Magnetic Fields from Currents

Overview

A key idea in electromagnetism is that electric current produces magnetic fields. Since current is moving charge, any conductor carrying current creates a magnetic field around it.

The shape and strength of the field depend on:

• conductor geometry
• current $I$
• distance from conductor
• number of turns for coils
• presence of magnetic core for solenoids

This page deepens the current-produced fields introduced in Magnetic Fields.

Definition

A current-produced magnetic field is the magnetic field generated by moving charges in a conductor.

Different current paths produce different field patterns.

Why It Matters

This is the foundation for:

• electromagnets
• motors
• relays
• transformers
• later magnetic-force and electromagnetic-induction topics

Core Physical Idea

Charges in motion generate magnetic fields.

Hence:

• straight wire current gives a circular field
• circular coil current gives a concentrated central field
• many loops combined give a strong solenoid field

Key Representations

Right-Hand Grip Rule

This rule determines magnetic field direction around conventional current.

Straight Wire

• thumb points in direction of current
• curled fingers show direction of magnetic field lines

Coil or Solenoid

• fingers curl in direction of current around the coil
• thumb points to:
  • internal magnetic field direction
  • North pole of the solenoid

Magnetic Field Around a Long Straight Wire

Field Pattern

The field lines are concentric circles centred on the wire.

• strongest near the wire
• weaker further away

The field is non-uniform.

Figure: Magnetic field around a straight current-carrying wire.

Magnitude

$$B=\frac{{\mu }_{0}I}{2\pi r}$$

where:

• $I$ = current
• $r$ = perpendicular distance from wire
• ${\mu }_0$ = permeability of free space

Trends

If current doubles, $B$ doubles.

If distance doubles, $B$ halves.

Notes

Distance must be measured perpendicularly from the wire.

Straight Wire Examples

Current Upward

Viewed from above:

• field circles anticlockwise

Current Downward

• field circles clockwise

Figure: Three-dimensional view of the magnetic field around a straight current-carrying wire.

Magnetic Field Around a Circular Coil

Field Pattern

Each part of the wire contributes magnetic field at the centre.

These combine to produce a stronger resultant field through the centre.

The pattern resembles a short bar magnet.

Figure: Magnetic field pattern around a circular current-carrying wire, showing a concentrated field through the centre.

Magnitude at Centre

$$B=\frac{{\mu }_{0}NI}{2r}$$

where:

• $N$ = number of turns
• $I$ = current
• $r$ = radius

Trends

Increase $B$ by:

• increasing current
• increasing number of turns
• decreasing radius

Why Coils Strengthen Fields

A single wire loop creates field contributions that reinforce one another at the centre.

More turns means more reinforcing contributions.

Hence coils are much more useful than single wires for producing strong fields.

Magnetic Field of a Solenoid

A solenoid is a long helical coil carrying current.

Detailed applications: Solenoids and Electromagnets

Field Pattern

Inside Solenoid

• nearly parallel field lines
• nearly equal spacing
• approximately uniform field

Outside Solenoid

• weak returning field lines
• resembles bar magnet external field

Figure: Magnetic field pattern of a solenoid, with a strong nearly uniform field inside and weaker returning field lines outside.

Magnitude for a Long Solenoid

$$B={\mu }_{0}nI$$

where:

• $n$ = turns per unit length
• $I$ = current

Solenoid Trends

Increase field strength by:

• increasing current
• increasing turns per unit length
• using a soft iron core

Why Solenoid Field Is Strong

Each loop contributes field in the same internal direction.

These contributions add strongly inside the solenoid.

Outside, many contributions partially cancel.

Comparing Field Patterns

Straight Wire

• concentric circles
• non-uniform
• strongest near wire

Circular Coil

• concentrated centre field
• bar-magnet-like pattern

Long Solenoid

• strong uniform internal field
• weak external field

Relative Field Strength Logic

Use line spacing qualitatively.

Closer lines indicate stronger field.

Examples

Straight Wire

Closer to the wire means stronger field.

Solenoid

The inside centre region is stronger than the outside.

Coil

The centre is stronger than a distant external region.

Multiple Current-Carrying Conductors

If two or more conductors produce fields at one point:

• fields combine by vector addition

Use Vectors.

This becomes important in later force topics.

Short Worked Examples

Example 1

A wire current is doubled while distance remains constant.

Since:

$$B\propto I$$

the field doubles.

Example 2

A point moves from distance $r$ to $2r$ from a wire.

Since:

$$B\propto \frac{1}{r}$$

the field halves.

Example 3

Two identical coils, but one has twice the number of turns.

The second coil has twice the field at the centre.

Common Mistakes

1. Using the wrong hand rule
2. Using the wrong distance from a wire
3. Assuming the outside solenoid field is zero
4. Mixing coil and solenoid formulae
5. Ignoring number of turns

Summary

Straight Wire

$$B=\frac{{\mu }_{0}I}{2\pi r}$$

Circular field lines.

Circular Coil

$$B=\frac{{\mu }_{0}NI}{2r}$$

Strong centre field.

Long Solenoid

$$B={\mu }_{0}nI$$

Strong approximately uniform internal field.

General Rule

More current and more aligned turns give stronger magnetic fields.

Links

• Magnetic Fields
• Solenoids and Electromagnets
• Magnetic Fields Common Exam Traps
• Magnetic Force
• Current Electricity Fundamentals
• Vectors