Chapter 6 / 6.5 Vector Product of Two Vectors

Vector Product (Cross Product) of Two Vectors

Why we care

The “cross” of two vectors helps us build moment of force (torque) and angular momentum—two pillars of rotational motion.:contentReference[oaicite:0]{index=0}

Definition

For two vectors \(\mathbf a\) and \(\mathbf b\), their vector product is \(\mathbf c = \mathbf a \times \mathbf b\).
Magnitude: \( |\mathbf c| = ab\sin\theta \), where \(a\) and \(b\) are the lengths of the two vectors and \(\theta\) is the smaller angle between them.:contentReference[oaicite:1]{index=1}
Direction: \(\mathbf c\) stands straight out of the plane of \(\mathbf a\) and \(\mathbf b\). Point your right-hand fingers from \(\mathbf a\) toward \(\mathbf b\); your thumb shows \(\mathbf c\).:contentReference[oaicite:2]{index=2}

Key properties

Perpendicularity: \(\mathbf c\) is perpendicular to both \(\mathbf a\) and \(\mathbf b\).:contentReference[oaicite:3]{index=3}
Non-commutative: \(\mathbf a \times \mathbf b = -(\mathbf b \times \mathbf a)\). Same size, opposite direction.:contentReference[oaicite:4]{index=4}
Distributive: \(\mathbf a \times (\mathbf b+\mathbf c)=\mathbf a \times \mathbf b+\mathbf a \times \mathbf c\).:contentReference[oaicite:5]{index=5}
Self-product vanishes: \(\mathbf a \times \mathbf a=\mathbf 0\).:contentReference[oaicite:6]{index=6}
Mirror-safe: reflecting the whole system flips each vector but not their cross product.:contentReference[oaicite:7]{index=7}

Right-hand “cheat sheet” for unit vectors

Follow the cyclic order \(\hat{\mathbf i}\rightarrow\hat{\mathbf j}\rightarrow\hat{\mathbf k}\rightarrow\hat{\mathbf i}\):

\(\hat{\mathbf i}\times\hat{\mathbf j}= \hat{\mathbf k}\)
\(\hat{\mathbf j}\times\hat{\mathbf k}= \hat{\mathbf i}\)
\(\hat{\mathbf k}\times\hat{\mathbf i}= \hat{\mathbf j}\)
Reverse the order and you pick up a minus sign, e.g., \(\hat{\mathbf j}\times\hat{\mathbf i}= -\hat{\mathbf k}\).:contentReference[oaicite:8]{index=8}

Component formula (determinant form)

\[ \mathbf a \times \mathbf b= \begin{vmatrix} \hat{\mathbf i}&\hat{\mathbf j}&\hat{\mathbf k}\\ a_x & a_y & a_z\\ b_x & b_y & b_z \end{vmatrix} \] This is the quickest way to crank out the cross product once you know the components.:contentReference[oaicite:9]{index=9}

Worked idea (outline)

With \(\mathbf a=3\hat{\mathbf i}+4\hat{\mathbf j}+5\hat{\mathbf k}\) and \(\mathbf b=-2\hat{\mathbf i}+\,1\hat{\mathbf j}+3\hat{\mathbf k}\):

Dot product: \(\mathbf a\cdot\mathbf b=-25\).
Cross product: \(\mathbf a \times \mathbf b = 7\hat{\mathbf i}+5\hat{\mathbf j}-11\hat{\mathbf k}\).:contentReference[oaicite:10]{index=10}

(The numbers show how the determinant method works in practice.)

NEET high-yield ideas

Magnitude formula \(ab\sin\theta\) and the insistence on the smaller angle.
Right-hand rule—curl from \(\mathbf a\) to \(\mathbf b\); thumb is \(\mathbf a\times\mathbf b\).
Non-commutative nature: sign flip when you swap vectors.
Unit-vector cross products (\(\hat{\mathbf i},\hat{\mathbf j},\hat{\mathbf k}\)) and the cyclic rule.
Determinant shortcut for quick component calculation.

Keep practicing the right-hand trick—it turns vector puzzles into simple thumb rules!