What happens when a weight is moved closer to the fulcrum of a uniformly balanced lever at an equilibrium point?

The amount of torque required to balance decreases as the weight moves closer to the fulcrum.

The lever arm's moment of inertia increases, resulting in a decrease in torque required.

The speed at which equilibrium is reached increases.

The weight's effective mass increases, causing an increase in torque required.

A solid disk is spinning freely at an angular velocity ω around a fixed axis; what would happen to its angular velocity if half of its mass were suddenly distributed closer to its rotation axis without adding or removing any mass?

The angular velocity would increase.

The angular velocity would decrease.

The angular velocity would remain unchanged.

Which condition must be met for an object to be in translational equilibrium?

Net force acting on the object is zero.

Net torque acting on the object is zero.

The object moves with constant velocity.

What must happen to the net external torque acting on a stationary object for it to begin rotating?

Net external torque must be applied for the stationary object to begin rotating.

Net external torque needs to remain constant for motion to initiate.

Incorrect spellings or grammatical errors appear in answer choices rather than providing factually wrong options?

How might a hypothetical reduction in the value of Planck's constant affect angular momentum quantization for particles with mass similar to electrons but bound within rigid bodies?

It could result in smaller discrete values of angular momentum, affecting stability and energy states within rotational systems.

Angular momentum quantization would become continuous, eliminating discrete energy levels in such systems.

There would be no effect because angular momentum quantization is not relevant for macroscopic rigid bodies' rotational dynamics.

Larger quantum numbers might be necessary for describing stable rotational states due to expanded spacing between energy levels.

What effect does doubling both diameter and density have on torsional rigidity (stiffness) for cylindrical objects assuming material properties remain constant?

The stiffness increases by a factor of sixteen because torsional rigidity depends directly on polar moment area which changes with fourth power diameter change while density affects overall inertia proportionally without change stiffness itself but combined effect increases rigidity significantly due square-cube law enhancing resistance deformation under torque application.

No change because changing dimension density simultaneously has cancelling out effects keeping torsional rigidity same overall balance between structural geometry material composition maintained.

Halves because increasing diameter reduces ability resist twisting due increased leverage points further away axis rotation despite higher overall weight contributing additional inertial factors counteracting potential gains stiffness provided added bulk.

What happens to torque when you triple only the force applied perpendicularly at a pivot point but keep distance constant?

The torque becomes nine times greater.

The torque increases by one third.

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5.1 Torque and Rotational Statics

5 min read•december 31, 2022

Daniella Garcia-Loos

Torque & Rotational Statics

Torque is the rotational analog of force, which is what causes an object to rotate around its center of mass. It's units are (kgm^2)/(s^2)or N*m.

Torque(T) is the cross product of the radius(r) and the force(F) applied at that radius, which in equation form is:

In which r, F, and T are vectors!

Here's an image of an application of torque:

Taken from Lumen Learning

First Condition of Equilibrium: This condition is about static and dynamic equilibrium in which the object either has a 0 or constant velocity and the acceleration is 0, meaning the net force is zero.

Second Condition of Equilibrium: This condition states that the sum of the net torques is 0 and the angular acceleration is 0.

Both of these conditions must be satisfied in order for an object/system to be in equilibrium!

Here are some key things to remember about torque and rotational statics:

Torque is a measure of the rotational force applied to an object. It is defined as the product of the force applied to an object and the lever arm (the distance from the point of application of the force to the axis of rotation).
Torque is a vector quantity, with both magnitude and direction. The direction of the torque is perpendicular to the plane defined by the force and the lever arm.
Torque is measured in newton-meters (N*m).
The net torque acting on an object is the sum of all the torques acting on the object. The net torque determines the rotational acceleration of the object.
Rotational statics is the study of objects that are in rotational equilibrium. This means that the net torque acting on the object is zero, and the object is not accelerating.
To achieve rotational equilibrium, the torques acting on an object must balance out. This means that the clockwise torques must equal the counterclockwise torques.
In rotational equilibrium, the sum of the forces acting on an object is not necessarily zero. The forces can still be in balance even if the torques are not.

