Definition Of Work (3.2) - Theme A: Space, Time and Motion - IB 11 Physics
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Definition of Work

Definition of Work

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Interactive Audio Lesson

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Work Done by a Constant Force

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Teacher
Teacher Instructor

Today, we're going to discuss the definition of work in physics. Work is done when a force moves an object across a distance. Can someone tell me what the formula for work is?

Student 1
Student 1

Is it W equals force times displacement?

Teacher
Teacher Instructor

Close! The formula is W = F Β· Ξ”r, where F is the force applied and Ξ”r is the displacement. Remember, W stands for work, and it's a scalar quantity.

Student 2
Student 2

What does it mean when you say work is a scalar quantity?

Teacher
Teacher Instructor

Great question! Unlike vector quantities like force, which have both magnitude and direction, work only has magnitude. This leads us to consider the angle between the force and displacement. If the angle is 0 to 90 degrees, work is positive. Can anyone explain what happens when the angle is 90 degrees?

Student 3
Student 3

That's when the work done is zero, right?

Teacher
Teacher Instructor

Exactly! If the force is perpendicular to the direction of motion, no work is done. So, keep in mind these anglesβ€”use the mnemonic 'Work is Done When You Run' for easy recall.

Student 4
Student 4

What about when the force opposes motion?

Teacher
Teacher Instructor

Good point! That’s when work is negative, which occurs between angles of 90 and 180 degrees. Essentially, if the force acts against the displacement, it reduces the object's energy.

Teacher
Teacher Instructor

In summary, we've learned that work depends on both the force applied, the displacement, and their angle. Remember, work can be positive, negative, or zero based on these factors.

Work Done by a Variable Force

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Teacher
Teacher Instructor

Now, let’s discuss work done by a variable force. When forces change along a path, how can we calculate work done?

Student 1
Student 1

Do we just use the same formula as before?

Teacher
Teacher Instructor

Not quite! For variable forces, we look at infinitesimal work, dW. The formula is dW = F(x) Β· dr, meaning we need to integrate to find total work.

Student 2
Student 2

Could you give us an example where we’d use integration?

Teacher
Teacher Instructor

Of course! A common example is the work done by a spring, which follows Hooke's Law: F(x) = -kx. Here, we can set up the integral for work done from an initial to a final displacement.

Student 3
Student 3

So the total work done by a spring is W = ∫(-kx) dx?

Teacher
Teacher Instructor

That's right! When you integrate that from x_initial to x_final, you find the work W_spring = -1/2 k (x_final^2 - x_initial^2).

Student 4
Student 4

This sounds a bit complicated, but I can see how it works now. It’s all about understanding what forces are acting.

Teacher
Teacher Instructor

Exactly! Understanding the forces is crucial. It’s also helpful to visualize it graphically. The area under the force vs. displacement graph gives us the work done.

Teacher
Teacher Instructor

To summarize, for variable forces, we use integration to calculate total work, often seen with systems like springs. Knowing the relationship between force and displacement is key.

Applications of Work

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Teacher
Teacher Instructor

Let's connect work to energy. How does the work done on an object relate to its energy?

Student 1
Student 1

I think it’s like if you do work on an object, you give it energy, right?

Teacher
Teacher Instructor

Correct! The work-energy theorem tells us that the work done on an object equals its change in kinetic energy: W_net = Ξ”K.

Student 2
Student 2

Does this apply to potential energy too?

Teacher
Teacher Instructor

Great question! Absolutely, work done against gravity or any conservative force changes potential energy as well. We often see this in raised objects.

Student 3
Student 3

Can we have an equation for potential energy like we do for kinetic?

Teacher
Teacher Instructor

Yes! Near Earth's surface, this is U_g = mgh. When an object is lifted, work must be done against gravity, which converts to gravitational potential energy.

Student 4
Student 4

So both kinetic and potential energy are forms of energy connected by work done?

Teacher
Teacher Instructor

Exactly! Work is the bridge between forces and energy forms. Remember: energy can be transformed, but the total energy remains conserved in a closed system.

