On adiabatic shear instability in impacts of micron-scale Al-6061 particles with sapphire and Al-6061 substrates
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[1] D. Casem,et al. Miniature Beryllium Split-Hopkinson Pressure Bars for Extending the Range of Achievable Strain-Rates , 2022, Metals.
[2] G. Rousselier. Lode-dependent second porosity in porous plasticity for shear-dominated loadings , 2022, International Journal of Plasticity.
[3] Yaowu Hu,et al. Ultrahigh strain rate-activated superplastic forming of aluminum and gold nanometals , 2022, Materials & Design.
[4] J. Rodríguez-Martínez,et al. Shear band formation in porous thin-walled tubes subjected to dynamic torsion , 2022, International Journal of Solids and Structures.
[5] C. C. Aydiner,et al. Advance of Collaborative Twinning Fields in Magnesium AZ31 via the Strain and Residual Intensity Channels in Microscopic Image Correlation , 2021, Challenges in Mechanics of Time Dependent Materials, Mechanics of Biological Systems and Materials & Micro-and Nanomechanics, Volume 2.
[6] Yunzhi Wang,et al. Medium-range ordering, structural heterogeneity, and their influence on properties of Zr-Cu-Co-Al metallic glasses , 2021, Physical Review Materials.
[7] S. Satapathy,et al. Density, Microstructure, and Strain-Rate Effects on the Compressive Response of Polyurethane Foams , 2021, Experimental Mechanics.
[8] J. Rodríguez-Martínez,et al. New insights into the role of porous microstructure on dynamic shear localization , 2021, International Journal of Plasticity.
[9] J. Shao,et al. A novel micromechanics-enhanced phase-field model for frictional damage and fracture of quasi-brittle geomaterials , 2021 .
[10] Kailun Zheng,et al. A physical-based unified constitutive model of AA7075 for a novel hot forming condition with pre-cooling , 2021 .
[11] N. Thadhani,et al. Microstructure Quantification and Multiresolution Mechanical Characterization of Ti-Based Bulk Metallic Glass-Matrix Composites , 2021, JOM.
[12] C. Meredith,et al. Quasi-static and dynamic investigation of an advanced high strength and corrosion resistant 10 % Cr nanocomposite martensitic steel. , 2021, International journal of mechanical sciences.
[13] J. Rodríguez-Martínez,et al. Influence on strain-rate history effects on the development of necking instabilities under dynamic loading conditions , 2021 .
[14] A. Vaz-Romero,et al. Finite element analysis to determine the role of porosity in dynamic localization and fragmentation: Application to porous microstructures obtained from additively manufactured materials , 2021, International Journal of Plasticity.
[15] C. Meredith. Dynamic thermomechanical behavior of fine-grained Mg alloy AMX602 , 2021 .
[16] H. Waisman,et al. A mixed finite element formulation for ductile damage modeling of thermoviscoplastic metals accounting for void shearing , 2021, Computational Mechanics.
[17] S. Pauly,et al. Structural evolution of a CuZr-based bulk metallic glass composite during cryogenic treatment observed by in-situ high-energy X-ray diffraction , 2021 .
[18] C. Berndt,et al. Numerical modelling of particle impact and residual stresses in cold sprayed coatings: A review , 2021, Surface and Coatings Technology.
[19] H. Waisman,et al. Anisotropic thermal-conductivity degradation in the phase-field method accounting for crack directionality , 2021 .
[20] Yunzhuo Lu,et al. Controllable additive manufacturing of gradient bulk metallic glass composite with high strength and tensile ductility , 2021 .
[21] K. Inal,et al. Evolution of subsequent yield surfaces with plastic deformation along proportional and non-proportional loading paths on annealed AA6061 alloy: Experiments and crystal plasticity finite element modeling , 2021 .
[22] M. Zhan,et al. Flow stress correction for hot compression of titanium alloys considering temperature gradient induced heterogeneous deformation , 2021 .
[23] H. Waisman,et al. A thermodynamic framework to predict ductile damage in thermoviscoplastic porous metals , 2021 .
[24] J. Rodríguez-Martínez,et al. The combined effect of size, inertia and porosity on the indentation response of ductile materials , 2020, Mechanics of Materials.
