Final answer:
The angular displacement of a disk with an initial angular velocity of 5.5 rad/s, constant angular acceleration of 2.5 rad/s², over a time period of 95 seconds is calculated using the kinematic equation for rotational motion. Substituting the given values into the equation, the displacement can be found.
Step-by-step explanation:
The student's question asks about calculating the angular displacement of a disk given its initial angular velocity, constant angular acceleration, and the time interval during which it is accelerating. To find the angular displacement θ (theta) during the time interval, one can use the kinematic equation for rotational motion:
θ = ω0t + ½αt2
Where:
- ω0 is the initial angular velocity (5.5 rad/s in this case)
- α is the angular acceleration (2.5 rad/s²)
- t is the time period (95 s)
Applying these values, we find the angular displacement of the disk:
θ = (5.5 rad/s × 95 s) + ½(2.5 rad/s² × 95 s2)
This equation gives us the total radians through which the disk has rotated in the given time period under constant angular acceleration.