A block of mass m= 10.0 kg is attached to the end of an ideal spring. Due to the weight of the block, the block remains at rest when the spring is stretched a distance h= 6.00 cm from its equilibrium length. (Figure 1)The spring has an unknown spring constant k. Take the acceleration due to gravity to be g = 9.81 m/s2 .

a)What is the spring constant k?

b)Suppose that the block gets bumped and undergoes a small vertical displacement. Find the resulting frequency 'f' of the block's oscillations about its equilibrium position.

Express your answer in hertz.

 

 

Transcribed Image Text:

The image illustrates a basic spring-mass system. It consists of two vertical springs attached to a fixed horizontal support at their upper ends. The springs are identical, and one of them is shown in its relaxed (unstressed) state, labeled with height "h". Below this spring, there is nothing attached. Next to the relaxed spring, another identical spring has a mass "m" attached to its lower end. The weight of the mass causes this spring to stretch. The stretched spring extends to a position, with the additional distance labeled as "y," indicating the amount of stretch compared to the relaxed spring. Key components: - A fixed horizontal support from which both springs hang. - A relaxed spring showing its natural length with a vertical distance "h" labeled between the top and bottom. - A stretched spring with a mass "m" attached, showing how it extends further by a distance "y". This diagram is used to demonstrate the concepts of spring mechanics, such as Hooke's Law, where the force exerted by a spring is proportional to its extension or compression from its natural length.