[25] J. Rodríguez-Martínez,et al. A three-pronged approach to predict the effect of plastic orthotropy on the formability of thin sheets subjected to dynamic biaxial stretching , 2020, Journal of the Mechanics and Physics of Solids.
[26] M. Meyers,et al. Shear localization in metallic materials at high strain rates , 2020 .
[27] J. Yang,et al. Residual Intensity as a Morphological Identifier of Twinning Fields in Microscopic Image Correlation , 2020, Experimental Mechanics.
[28] Jun Song,et al. A modified Johnson-Cook material model with strain gradient plasticity consideration for numerical simulation of cold spray process , 2020 .
[29] M. Zhan,et al. Grain refinement in hot working of 2219 aluminium alloy: On the effect of deformation mode and loading path , 2020 .
[30] T. Gnäupel-Herold,et al. Quasi-static and dynamic response, and texture evolution of two overaged Al 7056 alloy plates in T761 and T721 tempers: Experiments and modeling. , 2020, International journal of plasticity.
[31] Jun Ma,et al. The mechanical performance and a rate-dependent constitutive model for Al3Ti compound , 2020, Defence Technology.
[32] N. Shafaghi,et al. Cyclic Strain Heterogeneity and Damage Formation in Rolled Magnesium Via In Situ Microscopic Image Correlation , 2020, Experimental Mechanics.
[33] H. Waisman,et al. Thermal-conductivity degradation across cracks in coupled thermo-mechanical systems modeled by the phase-field fracture method , 2020 .
[34] Xianfeng Zhang,et al. “Self-sharpening” tungsten high-entropy alloy , 2020 .
[35] P. Hu,et al. Investigation on mechanical behavior and plastic damage of AA7075 aluminum alloy by thermal small punch test: Experimental trials, numerical analysis , 2020 .
[36] J. Lloyd,et al. Fracture of an anisotropic rare-earth-containing magnesium alloy (ZEK100) at different stress states and strain rates: Experiments and modeling , 2019, International Journal of Plasticity.
[37] P. Hu,et al. On the thermal forming limit diagram (TFLD) with GTN mesoscopic damage model for AA7075 aluminum alloy: Numerical and experimental investigation , 2019, Journal of Alloys and Compounds.
[38] Z. Ning,et al. In situ study of the shear band features of a CuZr-based bulk metallic glass composite , 2019, Intermetallics.
[39] H. Fan,et al. Enhanced tensile plasticity of a CuZr-based bulk metallic glass composite induced by ion irradiation , 2019, Journal of Materials Science & Technology.
[40] X. Xue,et al. Serration and shear avalanches in a ZrCu based bulk metallic glass composite in different loading methods , 2019, Journal of Materials Science & Technology.
[41] M. Zhan,et al. Grain morphology related microstructural developments in bulk deformation of 2219 aluminum alloy sheet at elevated temperature , 2019, Materials Science and Engineering: A.
[42] O. Türkoğlu,et al. In situ investigation of strain heterogeneity and microstructural shear bands in rolled Magnesium AZ31 , 2019, International Journal of Plasticity.
[43] T. Edwards,et al. Slip bands in lamellar TiAl during high cycle fatigue microcompression by correlative total strain mapping, diffraction orientation mapping and transmission electron imaging , 2019, International Journal of Fatigue.
[44] T. Edwards,et al. An experimental study of the polycrystalline plasticity of lamellar titanium aluminide , 2019, International Journal of Plasticity.
[45] P. Hu,et al. Thermal forming limit diagram (TFLD) of AA7075 aluminum alloy based on a modified continuum damage model: Experimental and theoretical investigations , 2019, International Journal of Mechanical Sciences.
[46] S. Müftü,et al. Microstructural Characterization of Aluminum 6061 Splats Cold Spray Deposited on Aluminum 6061-T6 Substrate , 2019, Metallurgical and Materials Transactions A.
[47] M. Pham,et al. Crystal plasticity analysis of deformation anisotropy of lamellar TiAl alloy: 3D microstructure-based modelling and in-situ micro-compression , 2019, International Journal of Plasticity.
[48] H. Assadi,et al. Comment on ‘Adiabatic shear instability is not necessary for adhesion in cold spray’ , 2019, Scripta Materialia.