Moment of Inertia

Rotational Inertia(I) or Moment of Inertia is essentially an object's resistance to changes in its rotation. It is essentially the sum of all the tiny points of mass times the radius(r) squared of an object, in which the calculus definition for it is:

However, these derivations typically take a very long time and require a strong level of comfort in calculus, so AP doesn't usually make students derive them. Most of the time they will use one that is very common, like a rod, or they will give it to you in the question.

Here are some examples of the most commonly seen ones, take a look at the axis of rotation too!

Taken from OpenStax

Here are some key things to remember about rotational inertia:

Rotational inertia, also known as moment of inertia, is a measure of an object's resistance to rotational acceleration. It is a scalar quantity that depends on the mass of the object and the distribution of the mass around the axis of rotation.
The greater an object's moment of inertia, the more difficult it is to accelerate the object.
The moment of inertia of an object depends on the shape of the object and the location of the axis of rotation.
For a solid object with a uniform mass distribution, the moment of inertia is equal to the object's mass times the square of the distance from the axis of rotation to the object's center of mass.
For an object with a non-uniform mass distribution, the moment of inertia is equal to the sum of the moments of inertia of all the individual parts of the object.

Parallel Axis Theorem:

Sometimes, the axis of rotation isn't perfectly where we want it to be: at the center of mass. So we employ an awesome trick called parallel axis theorem!

In which I(new) is the rotational inertia of the object with the shifted axis, I(com) is the rotational inertia of the object with the axis at the center of mass (like the image above), m is mass, and h is the shift of the axis in meters.

Here is a step-by-step guide on how to apply the parallel axis theorem:

Identify the object or system that you want to analyze. This is the object or system for which you want to calculate the moment of inertia.
Draw a simple sketch of the object or system. You should include all relevant features of the object or system, such as its shape, size, and orientation.
Identify the axis of rotation. This is the line around which the object or system will rotate.
Identify the center of mass of the object or system. This is the point at which the mass of the object or system is evenly distributed.
Choose a reference point on the axis of rotation. This is the point where you want to calculate the moment of inertia.
Calculate the distance between the center of mass and the reference point. This is the distance r.
Calculate the moment of inertia of the object or system about its own center of mass using the appropriate formula for the shape of the object or system. This is the moment of inertia I_cm.
Use the parallel axis theorem to calculate the moment of inertia about the reference point: I = I_cm + M * r^2

Where I is the moment of inertia about the reference point, I_cm is the moment of inertia about the center of mass, M is the mass of the object or system, and r is the distance between the center of mass and the reference point.

Practice Questions

1) Two children push on opposite sides of a door during play. Both push horizontally and perpendicular to the door. One child pushes with a force of 17.5 N at a distance of 0.600 m from the hinges, and the second child pushes at a distance of 0.450 m. What force must the second child exert to keep the door from moving? Assume friction is negligible. (Taken from Lumen Learning)

Answer:

Taken from College Board

Answer:

Key Terms to Review (9)

Counterclockwise Torques

: Counterclockwise torques refer to the rotational forces that cause an object to rotate in a counterclockwise direction. They are applied perpendicular to the axis of rotation and can be caused by external forces or internal moments.

I(new)

: In the context of rotational motion, I(new) represents the moment of inertia of an object after a change in its mass distribution or shape.

Key Term: I(com)

: Definition: The moment of inertia about the center of mass (I(com)) is a measure of an object's resistance to rotational motion. It depends on both the mass distribution and shape of the object.

Newton-meters (N*m)

: Newton-meters, also known as joules, are the units used to measure torque or rotational force. It represents the amount of force applied at a distance from a pivot point.

Parallel Axis Theorem

: The parallel axis theorem states that for an object rotating about an axis parallel to but not passing through its center of mass, its moment of inertia can be calculated by adding together two components - one component being its moment of inertia about an axis through its center of mass, and another component based on its mass and distance from that axis.

Radius (r)

: The radius is the distance from the center of a circle or sphere to any point on its circumference or surface.

Second Condition of Equilibrium

: The second condition of equilibrium states that for an object to be in rotational equilibrium, the sum of the torques acting on it must be zero. In other words, the net torque acting on an object must be balanced.

Torque

: Torque is the measure of how effectively a force can cause an object to rotate. It depends on the magnitude of the force, the distance from the axis of rotation, and the angle between the force and lever arm.

