Consider a frictionless track as shown in the figure below. A block of mass m₁ = 4.85 kg is released from . It makes a head-on elastic collision at  with a block of mass m₂ = 15.0 kg that is initially at rest. Calculate the maximum height to which m₁ rises after the collision. Answer should be in meters. 

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### Example of an Inclined Plane with Masses In this diagram, we have an example of an inclined plane scenario with two masses, \( m_1 \) and \( m_2 \). Below is a detailed description of the elements in the figure: #### Diagram Description: 1. **Inclined Plane**: - The inclined plane is a curved surface starting from point \( A \) and descending down to a flat horizontal plane. - At point \( A \), mass \( m_1 \) is positioned at the top of the incline. - The height from point \( A \) vertically down to the base of the inclined plane is \( 5.00 \) meters. 2. **Horizontal Plane**: - This is the flat surface extending horizontally from the base of the inclined plane, starting from point \( B \). - Mass \( m_2 \) is resting on the horizontal plane at some distance from point \( B \). #### Explanation: - **Mass 1 (\( m_1 \))**: This mass is initially positioned at the top of the curved inclined plane at point \( A \). - **Mass 2 (\( m_2 \))**: This mass is located on the horizontal plane, positioned at some distance away from point \( B \). The figure illustrates the scenario of objects on an inclined plane transitioning to a horizontal plane, highlighting the initial and final positions of the masses, as well as the dimensions involved. The vertical height of 5.00 meters is crucial for calculating potential energy and other related physics problems, such as kinetic energy, acceleration, and time of descent for the mass \( m_1 \). This setup can be used to demonstrate various principles in physics, including gravitational potential energy, conservation of energy, friction (if it were to be included), and other principles of mechanics.