jr., L.(1996). Wave propagation, damage evolution, and dynamic fracture extension. Part II. Blasting . Materials Science. 32. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 403-410.
Mishnaevsky, L.L.(1995). Mathematical modelling of wear of cemented carbide tools in cutting brittle materials . International Journal of Machine Tools and Manufacture. 35. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 717-724. Elsevier
Mishnaevsky Jr., L.L.(1995). Mathematical modelling of wear of cemented carbide tools in cutting brittle materials . International Journal of Machine Tools and Manufacture. 35. (5). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 717-724.
Mishnaevsky, L.L.(1995). Physical mechanisms of hard rock fragmentation under mechanical loading: A review . International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts. 32. (8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 763-766. Elsevier
Mishnaevsky Jr., L.L.(1995). Physical mechanisms of hard rock fragmentation under mechanical loading: A review . International Journal of Rock Mechanics and Mining Sciences and. 32. (8). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 763-766.
Mishnaevsky, L. L.(1994). A NEW APPROACH TO THE DETERMINATION OF THE CRACK VELOCITY VERSUS CRACK LENGTH RELATION . Fatigue & Fracture of Engineering Materials and Structures. 17. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1205-1212. Wiley Blackwell (Blackwell Publishing)
Mishnaevsky Jr., L.L.(1994). A new approach to the analysis of strength of a matrix composite with a high content of hard filler . Applied Composite Materials. 1. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 317-324.
Mishnaevsky, L.L.(1994). Investigation of the cutting of brittle materials . International Journal of Machine Tools and Manufacture. 34. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 499-505. Elsevier
Mishnaevsky Jr., L.L.(1994). Investigation of the cutting of brittle materials . International Journal of Machine Tools and Manufacture. 34. (4). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 499-505.
Mishnaevsky Jr., L.L.(1994). New approach to the determination of the crack velocity versus crack length relation . Fatigue and Fracture of Engineering Materials and Structures. 17. (10). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1205-1212.
Mishnaevsky Jr., L.L.(1993). A brief review of Soviet theoretical approaches to dynamic rock failure . International Journal of Rock Mechanics and Mining Sciences and. 30. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 663-668.
CONFERENCE PAPER
Nikesh Kuthe, Leon Mishnaevsky Jr., Puneet Mahajan, Suhail Ahmad(2024). Potential of Development of Anti-Erosion Graphene-Reinforced Coatings for Wind Turbine Blades . Dynamic Behavior of Soft and Hard Materials. 3. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 109--114. Springer
Numerical Investigation of the Effect of Pre-Existing Surface Craters on Failure of Leading Edge Protection Coatings for Wind Turbine Blades @inproceedings{6e76fa1afc2d4069af7c55641bc29a42, title = "Numerical Investigation of the Effect of Pre-Existing Surface Craters on Failure of Leading Edge Protection Coatings for Wind Turbine Blades", abstract = "This study investigates how pre-existing surface craters of leading edge protection coating used against rain erosion of wind turbine blades affect the maximum strains during impacts of rain droplets. Surface craters in the form of pinholes can form during the coating application process. The investigation is carried out by using finite element models of droplet impacts on surfaces with craters, where the impact velocity, droplet size, and crater position and size are varied. The simulations predict that the maximum strain is located at the crater walls and increases as the impact velocity and droplet size increase, and that craters closer to the central impact axis experience larger strains than craters placed farther away. The size of the crater was not predicted to have an influence on strains. The position of the maximum strain value was at the crater walls for all cases, and it was larger than for an impact on a flat surface. Observations from rain erosion tests suggest that some fractures initiate from pre-existing craters which act as weak points of otherwise highly resistant coatings.", keywords = "Leading edge erosion, Wind energy, Coatings, Finite elements, Roughness", author = "Antonios Tempelis and Jr., {Leon Mishnaevsky} and Jespersen, {Kristine Munk}", year = "2024", doi = "10.60691/yj56-np80", language = "English", volume = "3", pages = "85--92", editor = "Christophe Binetruy and Jacquemin, {Fr{\'e}d{\'e}ric }", booktitle = "Proceedings of ECCM21 – 21st European Conference on Composite Materials", publisher = "European Society for Composite Materials", note = "21<sup>st</sup> European Conference on Composite Materials, ECCM21 ; Conference date: 02-07-2024 Through 05-07-2024", } . Proceedings of ECCM21 – 21st European Conference on Composite Materials.
