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Ali, Usman
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Publications (7/7 displayed)
- 20243D AND 4D PRINTING: A REVIEW OF VIRGIN POLYMERS USED IN FUSED DEPOSITION MODELINGcitations
- 2024Design and performance investigation of metamaterial-inspired dual band antenna for WBAN applicationscitations
- 2023Carbon and Titanium Effect on Tensile Behavior of Aged A286 Nickel-Iron Based Superalloy
- 2023Design and SAR Analysis of AMC-Based Fabric Antenna for Body-Centric Communicationcitations
- 2023Strategic Optimization of Annealing Parameters for Efficient and Low Hysteresis Triple Cation Perovskite Solar Cellcitations
- 2022Validation of DEM using macroscopic stress-strain behavior and microscopic particle motion in sheared granular assemblies
- 2019MICROSTRUCTURE AND CORROSION ANALYSIS OF RRA HEAT TREATED AA7075-T6 TEMPERED ALUMINIUM ALLOY
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article
Carbon and Titanium Effect on Tensile Behavior of Aged A286 Nickel-Iron Based Superalloy
Abstract
<jats:p>A286 nickel-iron based superalloy used in high temperature applications. Age hardening is done to enhance the creep behavior which is much affected by TiC and eta (ⴄ (Ni<jats:sub>3</jats:sub>Ti)) phases. Effect of carbon and titanium (0.02C-2.46Ti, 0.04C-2.54Ti, 0.05C-2.58Ti, and 0.06C-2.62Ti) on tensile behavior of aged A286 superalloy is systematically investigated via TiC and ⴄ (Ni<jats:sub>3</jats:sub>Ti) phases. It has been revealed that carbon and titanium contents are in proportional to nucleation of TiC and eta phases in the austenitic matrix of this alloy. Precipitation of these phases enhanced yield strength from 354MPa to 501MPa and ultimate tensile strength (UTS) 543MPa to 651MPa. However, plasticity decreased nearly 4%. Fracture topography showed that the ductile transgranular fracture in low C-Ti alloys are due to TiC particles, whereas in high C-Ti alloys fracture nature is found brittle intergranular due to eta phases.</jats:p>