[49] Jared M. Johnson,et al. Direct determination of structural heterogeneity in metallic glasses using four-dimensional scanning transmission electron microscopy. , 2018, Ultramicroscopy.
[50] G. Ye,et al. Thermal gradient and its contribution to size effect of specific cutting energy , 2018, The International Journal of Advanced Manufacturing Technology.
[51] K. Nelson,et al. Response to Comment on “Adiabatic shear instability is not necessary for adhesion in cold spray” , 2018, Scripta Materialia.
[52] Jing Wu,et al. Laser additive manufacturing of structural-graded bulk metallic glass , 2018, Journal of Alloys and Compounds.
[53] S. Satapathy,et al. High Rate Compressive Behaviour of a Dilatant Polymeric Foam , 2018, Journal of Dynamic Behavior of Materials.
[54] M. Zhan,et al. Achieving fine-grained equiaxed alpha via thermo-mechanical loading under off-equilibrium state in two-phase Ti-alloys , 2018, Journal of Materials Processing Technology.
[55] H. Waisman,et al. Explicit and implicit methods for shear band modeling at high strain rates , 2018, Computational Mechanics.
[56] S. Müftü,et al. Effects of Interface Bonding on the Residual Stresses in Cold-Sprayed Al-6061: A Numerical Investigation , 2018, Journal of Thermal Spray Technology.
[57] Jae-Hwang Lee,et al. High-Strain-Rate Material Behavior and Adiabatic Material Instability in Impact of Micron-Scale Al-6061 Particles , 2018, Journal of Thermal Spray Technology.
[58] Peng Xue,et al. A CuZr-based bulk metallic glass composite with excellent mechanical properties by optimizing microstructure , 2018 .
[59] J. Rodríguez-Martínez,et al. Random distributions of initial porosity trigger regular necking patterns at high strain rates , 2018, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.
[60] J. Ihlemann,et al. Strain Localization during Equal-Channel Angular Pressing analyzed by Finite Element Simulations , 2018 .
[61] T. Edwards,et al. The interaction of borides and longitudinal twinning in polycrystalline TiAl alloys , 2017 .
[62] A. Molinari,et al. Multiple necking pattern in nonlinear elastic bars subjected to dynamic stretching: The role of defects and inertia , 2017 .
[63] Z. Ning,et al. Bending behavior of as-cast and annealed ZrCuNiAl bulk metallic glass , 2017 .
[64] H. Waisman,et al. Combined stability analysis of phase-field dynamic fracture and shear band localization , 2017 .
[65] S. Müftü,et al. Rebound mechanics of micrometre-scale, spherical particles in high-velocity impacts , 2017, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.
[66] Yang Wang,et al. Size effects on the mechanical properties of nanocrystalline NbMoTaW refractory high entropy alloy thin films , 2017 .
[67] T. Gnäupel-Herold,et al. Anisotropy, tension-compression asymmetry and texture evolution of a rare-earth-containing magnesium alloy sheet, ZEK100, at different strain rates and temperatures: Experiments and modeling , 2017 .
[68] Yunzhi Wang,et al. Influence of nanoscale structural heterogeneity on shear banding in metallic glasses , 2017 .
[69] Jae-Hwang Lee,et al. Dynamics and extreme plasticity of metallic microparticles in supersonic collisions , 2017, Scientific Reports.
[70] M. Zhan,et al. Deformation behavior and microstructure evolution during hot working of a coarse-grained Ti-5Al-5Mo-5V-3Cr-1Zr titanium alloy in beta phase field , 2017 .
[71] H. Waisman,et al. An overlapping Domain Decomposition preconditioning method for monolithic solution of shear bands , 2017 .
[72] S. Forest,et al. Interaction of the Portevin–Le Chatelier phenomenon with ductile fracture of a thin aluminum CT specimen: experiments and simulations , 2017, International Journal of Fracture.
[73] A. Molinari,et al. The critical neck spacing in ductile plates subjected to dynamic biaxial loading: On the interplay between loading path and inertia effects , 2017 .
[74] N. Shafaghi,et al. Texture-dependent character of strain heterogeneity in Magnesium AZ31 under reversed loading , 2017 .
