An object of mass M = 2.00 kg is attached to a spring with spring constant k = 352 N/m whose unstretched length is L = 0.120 m, and whose far end is fixed to a shaft that is rotating with an angular speed of w= 4.00 radians/s 3/s. Neglect gravity and assume that the mass also rotates with an angular speed of 4.00 radians/s as shown. (Figure 1)When solving this problem use an inertial coordinate system, as drawn here. (Figure 2) Figure min 1 of 2 > W ▼ ✓ Given the angular speed of w = 4.00 radians/s, find the radius R (w) at which the mass rotates without moving toward or away from the origin. Express your answer in meters. ► View Available Hint(s) R(w) = 0.132 m Submit ✓ Correct Part B Previous Answers Assume that, at a certain angular speed w2, the radius R becomes twice L. Find w₂. Express your answer in radians per second. ▸ View Available Hint(s) W2 = Submit Ψ—| ΑΣΦ 3 C ? radians/s

I need help with part B please

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**Physics Problem: Rotational Dynamics and Springs** **Background Information:** An object of mass \( M = 2.00 \, \text{kg} \) is attached to a spring with a spring constant \( k = 352 \, \text{N/m} \). The spring's unstretched length is \( L = 0.120 \, \text{m} \), and the far end of the spring is fixed to a shaft that rotates at an angular speed of \( \omega = 4.00 \, \text{radians/s} \). Neglect gravity and assume that the mass also rotates with an angular speed of \( 4.00 \, \text{radians/s} \). **Problem Description:** - **Part A:** Given the angular speed \( \omega = 4.00 \, \text{radians/s} \), find the radius \( R(\omega) \) at which the mass rotates without moving toward or away from the origin. Express your answer in meters. - **Answer:** \( R(\omega) = 0.132 \, \text{m} \) - **Status:** Correct. - **Part B:** Assume that, at a certain angular speed \( \omega_2 \), the radius \( R \) becomes twice \( L \). Find \( \omega_2 \). Express your answer in radians per second. **Diagram Explanation:** - The figure illustrates a mass \( M \) connected to a spring with constant \( k \). The spring is attached to a rotating shaft. The system rotates at an angular speed \( \omega \). The radius \( R \) extends from the axis of rotation to the mass. The goal of this exercise is to apply principles of mechanics to determine the conditions under which the mass maintains a stable rotational path and to explore the relationship between angular speed and the spring's extension involved in centrifugal motion.