A node is marked when one of its child nodes is cut because of a decrease-key. When a second child is cut, the node also cuts itself from its parent. Marking is done so that you know when the second cut occurs.
Intuitively, the Fibonacci heap maintains a collection of trees of different orders, coalescing them when a delete-min occurs. The hope in constructing a Fibonacci heap is that each tree holds a large number of nodes. The more nodes in each tree, the fewer the number of trees that need to be stored in the tree, and therefore the less time will be spent coalescing trees on each delete-min.
At the same time, the Fibonacci heap tries to make the decrease-key operation as fast as possible. To do this, Fibonacci heaps allow subtrees to be "cut out" of other trees and moved back up to the root. This makes decrease-key faster, but makes each tree hold fewer nodes (and also increases the number of trees). There is therefore a fundamental tension in the structure of the design.
To get this to work, the shape of the trees in the Fibonacci heap have to be somewhat constrained. Intuitively, the trees in a Fibonacci heap are binomial trees that are allowed to lose a small number of children. Specifically, each tree in a Fibonacci heap is allowed to lose at most two children before that tree needs to be "reprocessed" at a later step. The marking step in the Fibonacci heap allows the data structure to count how many children have been lost so far. An unmarked node has lost no children, and a marked node has lost one child. Once a marked node loses another child, it has lost two children and thus needs to be moved back to the root list for reprocessing.
The specifics of why this works are documented in many introductory algorithms textbooks. It's not obvious that this should work at all, and the math is a bit tricky.
Hopefully this provides a useful intuition!