Kristine Munk Jespersen, Leon Mishnaevsky Jr.(2023). Composite coatings with embedded fibers and particiles for multiple impact protection . 23rd International Conference on Composite Materials, Belfast, Ireland, 30/07/2023.
Leon Mishnaevsky Jr., N. Kuthe, Antonios Tempelis, P. Mahajan(2023). Complex damage mechanisms and roughness evolution of wind turbine blade surface: Multiphysics and stochastic effect modelling . 43rd Risoe International Symposium on Materials Science. 1293. IOP Publishing
Nikesh Kuthe, V. B. Pandey, Suhail Ahmad, Puneet Mahajan, Leon Mishnaevsky Jr.(2023). Investigating Damage Initiation in Wind Turbine Blade Coating Under Repeated Raindrop Impacts . International Conference on Offshore Mechanics and Arctic Engineering: Conference Proceedings. 8. The American Society of Mechanical Engineers (ASME)
Leon Mishnaevsky Jr., Brian Bendixen, Puneet Mahajan, S&#248;ren F&#230;ster, Nicolai Frost-Jensen Johansen, Daniel Paul, Anthony Fraisse(2022). Repair of Wind Turbine Blades: Costs and Quality . Turbine Technology; Artificial Intelligence, Control and Monitoring. (3). IOP Publishing
Alexandros Antoniou, Kirsten Dyer, William Finnegan, Robbie Herring, Bodil Holst, Jakob Ilsted Bech, Ioannis Katsivalis, Tazefidan Kutlualp, Leon Mishnaevsky Jr., Asta Šakalyte, et al.(2022). Multilayer leading edge protection systems of wind turbine blades . ECCM 2022 - Proceedings of the 20th European Conference on Composite Materials: Composites Meet Sustainability. 5. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 97--104. {\'E}cole Polytechnique F{\'e}d{\'e}rale de Lausanne
Leon Mishnaevsky Jr.(2014). Hierarchical nanoreinforced composites for highly reliable large wind turbines: Computational modelling and optimization . Abstract Book - DTU Sustain Conference 2014. Technical University of Denmark
Mishnaevsky Jr., L.(2012). Computational testing and design of materials for wind energy and structural applications . Proceedings of the IASTED International Conference on Engineering and Applied Science, EAS 2012. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1-5.
Leon Mishnaevsky Jr.(2012). Computational testing and design of materials for wind energy and structural applications . Proceedings of the IASTED International Conference on Engineering and Applied Science, EAS 2012. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1--5. Acta Press
Hai Qing, Leon Mishnaevsky Jr.(2010). 3D computational hierarchical model of wood: From microfibrils to annual rings . Proceedings. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 168--ECCM14. European Society for Composite Materials
Leon Mishnaevsky Jr., Dietmar Gross(2008). Computational Micromechanics of Damage Initiation and Growth in Functionally Graded Composites . MULTISCALE AND FUNCTIONALLY GRADED MATERIALS. 973/1. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 216--221. American Institute of Physics
Leon Mishnaevsky Jr., Povl Br&#248;ndsted(2008). Fiber bridging in GFRP composites: Mesomechanical analysis . Proceedings (on USB-stick). Swedish Institute of Composites; Royal Institute of Technology
Mishnaevsky Jr., L., Gross, D.(2008). Computational micromechanics of damage initiation and growth in functionally graded composites . AIP Conference Proceedings. 973. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 216-221.
Leon Mishnaevsky Jr., Povl Br&#248;ndsted(2007). Software for automatic generation of 3D microstructural models of fiber reinforced composites with damageable elements . Interface design of polymer matrix composites - mechanics, chemistry, modelling and manufacturing. Proceedings. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 241--248. Ris{\o} National Laboratory
Haldrup, K., Nielsen, S.F., Mishnaevsky Jr., L., Beckmann, F., Wert, J.A.(2006). 3-Dimensional strain fields from tomographic measurements . Progress in Biomedical Optics and Imaging - Proceedings of SPIE. 6318.