Teacher
Teacher Instructor

In conclusion, we have seen how work relates to energy, emphasizing the critical role work plays in both kinetic and potential energy changes.

Introduction & Overview

Read summaries of the section's main ideas at different levels of detail.

Quick Overview

Work is defined as the product of force and displacement in the direction of the force, and it can be positive, negative, or zero depending on the angle between the force and displacement.

Standard

The section elaborates on the definition of work in physics, describing it as the scalar product of force and displacement. It explains under which conditions work is positive, negative, or zero, and introduces work done by variable forces, emphasizing the importance of this concept in relating forces to energy changes.

Detailed

In the physics context, work (W) is defined as the measure of energy transfer that happens when an object is moved over a distance by an external force. Mathematically, work is expressed as the scalar product of the force applied () and displacement (), denoted as W =  3 . The angle (BC) between the force and displacement vectors is crucial in determining the nature of work done. Positive work occurs when the angle is between 0 and 90 degrees, indicating the force contributes to the displacement. Negative work occurs when the angle is between 90 and 180 degrees, indicating that the force opposes the displacement. Zero work arises when the angle is 90 degrees, meaning the force is perpendicular to the motion. The section also discusses the calculation of work done by variable forces and includes an example related to spring forces, reinforcing the understanding of work in energy transfer contexts.

Audio Book

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Work Done by a Constant Force

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Chapter Content

If a constant force F⃗\vec{F}F acts on an object and the object moves a displacement Δr⃗\Delta \vec{r}Δr, the work WWW done by the force is the scalar product of force and displacement:

W=F⃗⋅Δr⃗=F Δr cos ϕ, W = \vec{F} \cdot \Delta \vec{r} = F\,\Delta r\,\cos\phi,
W=Fβ‹…Ξ”r=FΞ”rcosΟ•,
where ϕ\phiϕ is the angle between F⃗\vec{F}F and Δr⃗\Delta \vec{r}Δr.

Detailed Explanation

In physics, work is defined as the energy transferred to or from an object through force acting over a distance. When a force moves an object through a distance, we calculate work using the formula: W = F * Ξ”r * cos(Ο•). Here, W is the work done, F is the magnitude of the force, Ξ”r is the magnitude of the displacement, and Ο• is the angle between the force and the direction of the displacement.
- If the force is in the same direction as the displacement (Ο• = 0Β°), all the force does work on the object, resulting in positive work.
- If the force is opposite to the direction of movement (Ο• = 180Β°), the work is negative, meaning the force is acting against the movement.
- If the force is perpendicular to the displacement (Ο• = 90Β°), no work is done because the force does not contribute to displacement in that direction.

Examples & Analogies

Imagine pushing a car on a flat road. If you apply a force while pushing straight in the direction the car is supposed to move, you do positive work on it. In contrast, if you push against the car while it is rolling downhill, you’re doing negative work since you're trying to stop its motion. Finally, if you apply a force vertically while the car moves horizontally, you don’t contribute to its motion in the direction it is moving, resulting in zero work done.

Types of Work Based on Angle

Chapter 2 of 3

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Chapter Content

Positive work when 0βˆ˜β‰€Ο•<90∘0^\circ \le \phi < 90^\circ0βˆ˜β‰€Ο•<90∘ (force has a component along displacement).

Negative work when 90∘<ϕ≀180∘90^\circ < \phi \le 180^\circ90∘<ϕ≀180∘ (force opposes motion).

Zero work if force is perpendicular to displacement (Ο•=90∘\phi = 90^\circΟ•=90∘).

Detailed Explanation

The work done by a force can be characterized by the angle at which the force is applied relative to the direction of displacement.
- Positive Work: When the force has a component in the direction of displacement (0Β° ≀ Ο• < 90Β°), work is positive. This situation means that the force is aiding the motion.
- Negative Work: When the angle is between 90Β° and 180Β° (90Β° < Ο• ≀ 180Β°), the work done is negative, indicating that the force opposes the motion.
- Zero Work: If the force is applied at a right angle to the direction of motion (Ο• = 90Β°), no work is done since there is no displacement in the direction of the force.

