Poor performance here is due to forming all possible letter assignments before checking if any are feasible.
My advice is "fail early, fail often". That is, push as many checks for failure as early as possible into the assignment steps, thus pruning the search tree.
Klas Lindbäck makes some good suggestions. As a generalization, when adding two numbers the carry is at most one in each place. So the assignment of distinct digits to letters from left to right can be checked with allowance for the possibility of an as-yet-undetermined carry in the rightmost places. (Of course in the final "units" place, there is no carry.)
It's a lot to think about, which is why constraint logic, as mat suggests (and which you've already broached with fd_all_different/1), is such a convenience.
Added: Here's a Prolog solution without constraint logic, using just one auxiliary predicate omit/3:
omit(X,[H|T],[H|Y]) :- omit(X,T,Y).
which both selects an item from a list and produces the shortened list without that item.
Here then is the code for sendMoreMoney/3 that searches by evaluating the sum from left to right:
M = 1,
(CarryS = 0 ; CarryS = 1),
%% CarryS + S + M = M*10 + O
O is (CarryS + S + M) - (M*10),
(CarryE = 0 ; CarryE = 1),
%% CarryE + E + O = CarryS*10 + N
N is (CarryE + E + O) - (CarryS*10),
(CarryN = 0 ; CarryN = 1),
%% CarryN + N + R = CarryE*10 + E
R is (CarryE*10 + E) - (CarryN + N),
%% D + E = CarryN*10 + Y
Y is (D + E) - (CarryN*10),
We get off to a quick start by observing that M must be the nonzero carry from the leftmost digits sum, hence 1, and that S must be some other nonzero digit. The comments show steps where additional letters may be deterministically assigned values based on choices already made.
Added(2): Here is a "general" cryptarithm solver for two summands, which need not have the same length/number of "places". Code for length/2 is omitted as a fairly common built-in predicate, and taking up the suggestion by Will Ness, calls to omit/3 are replaced by select/3 for convenience of SWI-Prolog users.
I've tested this with Amzi! and SWI-Prolog using those alphametics examples from Cryptarithms.com which involve two summands, each of which has a unique solution. I also made up an example with a dozen solutions, I + AM = BEN, to test proper backtracking.
( Size = Length
-> ( Carry = 0, Sum = TSum , Pool = [1|Peel] )
; ( Size is Length+1, Carry = 1, Sum = [Carry|TSum], Pool = Peel )
Peel = [2,3,4,5,6,7,8,9,0].
( Length1 >= Length2
-> ( Length = Length1, Longer = List1, Shorter = List2, Pad is Length1 - Length2 )
; ( Length = Length2, Longer = List2, Shorter = List1, Pad is Length2 - Length1 )
K > 0,
M is K-1,
( CarryIn = 0 ; CarryIn = 1 ), /* anticipatory carry */
; Pool = P_ol
; P_ol = P__l
-> ( H3 is H1 + H2 + CarryIn - 10*CarryOut, select(H3,P__l,P___) )
; ( H3 is H1 + H2 + CarryIn - 10*CarryOut, P__l = P___ )
NZ1 \== 0,
NZ2 \== 0,
I think this illustrates that the advantages of left-to-right search/evaluation can be attained in a "generalized" solver, increasing the number of inferences by roughly a factor of two in comparison with the earlier "tailored" code.