Fisika XI Elastisitas Part 1

SMA Muhammadiyah 1 Yogyakarta

8 Aug 202109:53

Summary

TLDRIn this physics lesson, Khawarizmi Mahfud introduces the concept of elasticity, explaining the difference between elastic and plastic materials. Using rubber and plastic as examples, he demonstrates how elasticity allows materials to return to their original shape after being stretched, while plastic materials do not. The lesson then covers Young's modulus, a measure of a material's elasticity, with a focus on tension, strain, and modulus calculations. Example problems are provided to illustrate how to compute tension, strain, and modulus, making the content accessible and engaging for students learning about material properties in physics.

Takeaways

😀 **Elasticity** is the ability of a material to return to its original shape after deformation when the applied force is removed.
😀 **Elastic materials** like rubber return to their original shape after stretching, whereas **plastic materials** like plastic do not.
😀 The property of elasticity is a fundamental concept in physics that helps describe how materials respond to external forces.
😀 **Young’s Modulus** (also called the modulus of elasticity) is a measure of the stiffness of a material, indicating how resistant it is to deformation.
😀 The formula for **Young’s Modulus** is: E = (Tensile Stress) / (Tensile Strain), which helps determine how much force is needed to stretch a material.
😀 **Tensile Stress** is defined as force per unit area, and **Tensile Strain** is the change in length divided by the original length.
😀 The higher the Young’s Modulus, the stiffer the material, meaning it requires more force to stretch or compress.
😀 In the first example, we calculated the **tensile stress**, **strain**, and **Young’s Modulus** for a rope using its force, cross-sectional area, and length change.
😀 In the second example, we used Young’s Modulus to calculate the extension of a wire, showing how force and material properties determine deformation.
😀 Understanding **modulus of elasticity** and material behavior under stress is crucial for designing structures and understanding material performance under different conditions.

Q & A

What is the definition of elasticity in physics?
-Elasticity refers to the ability of a material to return to its original shape after the force applied to it is removed.
How does plasticity differ from elasticity?
-Plasticity refers to the inability of a material to return to its original shape after being deformed, unlike elasticity, where the material regains its shape after the force is removed.
What is Young's Modulus?
-Young's Modulus is a measure of the stiffness of a material. It is the ratio of stress (force per unit area) to strain (relative deformation), and it quantifies how much a material will stretch or compress under a given force.
What is the formula for calculating stress?
-Stress is calculated using the formula: Stress = Force / Area, where Force (F) is the applied force, and Area (A) is the cross-sectional area of the material.
What does strain represent in materials science?
-Strain represents the relative deformation or change in shape of a material when a force is applied. It is calculated as the change in length divided by the original length of the material.
What is the formula for calculating strain?
-Strain is calculated using the formula: Strain = Change in Length (ΔL) / Original Length (L₀). It is a dimensionless quantity.
How is Young's Modulus calculated?
-Young's Modulus is calculated as the ratio of stress to strain: E = Stress / Strain, or E = (F / A) / (ΔL / L₀), where F is the force applied, A is the cross-sectional area, ΔL is the change in length, and L₀ is the original length.
What is the relationship between stress and strain in elastic materials?
-In elastic materials, stress is directly proportional to strain within the elastic limit. This means that as the force applied increases, the deformation (strain) increases proportionally, as described by Young's Modulus.
What are the units of stress and strain?
-Stress has the unit of Newtons per square meter (N/m²) or Pascals (Pa). Strain is dimensionless and does not have units since it is a ratio of lengths.
How do you calculate the final length of a stretched material?
-To calculate the final length of a material after it has been stretched, you add the change in length (ΔL) to the original length (L₀). The formula is: Final Length = Original Length + ΔL.