Take the simple example of a sorted list, based on an unsorted list.

Let us assume that the insertion time on the unsorted list at an arbitrary index is O(n/2) where n is the size of the list. The reflects that on average, half of the list elements will have to be displaced to make room for the element being inserted.

Similarly, in this list, to remove an element from an arbitrary position is also O(n/2) because on average again half the elments will have to be moved to close the gap.

. . .

Now, imagine the same implementation, but with sorting.

The sorting will have to be done at insertion--it will have to find the position of the new element. Since all previous elements are already sorted (we do it at insertion, so this is true), we can start scanning from the beginning.

This is a O(n/2) operation, before we even begin the insertion. That is just to find the insertion point.

A better method, using binary search would give us O(log n) to find the insertion position, but still before paying the O(n/2) cost of doing the insertion itself.

If the cost of a scanning operation is s, and the cost of the insertion operation is m (for move), then the cost of the sorted insertion is:

```
s x O(log n) + m x (n/2)
```

However, an insertion operation on the unsorted list at an arbitrary position is only:

```
m x (n /2)
```

This is a concrete example of the real reason why sorted operations take longer.

There is more to this type of theory, but that should be a start.