---
title: "Cross Product — AP Physics C: E&M Definition & Exam Guide"
description: "The cross product gives a vector perpendicular to two inputs with magnitude |A||B|sinθ. It powers F = qv×B and every right-hand-rule question in Unit 12."
canonical: "https://fiveable.me/ap-physics-c-e-m/key-terms/cross-product"
type: "key-term"
subject: "AP Physics C: E&M"
unit: "Unit 12"
---

# Cross Product — AP Physics C: E&M Definition & Exam Guide

## Definition

The cross product A × B is a vector operation that outputs a vector perpendicular to both A and B, with magnitude |A||B|sinθ and direction given by the right-hand rule; in AP Physics C: E&M it determines the magnitude and direction of the magnetic force in F = qv × B.

## What It Is

The cross product takes two vectors and produces a third vector that's [perpendicular](/ap-physics-c-e-m/unit-12/2-magnetism-and-moving-charges/study-guide/aujVCr641dSEbfts "fv-autolink") to both. Its magnitude is |A||B|sinθ, where θ is the angle between the inputs, and its direction comes from the [right-hand rule](/ap-physics-c-e-m/key-terms/right-hand-rule "fv-autolink") (point your fingers along A, curl toward B, and your thumb points along A × B).

In E&M, this isn't abstract math. It's the machinery behind magnetism. The magnetic force on a moving [charge](/ap-physics-c-e-m/unit-10/2-redistribution-of-charge-between-conductors/study-guide/3zelmsMupFfJh7VP "fv-autolink") is F = qv × B, which means the force is always perpendicular to both the velocity and the field. That single geometric fact explains why magnetic forces do no work, why charged particles spiral in circles instead of speeding up, and why you'll be twisting your right hand around on test day. Two quick consequences worth memorizing now. If v is parallel to B, sinθ = 0 and the force vanishes. The cross product is also anti-commutative, so B × v = −(v × B), and flipping the order flips the direction.

## Why It Matters

The cross product lives at the heart of Topic 12.2, Magnetism and Moving Charges, where you compute the [magnetic force](/ap-physics-c-e-m/key-terms/magnetic-force "fv-autolink") F = qv × B on charged particles. But it shows up everywhere in [Unit 12](/ap-physics-c-e-m/unit-12 "fv-autolink"). The Biot-Savart law uses a cross product to find the magnetic field a moving charge or current element creates, and torque on a current loop is τ = μ × B. If you can't execute a cross product, both with the right-hand rule for direction and with unit-vector components for magnitude, most of Unit 12 locks you out. Multiple-choice questions routinely give you v and B in î, ĵ, k̂ components and expect a clean component-by-component calculation, including the sign flip for negative charges like electrons.

## Connections

### [F_B = q(v × B) (Unit 12)](/ap-physics-c-e-m/key-terms/f-b-q-v-b)

This is the cross product's main job in E&M. The force on a moving charge is perpendicular to both velocity and field, which is why magnetic forces steer particles into circles but never change their speed. For a negative charge, the force points opposite to v × B, a sign trap the exam loves.

### [Lorentz force (Unit 12)](/ap-physics-c-e-m/key-terms/lorentz-force)

The full force on a charge is F = qE + qv × B. The electric piece is a simple scalar multiple of E, but the magnetic piece needs the cross product. Velocity selector problems with crossed E and B fields hinge on getting the direction of qv × B right so it can cancel the [electric force](/ap-physics-c-e-m/unit-8/1-electric-charge-and-electric-force/study-guide/vbxIAJB9gM4zK3F7 "fv-autolink").

### [Kinematics of charged particle (Unit 12)](/ap-physics-c-e-m/key-terms/kinematics-of-charged-particle)

Because v × B is always perpendicular to v, the magnetic force acts like a centripetal force. That geometry, not any new physics, is what makes a charged particle in a uniform field travel in a circle (or a helix if it has a velocity component along B).

### [Hall effect (Unit 12)](/ap-physics-c-e-m/key-terms/hall-effect)

Inside a current-carrying conductor in a magnetic field, qv × B pushes charge carriers to one side, building up a measurable [voltage](/ap-physics-c-e-m/key-terms/voltage "fv-autolink"). The direction of that push, straight from the right-hand rule, tells you the sign of the charge carriers.

## On the AP Exam

Cross products get tested two ways. Conceptual MCQs hand you directions (a particle moving along +x in a field along +y) and ask for the force direction, which is a pure right-hand-rule check. Calculation questions give v and B in unit-vector form, like v = (3.0 × 10⁶ m/s) î and B = (0.5 T) ĵ + (0.3 T) k̂, and expect you to compute the full vector cross product, then apply q (watching the sign for electrons). Cross products also appear inside bigger setups, like velocity selectors with crossed E and B fields and the field produced by a moving charge via Biot-Savart. FRQs in the magnetism unit typically require you to state the direction of the magnetic force at multiple points along a particle's path and justify it, so practice saying 'by the right-hand rule, v × B points...' until it's automatic.

## cross product vs Dot product

The dot product (A·B = |A||B|cosθ) outputs a scalar and is maximized when vectors are parallel. The cross product outputs a vector and is maximized when vectors are perpendicular, vanishing when they're parallel. In E&M, dot products show up in work and flux calculations, while cross products show up in magnetic force, Biot-Savart, and torque. Mixing up sinθ and cosθ is the classic error.

## Key Takeaways

- The cross product A × B has magnitude |A||B|sinθ and points perpendicular to both A and B, with direction set by the right-hand rule.
- In F = qv × B, the magnetic force is always perpendicular to velocity, so it changes a particle's direction but never its speed and does zero work.
- If the velocity is parallel or antiparallel to the magnetic field, sinθ = 0 and the magnetic force is zero.
- The cross product is anti-commutative, meaning B × v = −(v × B), so order matters.
- For a negative charge like an electron, the force points opposite to the direction v × B gives you.
- When v and B are given in î, ĵ, k̂ components, compute the cross product term by term rather than guessing with the right-hand rule.

## FAQs

### What is the cross product in AP Physics C: E&M?

It's a vector operation that takes two vectors and returns a vector perpendicular to both, with magnitude |A||B|sinθ and direction from the right-hand rule. It's how you find the magnetic force on a moving charge using F = qv × B in Topic 12.2.

### How is the cross product different from the dot product?

The [dot product](/ap-physics-c-e-m/key-terms/dot-product "fv-autolink") gives a scalar using cosθ and is biggest when vectors are parallel; the cross product gives a vector using sinθ and is biggest when vectors are perpendicular. On the E&M exam, flux and work use dot products, while magnetic force and torque use cross products.

### Can the magnetic force ever speed up a charged particle?

No. Because F = qv × B is always perpendicular to the velocity, the magnetic force does zero work and only changes the particle's direction. That's why charges in a uniform magnetic field move in circles at constant speed.

### Does the right-hand rule work for negative charges?

Use the right-hand rule to find v × B first, then flip the result 180° because q is negative. Alternatively, some people use their left hand for negative charges, but the safest habit is computing v × B and then applying the sign of q.

### Is v × B the same as B × v?

No. The cross product is anti-commutative, so B × v = −(v × B). Swapping the order reverses the direction of the result, which flips the direction of your force and tanks the answer if you're not careful.

## Related Study Guides

- [12.2 Magnetism and Moving Charges](/ap-physics-c-e-m/unit-12/2-magnetism-and-moving-charges/study-guide/aujVCr641dSEbfts)

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