Two blocks are connected by a massless rope. The rope passes over an ideal (frictionless and massless) pulley such that one block with mass m₁ = 13.25 kg is on a horizontal table and the other block with mass m₂ = 9.5 kg hangs vertically. Both blocks experience gravity and the tension force, T. Use the coordinate system specified in the diagram.

 

1. Carefully consider how the accelerations a₁ and a₂ are related. Solve for the magnitude of the acceleration, a₁, of the block of mass m₁, in meters per square second. 

2. Find the magnitude of the tension in the rope, T, in newtons. 

Transcribed Image Text:

The image depicts a classic physics problem involving two masses connected by a string over a pulley. This setup is commonly used to study the principles of classical mechanics, specifically tension and acceleration in connected systems. ### Diagram Details: - **Mass \( m_1 \):** - Positioned on a horizontal surface. - Forces acting on it: - Downward gravitational force \( m_1g \). - Upward normal force \( N \). - Horizontal tension \( T \) in the string. - Horizontal acceleration \( a \) to the right. - **Pulley System:** - The string passes over a pulley, which is assumed to be frictionless. - Tension \( T \) is the same on both sides of the pulley if the string and pulley are ideal (massless and frictionless). - **Mass \( m_2 \):** - Suspended vertically. - Forces acting on it: - Downward gravitational force \( m_2g \). - Upward tension \( T \) in the string. - Acceleration \( a \) downward. ### Key Concepts: - **Normal Force (N):** The perpendicular contact force exerted by a surface on an object. - **Tension (T):** The force conducted along the string, opposing the weight on the suspended mass and pulling the mass on the surface. This setup allows exploration of Newton’s Second Law (\( F = ma \)) as applied to different masses and helps in determining the relationship between the forces, tension, and acceleration in such systems.