[75] R. Othman,et al. Modeling of the Strain Rate Dependency of Polycarbonate’s Yield Stress: Evaluation of Four Constitutive Equations , 2016 .
[76] R. Othman. A Modified Eyring Equation for Modeling Yield and Flow Stresses of Metals at Strain Rates Ranging from 10−5 to 5 × 104 s−1 , 2015 .
[77] R. Othman,et al. Characterization and modeling of the strain rate sensitivity of polyetheretherketone’s compressive yield stress , 2015 .
[78] E. Thomas,et al. Dynamic mechanical behavior of multilayer graphene via supersonic projectile penetration , 2014, Science.
[79] Sang Heon Lee,et al. Integration of a new data acquisition/processing scheme in SHPB test and characterization of the dynamic material properties of high-strength steels using the optional form of Johnson-Cook model , 2014 .
[80] P. Cleary,et al. Temperature and strain rate effects in cold spray investigated by smoothed particle hydrodynamics , 2014 .
[81] M. Guagliano,et al. Cold spray coating: review of material systems and future perspectives , 2014 .
[82] H. Singh,et al. Cold spray coating process for corrosion protection: a review , 2014 .
[83] A. Pandey,et al. Negative to positive strain rate sensitivity in 5xxx series aluminum alloys: Experiment and constitutive modeling , 2014 .
[84] Marco Giglio,et al. An experimental–numerical investigation on aluminium tubes subjected to ballistic impact with soft core 7.62 ball projectiles , 2013 .
[85] S. A. Alavian,et al. On Simulation of Multi-Particle Impact Interactions in the Cold Spray Process , 2012 .
[86] Liangchi Zhang,et al. Constitutive modelling of plasticity of fcc metals under extremely high strain rates , 2012 .
[87] S. Thibaud,et al. 3D FEM simulations of shoulder milling operations on a 304L stainless steel , 2012, Simul. Model. Pract. Theory.
[88] K. Nelson,et al. High strain rate deformation of layered nanocomposites , 2012, Nature Communications.
[89] K. Xia,et al. A dynamic punch method to quantify the dynamic shear strength of brittle solids. , 2011, The Review of scientific instruments.
[90] S. Müftü,et al. Modeling of high velocity impact of spherical particles , 2011 .
[91] Thomas Klassen,et al. From Particle Acceleration to Impact and Bonding in Cold Spraying , 2009 .
[92] D. Umbrello,et al. The influence of Johnson–Cook material constants on finite element simulation of machining of AISI 316L steel , 2007 .
[93] F. Gärtner. Advances in cold spraying , 2006 .
[94] Martin Rein,et al. Cold spray deposition: Significance of particle impact phenomena , 2005 .
[95] V. Champagne,et al. Interface material mixing formed by the deposition of copper on aluminum by means of the cold spray process , 2005 .
[96] George Z. Voyiadjis,et al. Microstructural based models for bcc and fcc metals with temperature and strain rate dependency , 2005 .
[97] M. Munro. Evaluated Material Properties for a Sintered alpha‐Alumina , 2005 .
[98] M. Grujicic,et al. Adiabatic shear instability based mechanism for particles/substrate bonding in the cold-gas dynamic-spray process , 2004 .
[99] Mica Grujicic,et al. Computational analysis of the interfacial bonding between feed-powder particles and the substrate in the cold-gas dynamic-spray process , 2003 .
[100] Hamid Assadi,et al. Bonding mechanism in cold gas spraying , 2003 .
[101] Cold Spray Technology: From R & D To Commercial Applications , 2003 .
[102] J. Intrater. Cold spray technology – prospects and applications , 2002 .
[103] 이창희,et al. Cold Spray 기술 , 2002 .
[104] J. H. Dautzenberg,et al. Material behaviour in conditions similar to metal cutting : flow stress in the primary shear zone , 2002 .
[105] G. Ravichandran,et al. A shear-compression specimen for large strain testing , 2002 .
[106] Qingming Li,et al. Strain energy density failure criterion , 2001 .
[107] D R Lesuer,et al. Modeling Large-Strain, High-Rate Deformation in Metals , 2001 .
[108] James R. Fekete,et al. Effect of strain rate in full vehicle frontal crash analysis , 2000 .
