JoDean Morrow scite author profile

The oxidation and scale crystallization kinetics of Hi‐NicalonTM‐S SiC fibers were measured after oxidation in dry air between 700° and 1400°C. Scale thickness, composition, and crystallization were characterized by TEM with EDS, supplemented by SEM and optical microscopy. TEM was used to distinguish oxidation kinetics of amorphous and crystalline scales. Oxidation initially produces an amorphous silica scale that incorporates some carbon. Growth kinetics of the amorphous scale was analyzed using the flat‐plate Deal‐Grove model. The activation energy for parabolic oxidation was 248 kJ/mol. The scales crystallized to tridymite and cristobalite, starting at 1000°C in under 100 h and 1300°C in under 1 h. Crystallization kinetics had activation energy of 514 kJ/mol with a time growth exponent of 1.5. Crystalline silica nucleated at the scale surface, with more rapid growth parallel to the surface. Crystalline scales cracked from thermal residual stress and phase transformations during cool‐down, and during oxidation from tensile hoop growth stress. High growth shear stress was inferred to cause intense dislocation plasticity near the crystalline SiO2–SiC interphase. Crystalline scales were thinner than amorphous scales, except where growth cracks allowed much more rapid oxidation.

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Microplastic Strain Hysteresis Energy as a Criterion for Fatigue Fracture

Feltner

Morrow

1961

227

123

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In this paper an energy criterion for fatigue failure is postulated. Microplastic strain hysteresis energy is considered to be an index for fatigue damage. On this basis, a relation is developed between stress amplitude and the number of cycles to failure which utilizes only material properties obtained from the static true stress-strain tension test. The analysis is found to compare well with an experimentally determined S-N curve for SAE 4340 steel.

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Relationships Between Fiber Strength, Passive Oxidation and Scale Crystallization Kinetics of Hi‐Nicalon™‐S SiC Fibers

Hay

Fair

Bouffioux

et al. 2011

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Neuber's Rule Applied to Fatigue of Notched Specimens

Topper¹,

Wetzel²,

Morrow³

1967

146

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JoDean Morrow

Cyclic Plastic Strain Energy and Fatigue of Metals

Hi‐Nicalon^TM‐SSiC Fiber Oxidation and Scale Crystallization Kinetics

Microplastic Strain Hysteresis Energy as a Criterion for Fatigue Fracture

Relationships Between Fiber Strength, Passive Oxidation and Scale Crystallization Kinetics of Hi‐Nicalon™‐S SiC Fibers

Neuber's Rule Applied to Fatigue of Notched Specimens

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About

JoDean Morrow

Cyclic Plastic Strain Energy and Fatigue of Metals

Hi‐NicalonTM‐SSiC Fiber Oxidation and Scale Crystallization Kinetics

Microplastic Strain Hysteresis Energy as a Criterion for Fatigue Fracture

Relationships Between Fiber Strength, Passive Oxidation and Scale Crystallization Kinetics of Hi‐Nicalon™‐S SiC Fibers

Neuber's Rule Applied to Fatigue of Notched Specimens

Contact Info

Product

Resources

About

Hi‐Nicalon^TM‐SSiC Fiber Oxidation and Scale Crystallization Kinetics