Understanding Stress-Strain Graphs

Ultimate tensile strength

Yield point

Young's modulus

Plastic deformation

Elastic limit

Yield point

Ultimate tensile strength

Fracture point

The maximum stress a material can withstand while being stretched or pulled before failing.

The stress at which a material returns to its original shape after being deformed.

The initial slope of the stress-strain curve.

The stress required to initiate plastic deformation.

It is reversible.

It represents the maximum stress a material can withstand.

It occurs after the yield point.

It is independent of the material's Young's modulus.

By dividing the ultimate tensile strength by the strain at fracture.

By finding the slope of the curve in the plastic deformation region.

By dividing the stress by the strain in the elastic deformation region.

By measuring the area under the curve.

Elastic limit

Toughness

Young's modulus

Yield strength

The material fractures.

The material returns to its original shape.

The material begins to deform plastically.

The material reaches its maximum possible stress.

The deformation is reversible.

The relationship between stress and strain is linear.

The material has reached its ultimate tensile strength.

Young's modulus can be determined.

It indicates the maximum strain a material can undergo before necking.

It represents the stiffness of a material.

It is the maximum stress that a material can withstand while being stretched or pulled before it breaks.

It marks the transition from elastic to plastic deformation.

It determines the toughness of a material.

It indicates how easily a material can be deformed.

It measures the material's resistance to elastic deformation under load.

It shows the ductility of a material.