Vector Quantity

: A vector quantity is a physical quantity that has both magnitude and direction. It can be represented by an arrow, where the length of the arrow represents the magnitude and the direction of the arrow represents the direction.

5.1 Torque and Rotational Statics

5 min read•december 31, 2022

Daniella Garcia-Loos

Torque & Rotational Statics

Torque is the rotational analog of force, which is what causes an object to rotate around its center of mass. It's units are (kgm^2)/(s^2)or N*m.

Torque(T) is the cross product of the radius(r) and the force(F) applied at that radius, which in equation form is:

In which r, F, and T are vectors!

Here's an image of an application of torque:

Taken from Lumen Learning

Second Condition of Equilibrium: This condition states that the sum of the net torques is 0 and the angular acceleration is 0.

Both of these conditions must be satisfied in order for an object/system to be in equilibrium!

Here are some key things to remember about torque and rotational statics:

Torque is a measure of the rotational force applied to an object. It is defined as the product of the force applied to an object and the lever arm (the distance from the point of application of the force to the axis of rotation).
Torque is a vector quantity, with both magnitude and direction. The direction of the torque is perpendicular to the plane defined by the force and the lever arm.
Torque is measured in newton-meters (N*m).
The net torque acting on an object is the sum of all the torques acting on the object. The net torque determines the rotational acceleration of the object.
Rotational statics is the study of objects that are in rotational equilibrium. This means that the net torque acting on the object is zero, and the object is not accelerating.
To achieve rotational equilibrium, the torques acting on an object must balance out. This means that the clockwise torques must equal the counterclockwise torques.
In rotational equilibrium, the sum of the forces acting on an object is not necessarily zero. The forces can still be in balance even if the torques are not.

Moment of Inertia

Here are some examples of the most commonly seen ones, take a look at the axis of rotation too!

Taken from OpenStax

Here are some key things to remember about rotational inertia:

Rotational inertia, also known as moment of inertia, is a measure of an object's resistance to rotational acceleration. It is a scalar quantity that depends on the mass of the object and the distribution of the mass around the axis of rotation.
The greater an object's moment of inertia, the more difficult it is to accelerate the object.
The moment of inertia of an object depends on the shape of the object and the location of the axis of rotation.
For a solid object with a uniform mass distribution, the moment of inertia is equal to the object's mass times the square of the distance from the axis of rotation to the object's center of mass.
For an object with a non-uniform mass distribution, the moment of inertia is equal to the sum of the moments of inertia of all the individual parts of the object.

Parallel Axis Theorem:

Sometimes, the axis of rotation isn't perfectly where we want it to be: at the center of mass. So we employ an awesome trick called parallel axis theorem!

Here is a step-by-step guide on how to apply the parallel axis theorem:

Identify the object or system that you want to analyze. This is the object or system for which you want to calculate the moment of inertia.
Draw a simple sketch of the object or system. You should include all relevant features of the object or system, such as its shape, size, and orientation.
Identify the axis of rotation. This is the line around which the object or system will rotate.
Identify the center of mass of the object or system. This is the point at which the mass of the object or system is evenly distributed.
Choose a reference point on the axis of rotation. This is the point where you want to calculate the moment of inertia.
Calculate the distance between the center of mass and the reference point. This is the distance r.
Calculate the moment of inertia of the object or system about its own center of mass using the appropriate formula for the shape of the object or system. This is the moment of inertia I_cm.
Use the parallel axis theorem to calculate the moment of inertia about the reference point: I = I_cm + M * r^2

Practice Questions

Answer:

Taken from College Board

Answer:

Key Terms to Review (9)

Counterclockwise Torques

I(new)

: In the context of rotational motion, I(new) represents the moment of inertia of an object after a change in its mass distribution or shape.

Key Term: I(com)

: Definition: The moment of inertia about the center of mass (I(com)) is a measure of an object's resistance to rotational motion. It depends on both the mass distribution and shape of the object.

Newton-meters (N*m)

: Newton-meters, also known as joules, are the units used to measure torque or rotational force. It represents the amount of force applied at a distance from a pivot point.

Parallel Axis Theorem

Radius (r)

: The radius is the distance from the center of a circle or sphere to any point on its circumference or surface.

Second Condition of Equilibrium

Torque

Vector Quantity