Kristoffer Haldrup, S&#248;ren F&#230;ster, Leon Mishnaevsky Jr., F. Beckmann, J. A. Wert(2006). 3-Dimensional strain fields from tomographic measurements . Developments in X-Ray Tomography V. 6318. SPIE - International Society for Optical Engineering
Mishnaevsky Jr., L.(2005). 3D computational testing of microstructures of particle reinforced metal matrix composites . 11th International Conference on Fracture 2005, ICF11. 2. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1175-1179.
Mishnaevsky Jr., L., Weber, U., Lippmann, N., Schmauder, S.(2001). Computational experiment in the mechanics of materials . Proceedings of the Conference on Computational Modeling of Materials, Minerals and Metals Processing. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 673-680.
Mishnaevsky, L.L.Jr.(1999). Optimization of shape of drilling tools . 20th Century Lessons, 21st Century Challenges. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1225-1228.
Mishnaevsky, L.L., Schmauder, S.(1997). Strength of particulate composites with a high content of high-melting point filler . Proceedings of the Engineering Foundation Conference. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 311-318.
Rossmanith, H.P., Mishnaevsky Jr., L., Knasmillner, R.E., Uenishi, K.(1996). Numerical simulation of dynamic fracture and damage of rock during impact . Proceedings of the International Congress on Numerical Methods in Engineering and Applied Sciences, CIMENICS. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 147-154.
BOOK CHAPTER
Vijendra Kumar Mohonee, Kheng Lim Goh, Leon Mishnaevsky Jr., Sheik Ambarine Banon Auckloo, Pooria Pasbakhsh(2023). Mechanical properties and modeling of polyurea capsule-based self-healing composites . Polyurea. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 203--219. Elsevier
Leon Mishnaevsky Jr.(2023). Micromechanical modeling of wind blade materials . Advances in Wind Turbine Blade Design and Materials. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 191--214. Elsevier
Leon Mishnaevsky Jr.(2023). Maintenance and repair of wind turbine blades . Advances in Wind Turbine Blade Design and Materials. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 475--484. Elsevier
Leon Mishnaevsky Jr.(2019). Structured interfaces and their effect on composite performance . Interfaces in Paricle and Fibre Reinforced Composites: From Macro to Nano Scales. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 9--28. Elsevier
Leon Mishnaevsky Jr.(2019). Micromechanics of Hierarchical Materials: Modeling and Perspectives . Handbook of Mechanics of Materials. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1293--1310. Springer
Leon Mishnaevsky Jr.(2013). Micromechanical modelling of wind turbine blade materials . Advances in wind turbine blade design and materials. (47). Woodhead Publishing
Gross, D., Mishnaevsky, L.(2008). Computational micromechanies of damage initiation and growth in functionally graded composites. Multiscale and Functionally Graded Materials. 973. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 216-221.
Beckmann, F., Haldrup, K., Mishnaevsky, L., Nielsen, S. F., Wert, J. A.(2006). 3-dimensional strain fields from tomographic measurements - art. no. 63181B . Developments in X-Ray Tomography V. 6318. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString B3181.
Mishnaevsky, L.(2006). Computational analysis of the effects of microstructures on damage and fracture in heterogeneous materials - Advanced numerical tools and virtual testing of microstructures. Fracture and Strength of Solids Vi, Pts 1 and 2. 306-308. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 489-494.
