Glossary

10.4 Moment of Inertia and Rotational Kinetic Energy

3 min readjune 24, 2024

Rotational motion adds a twist to energy concepts. We'll spin through kinetic energy's two forms: translational and rotational. Both depend on mass and velocity, but rotational energy considers how mass is distributed around the .

is the star of the rotational show. It measures an object's resistance to , like a in an engine. The distribution of mass affects an object's , influencing its rotational behavior.

Rotational Motion and Energy

Rotational vs translational kinetic energy

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Top images from around the web for Rotational vs translational kinetic energy

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  • Translational kinetic energy KE=12mv2KE = \frac{1}{2}mv^2 depends on mass mm and linear velocity vv (car moving along a straight road)
  • KErot=12Iω2KE_{rot} = \frac{1}{2}I\omega^2 depends on moment of inertia II and ω\omega (spinning figure skater)
  • Both forms of kinetic energy measured in joules (J) and are scalar quantities
  • Total kinetic energy is the sum of translational and rotational kinetic energies (rolling wheel)

Moment of inertia fundamentals

  • Moment of inertia II measures an object's resistance to rotational acceleration (flywheel in an engine)
  • I=mr2I = \sum mr^2 for discrete particles, where mm is mass and rr is distance from the axis of rotation
  • I=r2dmI = \int r^2 dm for continuous objects, where dmdm is an infinitesimal mass element
  • Objects with more mass farther from the axis of rotation have higher moment of inertia (figure skater with arms extended)
  • Higher moment of inertia results in greater resistance to rotational acceleration
  • Moment of inertia depends on the axis of rotation
    • Parallel-axis theorem I=[ICM](https://www.fiveableKeyTerm:ICM)+Md2I = [I_{CM}](https://www.fiveableKeyTerm:I_{CM}) + Md^2 relates moment of inertia about any axis to the moment of inertia about the center of mass axis ICMI_{CM}, total mass MM, and distance between axes dd

Energy Conservation and Rotational Dynamics

Impact of inertia on rotational energy

  • Increasing moment of inertia while maintaining increases (figure skater pulling arms in during a spin)
  • Decreasing moment of inertia while maintaining angular velocity decreases rotational kinetic energy
  • If moment of inertia changes and rotational kinetic energy remains constant, angular velocity must change to compensate
    • Decreasing II increases ω\omega, while increasing II decreases ω\omega (figure skater extending arms to slow down spin)
  • L=IωL = I\omega is conserved in the absence of external torques

Conservation in combined motion systems

  • Total mechanical energy [E = KE + KE_{rot} + PE](https://www.fiveableKeyTerm:E_=_KE_+_KE_{rot}_+_PE) includes translational kinetic energy KEKE, rotational kinetic energy KErotKE_{rot}, and potential energy PEPE
  • In the absence of non-conservative forces, total mechanical energy is conserved [E_i = E_f](https://www.fiveableKeyTerm:E_i_=_E_f) (roller coaster at different heights)
  • Solve problems by equating initial and final total mechanical energy, considering changes in translational and rotational kinetic energy as well as potential energy
  • Account for energy transfers between translational, rotational, and potential forms (yo-yo rolling down a ramp)
  • The relates the work done on a system to its change in kinetic energy

Angular velocity in non-ideal rotations

  • Angular velocity ω=dθdt\omega = \frac{d\theta}{dt} is the rate of change of angular displacement θ\theta with respect to time
  • In the presence of non-conservative forces, mechanical energy is not conserved
  • Work done by non-conservative forces, such as friction, reduces the total mechanical energy of the system (sliding block coming to rest due to friction)
  • To calculate angular velocity with non-conservative forces:
    1. Calculate the work done by non-conservative forces [Wnc](https://www.fiveableKeyTerm:Wnc)[W_{nc}](https://www.fiveableKeyTerm:W_{nc})
    2. Subtract WncW_{nc} from the initial total mechanical energy to determine the final total mechanical energy
    3. Use the final total mechanical energy to solve for the final angular velocity, considering the moment of inertia and any changes in potential energy (spinning top slowing down due to air resistance and friction at the point of contact)

