Avertical spring (spring constant =160 n/m) is mounted on the floor. a 0.340-kg block is placed on top of the spring and pushed down to start it oscillating in simple harmonic motion. the block is not attached to the spring. (a) obtain the frequency (in hz) of the motion. (b) determine the amplitude at which the block will lose contact with the spring.

a. The frequency (in Hz) of the motion is equal to 3.45 Hertz.

b. The amplitude at which the block will lose contact with the spring is 0.021 meters.

Given the following data:

a. To find the frequency (in Hz) of the motion:

Since the spring initiates simple harmonic motion, we would determine its angular frequency.

Mathematically, angular frequency of a spring is given by the formula:

Where:

Substituting the given parameters into the formula, we have;

Now, we can find the frequency of the motion by using the formula:

Frequency, F = 3.45 Hz

b. To determine the amplitude at which the block will lose contact with the spring:

Where:

Substituting the parameters into the formula, we have;

Amplitude, A = 0.021 meters

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(a) 3.5 Hz

The angular frequency in a spring-mass system is given by

where

k is the spring constant

m is the mass

Here in this problem we have

k = 160 N/m

m = 0.340 kg

So the angular frequency is

And the frequency of the motion instead is given by:

(b) 0.021 m

The block is oscillating up and down together with the upper end of the spring. The block will lose contact with the spring when the direction of motion of the spring changes: this occurs when the spring is at maximum displacement, so at

x = A

where A is the amplitude of the motion.

The maximum displacement is given by Hook's law:

where

F is the force applied initially to the spring, so it is equal to the weight of the block:

k = 160 N/m is the spring constant

Solving for A, we find

160.43 meters

Explanation:

T=(2*pi*r)/v

840=(2*pi*r)/1.2

1008=2*pi*r

504=pi*r

160.43=radius