Necking occurs in the material. A. A v Fracture. v The material has no plastic deformation. В. В C. C The point that defines the yield strength of the material. D.D Plastic deformation and strain hardening occurs. Е. Е F. F The point that defines the tensile strength of the material.

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**Engineering Stress-Strain Diagram Analysis** This diagram represents an engineering stress-strain curve for a ductile metal sample. It highlights critical points that describe the state of the material during deformation: - **Point A:** - No plastic deformation occurs. - Represents the initial linear elastic region. - **Point B:** - The point defining the yield strength of the material. - Indicates the start of plastic deformation where the material begins to deform permanently. - **Point C:** - The point where plastic deformation and strain hardening occur. - As stress increases, the material strains further at a slowly decreasing rate. - **Point D:** - Defines the tensile strength of the material. - Maximum stress the material can withstand while being stretched before necking begins. - **Point E:** - Necking occurs in the material. - Stress decreases with increasing strain due to the reduction of cross-sectional area. - **Point F:** - Fracture point. - Marks the failure of the material where it breaks apart. This diagram helps in understanding the mechanical properties and behavior of materials under various loading conditions, crucial for materials engineering and design applications.