Rotational Dynamics

  • τ=r×F\tau = r \times F is the rotational equivalent of force, causing rotational acceleration
  • Rotational acceleration α=dωdt\alpha = \frac{d\omega}{dt} is the rate of change of angular velocity
  • Newton's Second Law for rotation: τ=Iα\tau = I\alpha, relating torque, moment of inertia, and rotational acceleration

Key Terms to Review (33)

Angular momentum: Angular momentum is a measure of the quantity of rotation of an object and is a vector quantity. It is given by the product of the moment of inertia and angular velocity.
Angular Momentum: Angular momentum is a fundamental concept in physics that describes the rotational motion of an object. It is the measure of an object's rotational inertia and its tendency to continue rotating around a specific axis. Angular momentum is a vector quantity, meaning it has both magnitude and direction, and it plays a crucial role in understanding the behavior of rotating systems across various topics in physics.
Angular velocity: Angular velocity is the rate at which an object rotates around a fixed axis. It is measured in radians per second (rad/s).
Angular Velocity: Angular velocity is a measure of the rate of change of the angular position of an object. It describes the speed of rotation or the change in the orientation of an object around a fixed axis or point. This concept is fundamental in understanding the motion of objects undergoing circular or rotational motion.
Angular Velocity (ω): Angular velocity, denoted by the symbol ω (omega), is a measure of the rate of change of angular displacement with respect to time. It represents the speed of rotation or the number of revolutions or radians per unit of time.
Axis of Rotation: The axis of rotation is the imaginary line around which an object or system rotates. It is the fixed point or line that an object pivots or spins around as it undergoes rotational motion.
E = KE + KE_{rot} + PE: The total energy (E) of a system is equal to the sum of its kinetic energy (KE), rotational kinetic energy (KE_{rot}), and potential energy (PE). This equation represents the conservation of energy principle, which states that the total energy of an isolated system is constant and cannot be created or destroyed, but can be transformed or transferred from one form to another.
E_i = E_f: The principle that the initial kinetic energy of a rotating object is equal to its final kinetic energy, given that no external torques or forces act on the system. This equality of initial and final rotational kinetic energy is a fundamental concept in the study of rotational motion and dynamics.
Flywheel: A flywheel is a rotating mechanical device designed to store rotational energy. It helps maintain a constant angular velocity by resisting changes in rotational speed due to its high moment of inertia.
Helicopter: A helicopter is a type of rotorcraft in which lift and thrust are supplied by horizontally-spinning rotors. It can take off, land vertically, and hover due to its rotating blades.
I = ∑mr²: The term I = ∑mr² represents the moment of inertia, a fundamental concept in rotational dynamics that describes an object's resistance to changes in its rotational motion. It is a measure of an object's distribution of mass around its axis of rotation and is a crucial factor in determining the rotational kinetic energy of a system.
I = ∫ r²dm: The integral expression I = ∫ r²dm represents the moment of inertia, a fundamental concept in rotational dynamics that describes the distribution of mass in a rotating object. This term is crucial in understanding the rotational kinetic energy of a system and its response to applied torques.
I = mr²: I = mr² is a formula that represents the moment of inertia, a fundamental concept in rotational dynamics. Moment of inertia is a measure of an object's resistance to changes in its rotational motion, and it plays a crucial role in understanding rotational kinetic energy and the dynamics of rotating systems.
I_{CM}: I_{CM} is the moment of inertia of a system of particles about its center of mass. It represents the rotational inertia of an object or system about an axis passing through its center of mass, which is a crucial concept in understanding rotational dynamics and energy.
KE = ½Iω²: KE = ½Iω² is the formula for calculating the rotational kinetic energy of a rigid body rotating around a fixed axis. The term represents the relationship between the moment of inertia (I), the angular velocity (ω), and the kinetic energy (KE) of the rotating object.
Kg·m²: kg·m² is a unit of moment of inertia, which is a measure of an object's resistance to rotational acceleration. It represents the product of an object's mass and the square of its distance from the axis of rotation. This unit is crucial in understanding the dynamics of rotational motion and the conservation of angular momentum.
Moment of inertia: Moment of inertia is a measure of an object's resistance to changes in its rotational motion about a fixed axis. It depends on the mass distribution relative to the axis of rotation.