[109] J. Mason,et al. Adiabatic shear localization in the dynamic punch test, part II: numerical simulations , 1999 .
[110] Daniel W. Gorkiewicz,et al. Kinetic spray coatings , 1999 .
[111] R. Armstrong,et al. Dislocation mechanics aspects of plastic instability and shear banding , 1994 .
[112] Yi-long Bai. Thermo-plastic instability in simple shear , 1982 .
[113] Z. Marciniak,et al. Limit strains in the processes of stretch-forming sheet metal , 1967 .
[114] F. Hauser,et al. Techniques for measuring stress-strain relations at high strain rates , 1966 .
[115] R. Recht. Catastrophic Thermoplastic Shear , 1964 .
[116] J. D. Campbell,et al. Tensile Testing of Materials at Impact Rates of Strain , 1960 .
[117] H. Kolsky. An Investigation of the Mechanical Properties of Materials at very High Rates of Loading , 1949 .
[118] T. Edwards,et al. High resolution digital image correlation mapping of strain localization upon room and high temperature, high cycle fatigue of a TiAl intermetallic alloy , 2021 .
[119] P. Hu,et al. Towards joinability of thermal self-piercing riveting for AA7075-T6 aluminum alloy sheets under quasi-static loading conditions , 2021 .
[120] G. Rousselier. Porous plasticity revisited: Macroscopic and multiscale modeling , 2021 .
[121] M. Aindow,et al. Mesoscale modeling of jet initiation behavior and microstructural evolution during cold spray single particle impact , 2020 .
[122] M. Zhan,et al. Eddy current induced dynamic deformation behaviors of aluminum alloy during EMF: Modeling and quantitative characterization , 2019, Journal of Materials Processing Technology.
[123] G. R. Johnson,et al. A CONSTITUTIVE MODEL AND DATA FOR METALS SUBJECTED TO LARGE STRAINS, HIGH STRAIN RATES AND HIGH TEMPERATURES , 2018 .
[124] W. Ma,et al. On the instability of chip flow in high-speed machining , 2018 .
[125] G. Ye,et al. Onset and evolution of discontinuously segmented chip flow in ultra-high-speed cutting Ti-6Al-4V , 2017 .
[126] A. Moridi. Modeling Cold Spray , 2017 .
[127] M. Zhan,et al. A modified Johnson-Cook model of as-quenched AA2219 considering negative to positive strain rate sensitivities over a wide temperature range , 2017 .
[128] S. Müftü,et al. A Numerical Investigation Into Cold Spray Bonding Processes , 2015 .
[129] Marco Giglio,et al. Analysis of strain rate behavior of an Al 6061 T6 alloy , 2011 .
[130] S. Müftü,et al. On Cohesion of Micron Scale Metal Particles in High Velocity Impact With a Metal Substrate , 2011 .
[131] Jian Zhao. An overview of some recent progress in rock dynamics research , 2011 .
[132] Wang Lu. Numerical Simulation on the Penetrations of Long-rod Projectiles with Different Nose Shapes , 2007 .
[133] J. Villafuerte. Cold spray: A new technology , 2005 .
[134] Dean L. Preston,et al. Model of plastic deformation for extreme loading conditions , 2003 .
[135] H. Huh,et al. Crash-worthiness assessment of thin-walled structures with the high-strength steel sheet , 2002 .
[136] Akhtar S. Khan,et al. Behaviors of three BCC metals during non-proportional multi-axial loadings: experiments and modeling , 2000 .
[137] Akhtar S. Khan,et al. Behaviors of three BCC metal over a wide range of strain rates and temperatures: experiments and modeling , 1999 .
[138] A. Needleman. An analysis of tensile decohesion along an interface , 1990 .
[139] R. Batra,et al. The initiation and growth of adiabatic shear bands , 1985 .
[140] G. R. Johnson,et al. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures , 1985 .
[141] R. S. Culver. Thermal Instability Strain in Dynamic Plastic Deformation , 1973 .
[142] L. M. Yeakley,et al. High strain-rate testing: Tension and compression , 1968 .
[143] S. P. Keeler. Plastic instability and fracture in sheets stretched over rigid punches , 1961 .
[144] J. H. Hollomon,et al. Effect of Strain Rate Upon Plastic Flow of Steel , 1944 .