Items where Subject is "Metallurgy > Alloys and Compounds > Nickel Alloys"
Group by: Creators | Item Type
Number of items at this level: 8.
Djobo, J N Y and Elimbi, A and Tchakoute, H K and Kumar, Sanjay (2016) Mechanical activation of volcanic ash for geopolymer synthesis: effect on reaction kinetics, gel characteristics, physical and mechanical properties. RSC Advances, 6(45) (IF 3.169). pp. 39106-39117.
Paswan, Dayanand and Vaish, A K and Singh, S D and Ghorai, S and Malathi, M and Prasad, S and Minj, R K (2014) Production of Alloy Cast Iron from Multi–Metallic Magnetite Ore of Nagaland. Steel World 2013, 19/11 . pp. 36-38.
Rai, R K and Jena, P S M and Paulose, N and Sahu, J K (2022) Effect of carbide precipitation on Coffin-Manson relationship of a polycrystalline nickel-based superalloy. Fatigue & Fracture of Engineering Materials and Structures .
Rai, R K and Sahu, J K (2018) Mechanism of serrated flow in a cast nickel base superalloy. Materials Letters, 210 (IF-2.572). pp. 298-300.
Rai, R K and Sahu, J K and Das, S K and Paulose, N and Fernando, C (2020) Creep-fatigue deformation micromechanisms of a directionally solidified nickel-base superalloy at 850 degrees C. Fatigue & fracture of engineering materials & structures, 43(1) (IF- 2.555). pp. 51-62.
Rai, R K and Sahu, J K and Jena, P S M and Das, Swapan K and Paulose, N and Fernando, C D (2017) High temperature tensile deformation of a directionally solidified nickel base superalloy: Role of micro constituents. Materials Science and Engineering A, 705 (IF-3.094). pp. 189-195.
Rai, R K and Sahu, J K and Paulose, N and Fernando, C (2020) Low Cycle Fatigue Behavior of a Directionally Solidified Nickel-Based Superalloy: Mechanistic and Microstructural Aspect. Metallurgical and Materials Transactions A - Physical metallurgy and materials science, 51(6) (IF-2.050). pp. 2752-2765.
Tarafder, Mita and Sujata, M and Ranganath, V R and Tarafder, S and Bhumik, S K (2013) Microstructural Damage Evaluation in Ni-based Superalloy Gas Turbine Blades by Fractal Analysis. Procedia Engineering, 55 . pp. 289-294.