Work - classical-mechanics

Definition of Work

Mechanical Work

Work: energy transfer via force acting through displacement. Requires force component along displacement vector. Scalar quantity. Sign indicates energy direction.

Physical Interpretation

Work quantifies how force changes kinetic or potential energy in a system. No displacement or perpendicular force yields zero work.

Historical Context

Concept developed in 19th century physics by Coriolis and others. Foundation for energy conservation principles.

Mathematical Formula

Basic Equation

Work (W) = Force (F) × Displacement (d) × cos(θ), where θ is angle between force and displacement vectors.

Vector Representation

W = \(\vec{F} \cdot \vec{d}\) (dot product). Only component of force parallel to displacement contributes.

Formula Explanation

Cosine factor projects force onto displacement axis. Zero work if force perpendicular (θ = 90°).

W = F d cos(θ)where:F = magnitude of force (N)d = magnitude of displacement (m)θ = angle between force and displacement

Units of Work

SI Unit

Joule (J): 1 J = 1 Newton × 1 meter = 1 N·m.

Derived Units

1 J = 1 kg·m²/s². Work shares units with energy.

Other Units

Erg (CGS): 1 erg = 10⁻⁷ J. Foot-pound (Imperial): 1 ft·lb ≈ 1.356 J.

Unit	Symbol	Equivalent in Joules
Joule	J	1 J
Erg	erg	1 × 10⁻⁷ J
Foot-pound	ft·lb	1.356 J

Positive and Negative Work

Positive Work

Force component and displacement same direction (0° ≤ θ < 90°). Energy added to system.

Negative Work

Force opposes displacement (90° < θ ≤ 180°). Energy removed from system.

Zero Work

Force perpendicular to displacement (θ = 90°) or no displacement. No energy transfer.

If:θ < 90°, W > 0 (energy input)θ = 90°, W = 0 (no work)θ > 90°, W < 0 (energy output)

Work Done by Variable Force

Non-constant Force

Force magnitude/direction changes during displacement. Requires calculus integration.

Integral Form

W = ∫ \(\vec{F} \cdot d\vec{r}\) over path from initial to final position.

Application

Used for springs, friction, gravitational fields with variable force.

W = ∫ from r₁ to r₂ F(r) · drwhere:F(r) = position-dependent force vectordr = infinitesimal displacement vector

Work-Energy Theorem

Theorem Statement

Net work done on an object equals change in its kinetic energy: W_net = ΔK.

Mathematical Expression

W_net = K_final − K_initial = ½ m v_f² − ½ m v_i².

Significance

Connects force-displacement analysis to energy perspective. Foundation for dynamics.

Conservative and Non-Conservative Forces

Conservative Forces

Work independent of path. Examples: gravity, spring force. Potential energy defined.

Non-Conservative Forces

Work depends on path. Examples: friction, air resistance. Energy dissipated as heat.

Energy Conservation

Conservative forces conserve mechanical energy. Non-conservative forces cause energy loss.

Force Type	Work Dependence	Energy Implication
Conservative	Path-independent	Mechanical energy conserved
Non-Conservative	Path-dependent	Energy dissipated

Power and Its Relation to Work

Power Definition

Power: rate of doing work. P = dW/dt.

Average and Instantaneous Power

Average: W/Δt. Instantaneous: derivative of work with respect to time.

Units

Watt (W): 1 W = 1 J/s. Common for engines and machines.

P = dW/dtUnits: Watt (W) = Joule/second (J/s)

Work in Rotational Motion

Rotational Work Formula

W = τ θ, where τ is torque, θ angular displacement (radians).

Relation to Angular Variables

Torque analogous to force; angular displacement analogous to linear displacement.

Units

Joule is unit for rotational work. Torque in N·m, angular displacement in radians.

W = τ θwhere:τ = torque (N·m)θ = angular displacement (rad)

Worked Examples

Example 1: Horizontal Force

Force 10 N applied horizontally displacing object 5 m. θ=0°.

W = 10 × 5 × cos 0° = 50 J.

Example 2: Inclined Force

Force 20 N at 60° to displacement 3 m.

W = 20 × 3 × cos 60° = 20 × 3 × 0.5 = 30 J.

Example 3: Variable Force (Spring)

Spring constant k=200 N/m, compressed 0.1 m.

W = ½ k x² = 0.5 × 200 × (0.1)² = 1 J.

Common Misconceptions

Work and Force Always Positive

Incorrect: work can be negative or zero depending on force direction.

Work Done Without Displacement

Incorrect: no displacement means no work done regardless of force magnitude.

Work is a Vector Quantity

Incorrect: work is scalar; direction encoded in sign but no vector direction.

References

Halliday, D., Resnick, R., & Walker, J., Fundamentals of Physics, Wiley, 10th ed., 2013, pp. 120-145.
Tipler, P. A., & Mosca, G., Physics for Scientists and Engineers, W. H. Freeman, 6th ed., 2007, pp. 200-225.
Serway, R. A., & Jewett, J. W., Physics for Scientists and Engineers, Cengage Learning, 9th ed., 2014, pp. 150-180.
Giancoli, D. C., Physics: Principles with Applications, Pearson, 7th ed., 2013, pp. 130-160.
Young, H. D., & Freedman, R. A., University Physics with Modern Physics, Pearson, 14th ed., 2015, pp. 160-190.