Examples & Analogies

Think of carrying a heavy backpack while walking. The force of gravity is acting downwards (perpendicular to the direction you're walking), so even though you're exerting force, you're doing no work against the gravitational force while moving forward. However, if you were to lift the backpack upward as you walk, the work being done against gravity becomes positive. Conversely, if you were to push against the backpack backwards while walking, you would be doing negative work.

Work Done by a Variable Force

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Chapter Content

If F⃗(x)\vec{F}(x)F(x) varies along the path, then the infinitesimal work dWdWdW is:
dW=F⃗(x)⋅dr⃗. dW = \vec{F}(x) \cdot d\vec{r}.dW=F(x)⋅dr.

Total work from xix_ixi to xfx_fxf:
W=∫xixfF(x) cos Ο• dx. W = \int_{x_i}^{x_f} F(x)\,\cos\phi\,dx.
W=∫xi xf F(x)cosΟ•dx.

Detailed Explanation

When a force acting on an object changes as the object moves, we can express the work done as an integral. The infinitesimal work, represented as dW, is calculated by the dot product of the varying force vector and the differential displacement vector: dW = F(x) β‹… dr. To find the total work done over a specific path where the force changes, we integrate this expression across the limits of the displacement from xi to xf, resulting in: W = ∫(xi to xf) F(x) cos(Ο•) dx. Here, we evaluate how the force applied at different points along the path affects the total work done.

Examples & Analogies

Consider compressing a spring. As you compress it, the force you need to apply increases due to Hooke's Law (F = -kx), where k is the spring constant. At the beginning of the compression, it may take less force, but as it gets compressed more, the required force increases. To find the total work done as you compress the spring from its relaxed position (xi) to the fully compressed position (xf), you would need to integrate the varying amount of force applied over the distance compressed.

Key Concepts

  • Work is done when a force moves an object across a distance.

  • Work can be positive, negative, or zero depending on the direction of the force related to displacement.

  • Calculating work for variable forces often involves integration.

  • The work-energy theorem connects work done by forces to changes in kinetic energy.

Examples & Applications

A person pushing a box across the floor demonstrates positive work, as the force applied assists with displacement.

When friction acts on a sliding object, it does negative work, reducing the object's kinetic energy.

Lifting a weight against gravity involves doing positive work and converting this energy into gravitational potential energy.

Memory Aids

Interactive tools to help you remember key concepts

🎡

Rhymes

For work done, it’s force and move, with angles right to make the groove.

πŸ“–

Stories

Imagine a runner pushing a boulder uphill. The more they push in the right direction (0Β°), the more they work! If they slip sideways (90Β°), their effort has no work.

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Memory Tools

Use the acronym 'POSITIVE' to remember that Positive Work occurs when Work is in the Same direction (angle 0Β°).

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Acronyms

Remember 'W = FΒ·Ξ”r' stands for Work equals Force times Displacement.

Flash Cards

Glossary

Work

The energy transferred when a force moves an object over a distance.

Scalar Product

The product of two vectors that gives a scalar result, used in calculating work (W = FΒ·Ξ”r).

Displacement

The change in position of an object, described as a vector quantity.

Force

Any interaction that can change the motion of an object.

Positive Work

Work done when the force has a component in the direction of displacement (0Β° ≀ Ο† < 90Β°).

Negative Work

Work done when the force opposes the direction of displacement (90Β° < Ο† ≀ 180Β°).

Zero Work

Work done when the angle between force and displacement is 90Β°, meaning force is perpendicular to motion.

Variable Force

A force that changes in magnitude or direction along the path of motion.

Integrate

To calculate the total work when dealing with variable forces by summation over infinitesimal increments.

Hooke's Law

The principle stating that the force exerted by a spring is proportional to the displacement from its equilibrium position.

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