Cavitation-resistant intergranular precipitates enhance creep performance of θ'-strengthened Al-Cu based alloys.

[1]  X. Chen,et al.  Enhanced thermal stability of precipitates and elevated-temperature properties via microalloying with transition metals (Zr, V and Sc) in Al–Cu 224 cast alloys , 2021, Materials Science and Engineering: A.

[2]  K. Chattopadhyay,et al.  Five decades of research on the development of eutectic as engineering materials , 2021, Progress in Materials Science.

[3]  L. Allard,et al.  Aging behavior and strengthening mechanisms of coarsening resistant metastable θ' precipitates in an Al–Cu alloy , 2021 .

[4]  L. Allard,et al.  The synergistic role of Mn and Zr/Ti in producing θ′/L12 co-precipitates in Al-Cu alloys , 2020 .

[5]  Kun Liu,et al.  Enhanced mechanical properties of high-temperature-resistant Al–Cu cast alloy by microalloying with Mg , 2020, Journal of Alloys and Compounds.

[6]  A. Shyam,et al.  Grain Refinement Effect on the Hot-Tearing Resistance of Higher-Temperature Al–Cu–Mn–Zr Alloys , 2020, Metals.

[7]  L. Allard,et al.  Impact of microstructural stability on the creep behavior of cast Al–Cu alloys , 2020 .

[8]  J. Kuang,et al.  Nanostructural Sc-based hierarchy to improve the creep resistance of Al–Cu alloys , 2020 .

[9]  Dongwon Shin,et al.  Elevated temperature microstructural stability in cast AlCuMnZr alloys through solute segregation , 2019, Materials Science and Engineering: A.

[10]  S. Dar,et al.  Creep behavior of heat resistant Al–Cu–Mn alloys strengthened by fine (θ′) and coarse (Al20Cu2Mn3) second phase particles , 2019, Materials Science and Engineering: A.

[11]  L.F. Cao,et al.  Co-stabilization of θ′-Al2Cu and Al3Sc precipitates in Sc-microalloyed Al–Cu alloy with enhanced creep resistance , 2019, Materials Today Nano.

[12]  James R. Morris,et al.  Mechanisms for stabilizing θ′(Al2Cu) precipitates at elevated temperatures investigated with phase field modeling , 2019, Materialia.

[13]  James R. Morris,et al.  Temperature-dependent stability of θ′-Al2Cu precipitates investigated with phase field simulations and experiments , 2019, Materialia.

[14]  A. Deschamps,et al.  Recent advances in the metallurgy of aluminum alloys. Part II: Age hardening , 2018, Comptes Rendus Physique.

[15]  G. Liu,et al.  Stabilizing nanoprecipitates in Al-Cu alloys for creep resistance at 300°C , 2018, Materials Research Letters.

[16]  S. K. Makineni,et al.  Enhancement of High Temperature Strength of 2219 Alloys Through Small Additions of Nb and Zr and a Novel Heat Treatment , 2018, Metallurgical and Materials Transactions A.

[17]  Dongwon Shin,et al.  Solute segregation at the Al/θ′-Al2Cu interface in Al-Cu alloys , 2017 .

[18]  L. Allard,et al.  Comparative Evaluation of Cast Aluminum Alloys for Automotive Cylinder Heads: Part II—Mechanical and Thermal Properties , 2017, Metallurgical and Materials Transactions A.

[19]  V. Ström,et al.  Spatial correlation between local misorientations and nanoindentation hardness in nickel-base alloy 690 , 2016 .

[20]  F. Bonollo,et al.  The Effect of Transition Elements on High‐Temperature Mechanical Properties of Al–Si Foundry Alloys–A Review   , 2016 .

[21]  D. Bae,et al.  Strengthening behavior of carbon/metal nanocomposites , 2015, Scientific Reports.

[22]  K. Chattopadhyay,et al.  Development of alloys with high strength at elevated temperatures by tuning the bimodal microstructure in the Al-Cu-Ni eutectic system , 2014 .

[23]  Z. Xiliang,et al.  Creep behavior and microstructural evolution of deformed Al–Cu–Mg–Ag heat resistant alloy , 2014 .

[24]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[25]  D. Seidman,et al.  Precipitation evolution in Al–0.1Sc, Al–0.1Zr and Al–0.1Sc–0.1Zr (at.%) alloys during isochronal aging , 2010 .

[26]  I. Vasiliev,et al.  Computational study of the surface properties of aluminum nanoparticles , 2009 .

[27]  Stephan Saalfeld,et al.  Globally optimal stitching of tiled 3D microscopic image acquisitions , 2009, Bioinform..

[28]  D. Seidman,et al.  Precipitation evolution in Al–Zr and Al–Zr–Ti alloys during aging at 450–600 °C , 2008 .

[29]  D. Seidman,et al.  Criteria for developing castable, creep-resistant aluminum-based alloys – A review , 2006, International Journal of Materials Research.

[30]  F. Nabarro Creep at very low rates , 2002 .

[31]  O. Sherby,et al.  Influence of grain size, solute atoms and second-phase particles on creep behavior of polycrystalline solids , 2002 .

[32]  D. Dunand,et al.  Creep of metals containing high volume fractions of unshearable dispersoids—Part II. Experiments in the AlAl2O3 system and comparison to models , 1997 .

[33]  Dan Eliezer,et al.  The applicability of Norton's creep power law and its modified version to a single-crystal superalloy type CMSX-2 , 1996 .

[34]  W. Nix Mechanisms and controlling factors in creep fracture , 1988 .

[35]  A. Chokshi Analysis of constrained cavity growth during high temperature creep deformation , 1987 .

[36]  A. Argon,et al.  Diffusive growth of grain-boundary cavities , 1981 .

[37]  R. Singer,et al.  Deformation-induced microstructural instability in a θ′-hardened aluminum alloy at high temperature , 1979 .

[38]  R. Koeller,et al.  Diffusional relaxation of stress concentration at second phase particles , 1978 .

[39]  M. V. Speight,et al.  Vacancy Potential and Void Growth on Grain Boundaries , 1975 .

[40]  J. E. Harris The Inhibition of Diffusion Creep by Precipitates , 1973 .

[41]  D. Hull,et al.  The growth of grain-boundary voids under stress , 1959 .

[42]  M. E. Kassner,et al.  Five-power-law creep in single phase metals and alloys , 2000 .

[43]  Y. Takeda,et al.  Measurement of Thermodynamic Properties of Al–Sb System by Calorimeters , 1995 .

[44]  J. Rice,et al.  OVERVIEW NO. 9 – PLASTIC CREEP FLOW EFFECTS IN THE DIFFUSIVE CAVITATION OF GRAIN BOUNDARIES , 1983 .