My book here (Artificial intelligence A modern approach) says that the worstcase time and space complexity of a uniformcost search algorithm would be O(b[C*/e]) , where b is the branching factor, C* is the cost of the optimal solution, and every action costs atleast e. But why is this so?
First, the complexity is O(B^(C/e))
[exponential in C/e
].
To understand it, think of a simple example case first:
Let G=(V,E)
be a graph, with branch factor B
. The graph is unweighted (w(e) = 1
for each e
).
Consider finding the shortest path from S to T.
In this case, the algorithm is actually a BFS, and it will discover all nodes in the path up to length SOL
, where SOL
is the length of the shortest path, which is O(B^SOL)
For the general case  the same idea holds, you need to discover all nodes up to cost C
. So you discover nodes up to depth C/e
, giving you O(B^(C/e))
total nodes needed to be explored.
The exponential factor is because: First level (root) has B^0=1
nodes, second level has B nodes. from each of these you discover B
nodes, giving you B^2
, ....
EDIT:
Missed it so far, but the title asks for space complexity and not time complexity. However, the answer remains the same, since a uniform cost search holds a visited
set, for already visited nodes. Since each node you discover is also added to it  the answer remains O(B^(C/e))

But why do you take
C/e
? C is the cost of the the goal, and e is the minimum cost of any node. So what's the logic behind this. – Ghost Aug 15 '12 at 13:45 
@Ghost:
C/e
is the maximal possible depth you need to traverse. If the goal cost isC
, and each edge cost at leaste
, the total number of edges you can traverse in each path is at mostC/e
– amit Aug 15 '12 at 13:46 
So is
C*
the cost of traversing from the root to the goal node, or the cost of traversing from the node before the goal to the goal node? – Ghost Aug 15 '12 at 13:49 
@Ghost: From the source to the goal (The sum of costs of all edges on the path leading from source to goal) – amit Aug 15 '12 at 13:51

C*/e
means average number of nodes which should be visited during the search, and for visiting each of this nodes you should look at all possible b
branches (at least root nodes), so you should check b^{[C*/e]} node in your search. which is your search time complexity, this is by assuming process on each node takes O(1).
_{P.S: It's Ω(b[C*/e])in worst case}