Condition for Edge to be Bridge

Theorem
Let $G = \struct {V, E}$ be a connected graph.

Let $e \in E$ be an edge of $G$.

Then $e$ is a bridge $e$ does not lie on any circuit of $G$.

Proof
Let $G - e$ denote the edge deletion of $e$ from $G$.

Necessary Condition
We use a Proof by Contraposition.

To that end, suppose $e = u v$ such that $e$ lies on a circuit, say:
 * $C = \tuple {u, v, w, \ldots, x, u}$

Thus $G - e$ contains a $u - v$ path, that is, $\tuple {v, x, \ldots, w, u}$.

So $u$ is connected to $v$ in $G - e$.

Now we need to show that $G - e$ is connected.

Let $u_1, v_1 \in V$.

Since $G$ is connected, there is a $u_1 - v_1$ path $P$ in $G$.

If $e \notin P$, then $P$ is also a path in $G - e$ and $u_1$ is connected to $v_1$ in $G - e$.

On the other hand, suppose $e \notin P$.

Then $P$ can be expressed as $\tuple {u_1, \ldots, u, v, \ldots, v_1}$ or $\tuple {u_1, \ldots, v, u, \ldots, v_1}$.

In the first case, $u_1$ is connected to $u$ and $v$ is connected to $v_1$ in $G - e$.

In the second case, $u_1$ is connected to $v$ and $u$ is connected to $v_1$ in $G - e$.

But we have already established that $u$ is connected to $v$ in $G - e$.

From Graph Connectedness is Equivalence Relation it follows that $u_1$ is connected to $v_1$.

So, if $e$ lies on a circuit, then $G - e$ is connected.

Therefore $e$ is not a bridge.

From Rule of Transposition it follows that if $e$ is a bridge, it does not lie on a circuit.

Sufficient Condition
We use a Proof by Contraposition.

To that end, suppose $e = u v$ is not a bridge.

Then $G - e$ is connected, and thus there is a $u-v$ path $P$ in $G - e$.

But $P$ together with $e = u v$ produces a circuit containing $e$.

Thus $e$ lies on a circuit of $G$.

From Rule of Transposition it follows that if $e$ does not lie on a circuit, it is a bridge.

Also presented as
This result is usually given that:
 * $e$ is a bridge $e$ does not lie on any cycle of $G$.

As a cycle is by definition a circuit, the result as given in this entry is slightly stronger.