ONLINE RESOURCE
Justine Beauson, Lars Pilgaard Mikkelsen, Asger Bech Abrahamsen, Leon Mishnaevsky Jr.(2022). Genavendelse af vindmøllevinger kræver en holistisk tilgang . Ingeni{\o}ren
OTHER
Leon Mishnaevsky Jr., Shreyas Srivatsa, Pawel Packo, Tadeusz Uhl, Krzysztof Grabowski(2021). Micromechanical Modeling of Nacre-mimetic Ti<sub>3</sub>C<sub>2</sub>-MXene Nanocomposites with Viscoelastic Polymer Matrix . {MDPI} {AG}
Leon Mishnaevsky Jr., Shreyas Srivatsa, Paweł Paćko, Tadeusz Uhl, Krzysztof Grabowski(2020). Deformation of Bioinspired MXene Based Polymer Composites with Brick and Mortar Structures: Computational Analysis . {MDPI} {AG}
Leon Mishnaevsky Jr., Michael Tsapatsis(2016). Hierarchical materials: Background and perspectives . M R S Bulletin. 41. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 661--664. Cambridge University Press
Leon Mishnaevsky Jr., Evgeny Levashov(2013). Editorial: Selected Publications of the EU FP7 project VIRTUAL NANOTITANIUM . Computational Materials Science. 76. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1--2. Elsevier
Leon Mishnaevsky Jr., D. Wood(2010). Editorial . Wind Engineering. 34. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString i--iv. SAGE Publications
Leon Mishnaevsky Jr., David Wood(2009). Editorial: Wind Engineering, vol. 33, no. 2, 2009 . Wind Engineering. 33. (2). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString i--ii. SAGE Publications
REPORT
Charlotte Bay Hasager, Leon Mishnaevsky Jr., Christian Bak, Jakob Ilsted Bech, S&#248;ren F&#230;ster, Nicolai Frost-Jensen Johansen(2021). How can we combat leading-edge erosion on wind turbine blades? . DTU International Energy Report 2021: Perspectives on Wind Energy. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 134--142. DTU Wind Energy
Karin Jensen, Charlotte Bay Hasager, Leon Mishnaevsky Jr.(2020). DTU tackles leading edge erosion of wind turbine blades . Energy Insight Yearbook. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 50--52. NEM Media
Anthony Fraisse, Jakob Ilsted Bech, Kaj Kvisgaard Borum, Vladimir Fedorov, Nicolai Frost-Jensen Johansen, Malcolm McGugan, Leon Mishnaevsky Jr., Yukihiro Kusano(2018). Development of Single Point Impact Fatigue Tester (SPIFT) . DTU Wind Energy I. (751). DTU Wind Energy
Effect of the coating properties on the deformation and wave distribution in the leading edge erosion system @book{95142b326e6747639c6ea6aba473faf0, title = "Effect of the coating properties on the deformation and wave distribution in the leading edge erosion system", abstract = "The model is an expanded and modified version of the model by V. Fedorov, see for instance [1]. The material under droplet was designed as multilayered materials, with two layer protective coating, gelcoat, and filler, all on the top oflaminate. The model is designed in such a way that it can be easily expanded to simulate the interlayer debonding, coating/gelcoat, gelcoat/filler, and filler/laminate debonding. It is realized by creating “interphase/interface” layers between the coatings, following the concept of 3D interfaces by Povl Br{\o}ndstedt and Leon Mishnaevsky Jr [2]. In this way, the model can be used for optimization of protective coatings and their structures, testing various parameters of the protective systems and development of recommendations to their improvement. In order to demonstrate the application of the model for the analysis, we used the model to study various coating structures, and compare two extreme cases, namely, stiff upper coating/soft lower coating and, inversely, soft upper coating/stiff lower coating placed on homogeneous gelcoat, filler and laminate. The properties of gelcoat, filler and laminate remained the same in all cases, however, the stiff and soft phases have had drastically changed properties. The developed computational model allows numerical testing of various protective systems. The models is expandable and allows also to add specific damage mechanisms, as well as more complex (plastic, viscous, damping) behavior of protective layers. Further, more detailed models of filler and gelcoat should be added. Varying the stiffness and amount of protective layers, one can control the damage initiation and growth if composites", author = "Leon Mishnaevsky and Bech, {Jakob Ilsted} and Yukihiro Kusano", year = "2018", language = "English", series = "DTU Wind Energy I", number = "762", } . DTU Wind Energy I.
Leon Mishnaevsky Jr., Povl Br&#248;ndsted(2008). Micromechanical modelling of unidirectional long fiber reinforced composites . Denmark. Forskningscenter Risoe. Risoe-R. (1672(EN)). Danmarks Tekniske Universitet, Ris{\o} Nationallaboratoriet for B{\ae}redygtig Energi
Leon Mishnaevsky Jr., P. Br&#248;ndsted(2007). Micromechanical modeling of strength and damage of fiber reinforced composites . Denmark. Forskningscenter Risoe. Risoe-R. (1601(EN)). Ris{\o} National Laboratory
CONFERENCE POSTER
Charlotte Bay Hasager, Leon Mishnaevsky Jr., Christian Bak(2019). Leading edge erosion the state of the art research results . WindEurope Offshore 2019, Copenhagen, Denmark, 26/11/2019.
