Task Sets: Electric Field - OpenStax Physics (High School)

A

Warm-Up: Prerequisite Review

These questions review concepts needed for this section.

1.

Coulomb's Law gives the force between two specific charges. What is the electric field concept designed to describe?

A.

The same thing as Coulomb's force — they are identical.

B.

The influence of a source charge on the space around it, independent of what test charge is placed there.

C.

The force between two charges when one of them is very small.

D.

The total force on all charges in a region.

2.

A $+5 \times 10^{-6}$ C charge is located at the origin. What is the magnitude of the electric field at a distance of 0.30 m from this charge? Express your answer in N/C to two significant figures.

3.

The electric field at a point due to a positive source charge points —

A.

toward the source charge

B.

away from the source charge

C.

perpendicular to the line connecting source to that point

D.

in the direction of the nearest negative charge

B

Fluency Practice

Use $k = 9 \times 10^9$ N·m²/C². Show your work on calculation problems.

C

Mixed Practice

These problems apply electric field concepts in varied formats.

D

Application Problems

Read each scenario carefully. Show your work on calculations.

1.

A point charge of $q = +6.0 \times 10^{-9}$ C is fixed at the origin. A small test charge of $q_0 = -3.0 \times 10^{-9}$ C is placed at a distance of $r = 0.20$ m from the source charge.

1.

What is the magnitude of the electric field at the location of the test charge (due to the source charge only)? Express your answer in N/C to two significant figures.

2.

What is the magnitude of the electric force on the test charge? Express your answer in newtons to two significant figures.

2.

Two parallel metal plates create a uniform electric field of $E = 500$ N/C pointing from the top plate (positive) to the bottom plate (negative). An electron (charge $-e = -1.6 \times 10^{-19}$ C) is released from rest between the plates.

In which direction does the electron accelerate?

A.

Downward — toward the negative plate, in the direction of the field

B.

Upward — toward the positive plate, opposite to the field direction

C.

No acceleration — the electron is neutral between plates

D.

Horizontal — perpendicular to the field

3.

An electric field of $E = 8.0 \times 10^3$ N/C points horizontally to the right. A particle with charge $q = -5.0 \times 10^{-6}$ C is placed in this field.

What is the magnitude of the force on the particle? Express your answer in newtons.

E

Find the Mistake

Each problem shows incorrect reasoning. Identify the error.

1.

A student writes: "The electric field at a point is $E = 500$ N/C. This means there must be a test charge of 1 C at that point experiencing 500 N of force."

What is the conceptual error in this statement?

A.

The units of the electric field are wrong — it should be N·m/C, not N/C.

B.

The electric field exists at the point regardless of whether a test charge is there. The field is a property of space; the force only appears when a charge is actually present.

C.

The student is correct — a field always implies a specific force on a 1 C charge.

D.

The electric field cannot be stated without knowing the distance from the source.

2.

A student looks at a field line diagram for a single positive charge and says: "The field lines show the path the positive charge will travel — it will spiral outward from itself."

What is wrong with the student's interpretation of field lines?

A.

Field lines for a positive charge should spiral inward, not outward.

B.

Field lines show the direction of force on a positive test charge at each point in space, not the motion of the source charge.

C.

The student is correct — a free charge would follow the field line pattern.

D.

Field lines never spiral — they are always straight for isolated charges.

F

Challenge Problem

This bonus problem requires multi-step reasoning.

1.

Two point charges are on a line: $q_1 = +4.0 \times 10^{-9}$ C at $x = 0$ and $q_2 = -4.0 \times 10^{-9}$ C at $x = 0.10$ m. Find the magnitude of the net electric field at the midpoint ( $x = 0.05$ m).