Where does earths energy comes from

In the video, forces acting on the car that are parallel to the direction of motion are analyzed. how are these forces related?

expeople1 [14]

<span>The drag force acts opposite to the direction the cars' motion and the propelling force is in the direction of the motion. These are the two forces acting on the car and since they are both equal and opposite in direction, they cancel out each other. Thus, the car is able to move at a constant speed without changing its direction or momentum.</span>

5 0

3 years ago

Which statement correctly relates the first and second laws of thermodynamics?

o-na [289]

Thermal-energy flow between objects is conserved and always flows from the warmer object to the cooler object.

Here 'conserved' means that the amount of thermal energy lost of by one body is exactly equal to the amount of thermal energy gained by another body, which is the statement of the first law.

According to second law, we do not see objects warming up on their own. For example, if we have a cup of coffee left to itself, we would always see that it cools down. Here, thermal energy is being transferred from warmer object (coffee) to cooler objects (the air in the room).

4 0

3 years ago

Starting at 9a.m., you ride your hover board for 3hrs at an average speed of 6 mph. Out of breath, you stop for tea from noon un

Elena-2011 [213]

3 times 6= 18. The average speed is 19 mph.

hope this helps!

6 0

3 years ago

When an object is moving with uniform circular motion, the centripetal acceleration of the object a. is circular. b. is perpendi

never [62]

Hi Pupil Here's Your answer :::

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When an object is moving with uniform circular motion, the centripetal acceleration of the object $\textbf{is\:Zero}$ .

Because the body is moving with a uniform velocity and hence, there might not be any acceleration due to it.

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Hope this helps .......

5 0

3 years ago

A sock stuck to the inside of the clothes dryer spins around the drum once every 2.0 s at a distance of 0.50 m from the center o

Rashid [163]

a) 1.57 m/s

The sock spins once every 2.0 seconds, so its period is

T = 2.0 s

Therefore, the angular velocity of the sock is

$\omega=\frac{2\pi}{T}=\frac{2\pi}{2.0}=3.14 rad/s$