I'll describe polylogarithmic solution to the problem. Let's introduce some definitions. We'll denote:

- Set of graph's vertices by
`V`

, set of graph's edges by `E`

and set of MST edges by `T`

.
- Edge of graph between vertices
`v`

and `u`

by `{v, u}`

.
- Weight of edge
`e`

by `W(e)`

and weight of MST by `W(T)`

.

Let's consider function `MaxEdge(v, u)`

, which is equal to the edge with the largest weight on the simple path between `v`

and `u`

that belongs to `T`

. If there are several edges with maximum weight `MaxEdge(v, u)`

can be equal to any of them.

To find the second best MST, we need to find such edge `x = {p, q}`

, that:

`x`

does not belong to `T`

.
- Function
`W(x) - W(MaxEdge(p, q))`

is minimal possible.

It's possible to prove that the second best MST can be constructed by removing `MaxEdge(p, q)`

from `T`

and then adding `x = {p, q}`

to `T`

.

Now let's build a data structure that will be able to compute `MaxEdge(p, q)`

in `O(log|V|)`

.

Let's pick a root for the tree `T`

(it can be any vertex). We'll call the number of edges in the simple path between vertex `v`

and the root - the depth of vertex `v`

, and denote it `Depth(v)`

. We can compute `Depth(v)`

for all vertices in `O(|V|)`

by depth first search.

Let's compute two functions, that will help us to calculate `MaxEdge(p, q)`

:

`Parent(v, i)`

, which is equal to the vertex that is a parent (might be non direct parent) of vertex `v`

with depth equal to `Depth(v) - 2^i`

.
`MaxParentEdge(v, i)`

, which is equal to `MaxEdge(v, Parent(v, i))`

.

Both of them can be computed by a recurrence function with memorisation in `O(|V|log|V|)`

.

```
// Assumes that 2^i <= Depth(v)
Vertex Parent(Vertex v, Vertex i) {
if (i == 0) return direct_parent[v];
if (Memorized(v, i)) return memorized_parent[v][i];
memorized_parent[v][i] = Parent(Parent(v, i - 1), i - 1);
return memorized_parent[v][i];
}
Edge MaxParentEdge(Vertex v, Vertex i) {
if (i == 0) return Edge(v, direct_parent[v]);
if (Memorized(v, i)) return memorized_parent_edge[v][i];
Edge e1 = MaxParentEdge(v, i - 1);
Edge e2 = MaxParentEdge(Parent(v, i - 1), i - 1);
if (W(e1) > W(e2)) {
memorized_parent_edge[v][i] = e1;
} else {
memorized_parent_edge[v][i] = e2;
}
return memorized_parent_edge[v][i];
}
```

Before we are ready to compute `MaxEdge(p, q)`

, let's introduce the final definition. `Lca(v, u)`

will denote lowest common ancestor of vertices `v`

and `u`

in the rooted tree `T`

. There are a lot of well known data structures that allows to compute `Lca(v, u)`

query in `O(log|V|)`

or even in `O(1)`

(you can find the list of articles at Wikipedia).

To compute `MaxEdge(p, q)`

we will divide the path between `p`

and `q`

into two parts: from `p`

to `Lca(p, q)`

, from `Lca(p, q)`

to `q`

. Each of these parts looks like a path from a vertex to some of its parents, therefore we can use our `Parent(v, i)`

and `MaxParentEdge(v, i)`

functions to compute `MaxEdge`

for these parts.

```
Edge MaxEdge(Vertex p, Vertex q) {
Vertex mid = Lca(p, q);
if (p == mid || q == mid) {
if (q == mid) return QuickMaxEdge(p, mid);
return QuickMaxEdge(q, mid);
}
// p != mid and q != mid
Edge e1 = QuickMaxEdge(p, mid);
Edge e2 = QuickMaxEdge(q, mid);
if (W(e1) > W(e2)) return e1;
return e2;
}
Edge QuickMaxEdge(Vertex v, Vertex parent_v) {
Edge maxe = direct_parent[v];
string binary = BinaryRepresentation(Depth(v) - Depth(parent_v));
for (int i = 0; i < binary.size(); ++i) {
if (binary[i] == '1') {
Edge e = MaxParentEdge(v, i);
if (W(e) > W(maxe)) maxe = e;
v = Parent(v, i);
}
}
return maxe;
}
```

Basically function `QuickMaxEdge(v, parent_v)`

does jumps of length `2^i`

to cover distance between `parent_v`

and `v`

. During a jump it uses precomputed values of `MaxParentEdge(v, i)`

to update the answer.

Considering that `MaxParentEdge(v, i)`

and `Parent(v, i)`

is precomputed, `MaxEdge(p, q)`

works in `O(log|V|)`

, which leads us to an `O(|E|log|V|)`

solution to the initial problem. We just need to iterate over all edges that does not belong `T`

and compute `W(e) - MaxEdge(p, q)`

for each of them.