CONFERENCE ABSTRACT
Lars Pilgaard Mikkelsen, Leon Mishnaevsky Jr.(2013). Implementing Advanced Materials Models in a Commercial Finite Element Code . NAFEMS NORDIC Seminar 2013, Lund, Sweden, 05/11/2013.
A. Trondl, D. Gross, Leon Mishnaevsky Jr., N. Huber(2006). 3D simulations of nanoindentation and size effects in deformation of thin metallic films . 16th International Workshop on Computational Mechanics of Materials, Lublin, Poland, 25/09/2006.
Leon Mishnaevsky Jr., D. Gross(2006). Computational micromechanics of functionally gradient composites . Multiscale and functionally graded materials conference 2006, Honolulu, United States, 15/10/2006.
BOOK
Mishnaevsky, L.(2013). Micromechanical modelling of wind turbine blade materials . Advances in Wind Turbine Blade Design and Materials. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 298-324.
S. Schmauder, Leon Mishnaevsky Jr.(2008). Micromechanics and nanosimulation of metals and composites . Springer
Schmauder, Siegfried and Mishnaevsky, Leon(2008). Micromechanical Simulation of Composites . 37-126Springer-Verlag
Schmauder, Siegfried and Mishnaevsky, Leon(2008). Complex, Graded and Interpenetrating Microstructures . 213-310Springer-Verlag
Schmauder, Siegfried and Mishnaevsky, Leon(2008). Micromechanical Experiments . 1-36Springer-Verlag
Schmauder, Siegfried and Mishnaevsky, Leon(2008). Simulation of Damage and Fracture . 127-212Springer-Verlag
Schmauder, S., Mishnaevsky Jr., L.(2008). Micromechanics and nanosimulation of metals and composites: Advanced methods and theoretical concepts . Micromechanics and Nanosimulation of Metals and Composites: Advanced Methods and Theoretical Concepts. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1-420.
Schmauder, Siegfried and Mishnaevsky, Leon(2008). Atomistic and Dislocation Modelling . 311-418Springer-Verlag
Mishnaevsky, L.(2007). Computational Mesomechanics of Composites: Numerical analysis of the effect of microstructures of composites on their strength and damage resistance . Computational Mesomechanics of Composites: Numerical analysis of the effect of microstructures of composites on their strength and damage resistance. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1-276.
Mishnaevsky Jr., L.(2006). Computational analysis of the effects of microstructures on damage and fracture in heterogeneous materials: Advanced numerical tools and virtual testing of microstructures . Key Engineering Materials. 306-308 I. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 489-494.
Mishnaevsky, Leon(2004). Computational Mesomechanics of Materials . 123-128Springer-Verlag
Mishnaevsky, L. L.(2001). Numerical simulation of damage and fracture in heterogeneous rocks. Rock Mechanics in the National Interest, Vols 1 and 2. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 313-316.
Lippmann, N., Mishnaevsky, L., Schmauder, S., Weber, U.(2001). Computational experiment in the mechanics of materials. Computational Modeling of Materials, Minerals and Metals Processing. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 673-680.
Mishnaevsky, L. L.(1999). Optimization of shape of drilling tools. Ninth International Congress on Rock Mechanics, Vols 1 & 2. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1225-1228.
Mintchev, O., Mishnaevsky, L., Schmauder, S.(1998). Fe-simulation of crack growth using damage parameter and cohesive surface concept. Ecf 12: Fracture from Defects, Vols. I-Iii. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 1053-1058.
Mishnaevsky, L. L. and Schmauder, S.(1998). Informational Methods in Optimization of Tools . 499-510Springer-Verlag
Mishnaevsky, L.L.(1996). Percolation Model of Fatigue Fracture and Lifetime Prediction . 1287-1291Elsevier