Damage Development Under Creep-Fatigue in a Titanium and a Superalloy

Tarun Goswami,

doi:10.1515/HTMP.1995.14.2.47

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Damage Development Under Creep-Fatigue in a Titanium and a Superalloy

Tarun Goswami,

Published/Copyright: May 6, 2011

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From the journal High Temperature Materials and Processes Volume 14 Issue 2

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MLA
APA
Harvard
Chicago
Vancouver

Goswami,, Tarun. "Damage Development Under Creep-Fatigue in a Titanium and a Superalloy" High Temperature Materials and Processes, vol. 14, no. 2, 1995, pp. 47-56. https://doi.org/10.1515/HTMP.1995.14.2.47

Goswami,, T. (1995). Damage Development Under Creep-Fatigue in a Titanium and a Superalloy. High Temperature Materials and Processes, 14(2), 47-56. https://doi.org/10.1515/HTMP.1995.14.2.47

Goswami,, T. (1995) Damage Development Under Creep-Fatigue in a Titanium and a Superalloy. High Temperature Materials and Processes, Vol. 14 (Issue 2), pp. 47-56. https://doi.org/10.1515/HTMP.1995.14.2.47

Goswami,, Tarun. "Damage Development Under Creep-Fatigue in a Titanium and a Superalloy" High Temperature Materials and Processes 14, no. 2 (1995): 47-56. https://doi.org/10.1515/HTMP.1995.14.2.47

Goswami, T. Damage Development Under Creep-Fatigue in a Titanium and a Superalloy. High Temperature Materials and Processes. 1995;14(2): 47-56. https://doi.org/10.1515/HTMP.1995.14.2.47

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Published Online: 2011-05-06

Published in Print: 1995-04

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CONTENTS
Damage Development Under Creep-Fatigue in a Titanium and a Superalloy
Can Thermal Barrier Coatings be Sealed by Metal-Organic Chemical Vapour Deposition of Silica and Alumina?
Grain Boundary Penetration of a Ni-Rich Melt in Tungsten Polycrystals
Anomalous Scattering Factors near the Zn Κ Absorption Edge Estimated from the Absorption Coefficient Measurement of ZnFe2O4
Applicability of Modified Diercks Equation with NRIM Data
Relationship between Recrystallization Kinetics and Rate of Creep Cavitation in Bubble Strengthened Tungsten
Fullerite-Diamond Transition Under Shock Loading
Creep-Fatigue Life Prediction - A Ductility Model
Preparation of Zirconium and Hafnium Metal Powders Using Fused Salt Electrolysis
Growing Single Crystals of High-Purity Refractory Metals by Electron-Beam Zone Melting
X-Ray Diffraction Study on the Structure of Liquid Li2O-B2O3

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Articles in the same Issue

CONTENTS
Damage Development Under Creep-Fatigue in a Titanium and a Superalloy
Can Thermal Barrier Coatings be Sealed by Metal-Organic Chemical Vapour Deposition of Silica and Alumina?
Grain Boundary Penetration of a Ni-Rich Melt in Tungsten Polycrystals
Anomalous Scattering Factors near the Zn Κ Absorption Edge Estimated from the Absorption Coefficient Measurement of ZnFe2O4
Applicability of Modified Diercks Equation with NRIM Data
Relationship between Recrystallization Kinetics and Rate of Creep Cavitation in Bubble Strengthened Tungsten
Fullerite-Diamond Transition Under Shock Loading
Creep-Fatigue Life Prediction - A Ductility Model
Preparation of Zirconium and Hafnium Metal Powders Using Fused Salt Electrolysis
Growing Single Crystals of High-Purity Refractory Metals by Electron-Beam Zone Melting
X-Ray Diffraction Study on the Structure of Liquid Li2O-B2O3