Moment of Inertia: The moment of inertia is a measure of an object's resistance to rotational acceleration. It is a scalar quantity that depends on the mass and distribution of an object's mass about a given axis of rotation. The moment of inertia is a crucial concept in the study of rotational dynamics, as it determines how an object will respond to applied torques.
Parallel Axis Theorem: The parallel axis theorem is a fundamental principle in rotational dynamics that relates the moment of inertia of an object about any arbitrary axis to its moment of inertia about a parallel axis passing through the object's center of mass. This theorem is crucial in understanding the rotational motion and energy of rigid bodies.
Point Mass: A point mass is an idealized object that has mass concentrated at a single point in space, with no physical size or volume. It is a fundamental concept in classical mechanics that simplifies the analysis of objects by treating them as dimensionless particles.
Rad/s: Radians per second (rad/s) is a unit of angular velocity, which measures the rate of change of an object's angular position over time. It is a fundamental unit in the study of rotational motion and is used to quantify the speed of rotating or spinning objects.
Radius of Gyration: The radius of gyration is a measure of the distribution of mass within an object about a specific axis of rotation. It is a fundamental concept in the study of rotational dynamics and is used to calculate the moment of inertia of an object, which is a crucial factor in determining the object's rotational kinetic energy and its response to applied torques.
Rigid Body Rotation: Rigid body rotation refers to the rotational motion of an object where all the particles within the object move in circular paths around a common axis, maintaining their relative positions to one another. This concept is fundamental in understanding the dynamics of rotational motion and its associated properties.
Rotational Acceleration: Rotational acceleration is the rate of change of angular velocity of a rotating object. It describes how quickly the speed of rotation is increasing or decreasing over time. Rotational acceleration is a crucial concept in understanding the dynamics of rotating systems and their associated kinetic energy.
Rotational Dynamics: Rotational dynamics is the study of the motion of objects that are rotating or spinning around an axis. It involves the analysis of the forces and torques that act on a rotating body, and how these influence the object's rotational motion and energy.
Rotational Inertia Apparatus: A rotational inertia apparatus is a device used to measure the moment of inertia of an object. It allows for the experimental determination of an object's rotational kinetic energy by providing a way to observe and quantify the object's resistance to changes in its rotational motion.
Rotational kinetic energy: Rotational kinetic energy is the energy an object possesses due to its rotation. It is given by $$KE_{rot} = \frac{1}{2} I \omega^2$$, where $I$ is the moment of inertia and $\omega$ is the angular velocity.
Rotational Kinetic Energy: Rotational kinetic energy, denoted as KE_{rot}, is the energy possessed by an object due to its rotational motion. It is calculated using the formula KE_{rot} = ½Iω², where I is the moment of inertia and ω is the angular velocity of the object.
Steiner: Steiner's theorem, also known as the parallel axis theorem, is a fundamental principle in the study of rotational dynamics and moments of inertia. It provides a method for calculating the moment of inertia of an object about any arbitrary axis by relating it to the moment of inertia about the object's center of mass.
Torque: Torque is a measure of the rotational force applied to an object, which causes it to rotate about an axis. It is influenced by the magnitude of the force applied, the distance from the axis of rotation, and the angle at which the force is applied, making it crucial for understanding rotational motion and equilibrium.
W_{nc}: W_{nc} represents the non-conservative work done on a system during rotational motion. It is a term that is important in the context of understanding moment of inertia and rotational kinetic energy, as it accounts for the work done by external forces that are not aligned with the axis of rotation.
Work-energy theorem: The work-energy theorem states that the net work done on an object is equal to its change in kinetic energy. Mathematically, it is expressed as $W_{net} = \Delta KE$.
Work-Energy Theorem: The work-energy theorem is a fundamental principle in physics that states the change in the kinetic energy of an object is equal to the net work done on that object. It establishes a direct relationship between the work performed on an object and the resulting change in its kinetic energy, providing a powerful tool for analyzing and solving problems involving energy transformations.
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