Recursive algorithm is an algorithm that implemented in accordance with Divide & Conquer strategy, where solving each intermediate sub-problem produces 0, 1 or more new smaller sub-problems. If these sub-problems are solved in LIFO order, you get a classic recursive algorithm.

Now, if your algorithm is known to produce only 0 or 1 sub-problem at each step, then this algorithm can be easily implemented through tail recursion. In fact, such algorithm can easily be rewritten as an iterative algorithm and implemented by a simple cycle. (Needless to add, tail recursion is just another less explicit way to implement iteration.)

A schoolbook example of such recursive algorithm would be recursive approach to factorial calculation: to calculate `n!`

you need to calculate `(n-1)!`

first, i.e. at each recursive step you discover only *one* smaller sub-problem. This is the property that makes it so easy to turn factorial computation algorithm into a truly iterative one (or tail-recursive one).

However, if you know that in general case the number of sub-problems generated at each step of your algorithm is more than 1, then your algorithm is *substantially* recursive. It cannot be rewritten as iterative algorithm, it cannot be implemented through tail recursion. Any attempts to implement such algorithm in iterative or tail-recursive fashion will require additional LIFO storage of non-constant size for storing "pending" sub-problems. Such implementation attempts would simply obfuscate the unavoidable recursive nature of the algorithm by implementing recursion *manually*.

For example, such simple problem as traversal of a binary tree with parent->child links (and no child->parent links) is a substantially recursive problem. It cannot be done by tail-recursive algorithm, it cannot be done by an iterative algorithm.