When solving the problem of pool game and calculating the magnitude of the final velocity of the cue ball, the correct option is 0.56 m/s.
The following method: Use the principle of conservation of momentum, i.e. momentum before the collision is equal to the momentum after the collision, which is mathematically written as: [tex]$$mv_1+Mv_2=(m + M)v_3$$[/tex]
Where, m is the mass of the cue ball,
M is the mass of the striped ball,
v1 is the velocity of the cue ball before the collision,
v2 is the velocity of the striped ball before the collision, and
v3 is the velocity of the cue ball after the collision.
Using the above formula, we get the final velocity of the cue ball as:
[tex]$$v_3=frac {mv_1+Mv_2}{m+M}$$[/tex]
Plug in the given values, we get,
[tex]$$v_3=frac{0.4*0.80+0.4*0.38}{0.4+0.4}$$[/tex]
Solving for v3, we get [tex]$v_3=0.59$[/tex] m/s Therefore, the magnitude of the final velocity of the cue ball is 0.59 m/s.
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A 5-kg object is moving to the right at 4 m/s and collides with another object moving to the left at 5 m/s. The objects collide and stick together. After the collision, the combined object:
After the collision, the two objects stick together and move as one. Their total mass is m1 + m2 = 5 kg + m2.
How to determine the effect of the collisionIn this case, we can apply the principle of conservation of linear momentum
The initial momentum of the first object (P1_initial) is given by its mass (m1) times its velocity (v1), which is [tex]5 kg * 4 m/s = 20 kg*m/s.[/tex]
Therefore, the total initial momentum [tex](P_{total_initial}) is P1_{initial} + P2_{initial} = 20 kg*m/s - m2 * 5 m/s.[/tex]
After the collision, the two objects stick together and move as one.
Their total mass is m1 + m2 = 5 kg + m2.
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Assuming a constant density, the size of an object scales as its mass raised to what power?.
Assuming a constant density, the size of an object scales as its mass raised to the power of 1/3 (one-third).
The mass, density, and volume of an object are related by the equation:
ρ = m/Vwhere ρ is the density, m is the mass, and V is the volume.
We can write this equation as
V = m/ρThis equation can be used to find the relationship between the mass and volume of an object of constant density.
Assume that we have two objects of the same material with masses m1 and m2.
We can find the ratio of their volumes by taking the ratio of their masses and density as follows:
V1/V2 = m1/ρ / m2/ρV1/V2 = m1/m2V1/V2 = (m1/m2)^(1/3)
This shows that the ratio of the volumes of two objects with the same density is proportional to the cube root of the ratio of their masses.
This relationship can be expressed as:
V ∝ m^(1/3)
This relationship can also be expressed as the size of an object scales as its mass raised to the power of 1/3.
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A particle with a charge of 5nC has a distance of 0. 5m away from a charge of 9. 5nC. What is its electric potential energy?
The electric potential energy of the particle with a charge of 5nC, located 0.5m away from a charge of 9.5nC, is 1.9 J.
To calculate the electric potential energy, we can use the formula:
Electric potential energy = (k * q1 * q2) / r
Where:
k is the electrostatic constant (9 x 10^9 N m^2/C^2),
q1 and q2 are the charges of the two particles (in this case, 5nC and 9.5nC, respectively),
r is the distance between the charges (0.5m).
Substituting the given values into the formula:
Electric potential energy = (9 x 10^9 N m^2/C^2) * (5 x 10^-9 C) * (9.5 x 10^-9 C) / 0.5m
Calculating the expression:
Electric potential energy ≈ 1.9 J
Therefore, the electric potential energy of the particle is approximately 1.9 Joules.
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Inertia is the natural tendency of every object to resist change to either speed or direction. Describe a way in which you observe this in your everyday life.
Inertia refers to the natural tendency of every object to resist any change in either speed or direction. Every object tends to maintain its state of motion until an external force acts on it.
Inertia is an essential concept in physics, and it can be observed in everyday life. Here is how you can observe inertia in your everyday life:
When you are in a moving car, and the driver suddenly stops, your body tends to move forward. This is because of inertia. Your body is already in motion, and when the car stops, your body tends to keep moving in the same direction. The seatbelt helps to prevent this movement by exerting a force on your body in the opposite direction.
When you are on a merry-go-round and it starts spinning, you tend to feel a force pushing you away from the center of the ride. This is also due to inertia. Your body is already in motion, and when the ride starts spinning, your body tends to keep moving in the same direction. The force that pushes you away from the center of the ride is known as the centrifugal force.
When you are playing a game of pool, and you hit the cue ball, it tends to keep moving until it comes into contact with another ball or hits the wall of the table. This is also due to inertia. The cue ball is already in motion, and it tends to maintain its state of motion until it comes into contact with another object or hits the wall of the table.
These are just a few examples of how you can observe inertia in your everyday life.
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