#23 A 5.00-kg block is set into motion up an inclined plane with an initial speed of vi = 8.00 m/s. The block comes to rest after traveling d = 3.00 m along the plane, which is inclined at an angle of θ = 30.0o to the horizontal. For this motion, determine:(a) the change in the block's kinetic energy,(b) the change in the potential energy of the block– Earth system,(c) the friction force exerted on the block (assumed to be constant).(d) What is the coefficient of kinetic friction?Question 2: #80 In a physics lab experiment, a spring clamped to the table shoots a 20 g ball horizontally. When the spring is compressed 20 cm, the ball travels horizontally 5.0 m and lands on the floor 1.5 m below the point at which it left the spring. What is the spring constant? **Understanding Motion on an Inclined Plane**The diagram depicts a fundamental physics scenario involving motion on an inclined plane. Here is a detailed overview:1. **Inclined Plane (Ramp)**: The yellowish-brown triangular wedge represents an inclined plane, making an angle (θ) with the horizontal.2. **Block**: There are two small blue square blocks placed on the inclined plane. These blocks serve as objects undergoing motion analysis.3. **Initial Velocity (v₁)**: A red arrow pointing up the ramp signifies the initial velocity (v₁) of the block. This suggests that the block is moving up the inclined plane.4. **Distance (d)**: There is a horizontal arrow pointing from the first block to the second, labeled with "d". This indicates the distance between the two positions of the block on the inclined plane.5. **Inclination Angle (θ)**: The bottom left corner of the ramp shows an angle θ. This is the angle of the inclination of the ramp with respect to the horizontal surface.### Explanation of the Scenario:A block is moving up the inclined plane with an initial velocity \( v_1 \), and it travels a distance \( d \) along the plane. In the context of physics problems, this situation often involves analyzing the forces acting on the block (such as gravitational force, normal force, and friction, if any) and utilizing equations of motion to understand various parameters such as acceleration, velocity at different points, and energy considerations. The inclination angle \( \theta \) and distance \( d \) are crucial for determining components of forces and the kinematic equations that describe the block's motion.

Name: #23 A 5.00-kg block is set into motion up an inclined plane with an i
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Description: #23 A 5.00-kg block is set into motion up an inclined plane with an initial speed of vi = 8.00 m/s. The block comes to rest after traveling d = 3.00 m along the plane, which is inclined at an angle of θ = 30.0o to the horizontal. For this motion,

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Answered: A 5.00-kg block is set into motion up…

Inquiry into Physics

8th Edition

ISBN:9781337515863

Author:Ostdiek

Publisher:Ostdiek

Chapter1: The Study Of Motion

Section: Chapter Questions

Problem 1MIO: Consider Concept Map 1,1, which provides an overview of motion. Review Sections 1,2 and 1,3 and make...

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#23 A 5.00-kg block is set into motion up an inclined plane with an initial speed of v_i = 8.00 m/s. The block comes to rest after traveling d = 3.00 m along the plane, which is inclined at an angle of θ = 30.0^o to the horizontal. For this motion, determine:

(a) the change in the block's kinetic energy,

(b) the change in the potential energy of the block– Earth system,

(d) What is the coefficient of kinetic friction?

Question 2: #80 In a physics lab experiment, a spring clamped to the table shoots a 20 g ball horizontally. When the spring is compressed 20 cm, the ball travels horizontally 5.0 m and lands on the floor 1.5 m below the point at which it left the spring. What is the spring constant?

**Understanding Motion on an Inclined Plane**

The diagram depicts a fundamental physics scenario involving motion on an inclined plane. Here is a detailed overview:

1. **Inclined Plane (Ramp)**: The yellowish-brown triangular wedge represents an inclined plane, making an angle (θ) with the horizontal.

2. **Block**: There are two small blue square blocks placed on the inclined plane. These blocks serve as objects undergoing motion analysis.

3. **Initial Velocity (v₁)**: A red arrow pointing up the ramp signifies the initial velocity (v₁) of the block. This suggests that the block is moving up the inclined plane.

4. **Distance (d)**: There is a horizontal arrow pointing from the first block to the second, labeled with "d". This indicates the distance between the two positions of the block on the inclined plane.

5. **Inclination Angle (θ)**: The bottom left corner of the ramp shows an angle θ. This is the angle of the inclination of the ramp with respect to the horizontal surface.

### Explanation of the Scenario:

A block is moving up the inclined plane with an initial velocity \( v_1 \), and it travels a distance \( d \) along the plane. In the context of physics problems, this situation often involves analyzing the forces acting on the block (such as gravitational force, normal force, and friction, if any) and utilizing equations of motion to understand various parameters such as acceleration, velocity at different points, and energy considerations. The inclination angle \( \theta \) and distance \( d \) are crucial for determining components of forces and the kinematic equations that describe the block's motion.

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