Academically speaking, what's the essential difference between the data structure Tree and Graph? And how about the tree based search and Graph based search?
A Tree is just a restricted form of a Graph.
Trees have direction (parent / child relationships) and don't contain cycles. They fit with in the category of Directed Acyclic Graphs (or a DAG). So Trees are DAGs with the restriction that a child can only have one parent.
One thing that is important to point out, Trees aren't a recursive data structure. They can not be implemented as a recursive data structure because of the above restrictions. But any DAG implementation, which are generally not recursive, can also be used. My preferred Tree implementation is a centralized map representation and is non recursive.
Graphs are generally search breath first or depth first. The same applies to Tree.

8Graphs are very useful and can be used to model an enormous amount of things. Lots of other data structures can be seen as a graph with restrictions. For example, a singly linked list is a special case of a DAG. – J.R. Garcia Jul 27 '12 at 15:15

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29"Trees aren't a recursive data structure" is misleading and wrong. A tree can be represented with a nonrecursive data structure (e.g. an array of edges; a full tree, like that underlying a binary heap, can be represented very compactly in an array; there are other succinct representations etc. etc.), but probably the most popular and useful way to represent them is using a recursive pointerbased structure. The representation is not unique for unrooted trees, but that is immaterial. – j_random_hacker Jul 7 '14 at 9:42

Not quite. Tree's don't necessarily have direction. en.wikipedia.org/wiki/Tree_(graph_theory) shows an example of a tree without direction. These are frequently used in biological contexts. – Michal Palczewski Nov 20 '15 at 23:11

2@harshpatel991 trees are not directed in the sense that: "X and Y are in a parentchild relation" doesn't have a direction. The individual relations though, "X is the child of Y", and "Y is a child of X", are directed relations. Direction indicates just that; the direction of 'movement'. In trees the idea of direction is not really needed unless it is meaningful (which is the most often case with trees). That's how I view it at least. – Kostas Mouratidis Jun 11 '18 at 15:14
Instead of explaining I prefer to show it in pictures.
A tree in real time
A graph in real life use
Yes a map can be visualised as a graph data structure.
Seeing them like this makes life easier. Trees are used at places where we know that each node has only one parent. But graphs can have multiple predecessors(term parent is generally not used for graphs).
In real world, you can represent almost anything using graphs. I used a map, for example. If you consider each city as a node, it can be reached from multiple points. The points which lead to this node are called predecessors and the points which this node will lead to are called successors.
electrical circuit diagram, the plan of a house, computer network or a river system are few more examples of graphs. Many real world examples can be considered as graphs.
Technical diagram could be like this
Tree :
Graph :
Make sure to refer to below links. Those will answer almost all your questions on trees and graphs.
References :

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In tree, each node (except the root node) has exactly one predecessor node and one or two successor nodes. It can be traversed by using Inorder, Preorder, Postorder, and Breadth First traversals. Tree is a special kind of graph that has no cycle so that is known as DAG (Directed Acyclic Graph). Tree is a hierarchical model.
In graph, each node has one or more predecessor nodes and successor nodes. The graph is traversed by using Depth First Search (DFS) and Breadth First Search (BFS) algorithms. Graph has cycle so it is more complex than tree. Graph is a network model. There are two kinds of graph: directed graphs and undirected graphs.
Tree is special form of graph i.e. minimally connected graph and having only one path between any two vertices.
In graph there can be more than one path i.e. graph can have unidirectional or bidirectional paths (edges) between nodes
Also you can see more details: http://freefeast.info/differencebetween/differencebetweentreesandgraphstreesvsgraphs/
The other answers are useful, but they're missing the properties of each:
Graph
^{Undirected graph, image source: Wikipedia}
^{Directed graph, image source: Wikipedia}
 Consists of a set of vertices (or nodes) and a set of edges connecting some or all of them
 Any edge can connect any two vertices that aren't already connected by an identical edge (in the same direction, in the case of a directed graph)
 Doesn't have to be connected (the edges don't have to connect all vertices together): a single graph can consist of a few disconnected sets of vertices
Could be directed or undirected (which would apply to all edges in the graph)
As per Wikipedia:For example, if the vertices represent people at a party, and there is an edge between two people if they shake hands, then this graph is undirected because any person A can shake hands with a person B only if B also shakes hands with A. In contrast, if any edge from a person A to a person B corresponds to A admiring B, then this graph is directed, because admiration is not necessarily reciprocated.
Tree
^{Image source: Wikipedia}
 A type of graph
 Vertices are more commonly called "nodes"
 Edges are directed and represent an "is child of" (or "is parent of") relationship
 Each node (except the root node) has exactly one parent (and zero or more children)
 Has exactly one "root" node (if the tree has at least one node), which is a node without a parent
 Has to be connected
 Is acyclic, meaning it has no cycles: "a cycle is a path [AKA sequence] of edges and vertices wherein a vertex is reachable from itself"
There is some overlap in the above properties. Specifically, the last two properties are implied by the rest of the properties. But all of them are worth noting nonetheless.
Trees are obvious: they're recursive data structures consisting of nodes with children.
Map (aka dictionary) are key/value pairs. Give a map a key and it will return the associated value.
Maps can be implemented using trees, I hope you don't find that confusing.
UPDATE: Confusing "graph" for "map" is very confusing.
Graphs are more complex than trees. Trees imply recursive parent/child relationships. There are natural ways to traverse a tree: depthfirst, breadthfirst, levelorder, etc.
Graphs can have unidirectional or bidirectional paths between nodes, be cyclic or acyclic, etc. I would consider graphs to be more complex.
I think a cursory search in any decent data structures text (e.g. "Algorithms Design Manual") would give more and better information than any number of SO answers. I would recommend that you not take the passive route and start doing some research for yourself.

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1Saying "graphs are more complex than trees" is like saying "Crows are more specialized than birds". Shouldn't we say instead that "All trees are graphs, but not all graphs are trees"? – dudewad Jun 30 '17 at 18:41

I don't care six years later. Surely you can use your time better here. – duffymo Jun 30 '17 at 18:42
In mathematics, a graph is a representation of a set of objects where some pairs of the objects are connected by links. The interconnected objects are represented by mathematical abstractions called vertices, and the links that connect some pairs of vertices are called edges.[1] Typically, a graph is depicted in diagrammatic form as a set of dots for the vertices, joined by lines or curves for the edges. Graphs are one of the objects of study in discrete mathematics.
one root node in tree and only one parent for one child. However, there is no concept of root node. Another difference is, tree is hierarchical model but graph is network model.
A tree is a digraph such that:
a) with edge directions removed, it is connected and acyclic
 You can remove either the assumption that it is acyclic
 If it is finite, you can alternatively remove the assumption that it is connected
b) every vertex but one, the root, has indegree 1
c) the root has indegree 0
 If there are only finitely many nodes, you can remove either the assumption that the root has indegree 0 or the assumption that the nodes other than the root have degree 1
Reference: http://www.cs.cornell.edu/courses/cs2800/2016sp/lectures/lec2729graphtheory.pdf