You can do it in O(N log N) approach the following way.
Firstly, "squeeze" your y coordinates. That is, sort all y coordinates (tops and bottoms) together in one array, and then replace coordinates in your rectangle description by its index in a sorted array. Now you have all y's being integers from 0 to 2n-1, and the answer to your problem did not change (in case you have equal y's, see below).
Now you can divide the plane into 2n-1 stripes, each unit height, and each rectangle spans completely several of them. Prepare an segment tree for these stripes. (See this link for segment tree overview.)
Then, sort all x-coordinates in question (both left and right boundaries) in the same array, keeping for each coordinate the information from which rectangle it comes and whether this is a left or right boundary.
Then go through this list, and as you go, maintain list of all the rectangles that are currently "active", that is, for which you have seen a left boundary but not right boundary yet.
More exactly, in your segment tree you need to keep for each stripe how many active rectangles cover it. When you encounter a left boundary, you need to add 1 for all stripes between a corresponding rectangle's bottom and top. When you encounter a right boundary, you need to subtract one. Both addition and subtraction can be done in O(log N) using the mass update (lazy propagation) of the segment tree.
And to actually check what you need, when you meet a left boundary, before adding 1, check, whether there is at least one stripe between bottom and top that has non-zero coverage. This can be done in O(log N) by performing a sum on interval query in segment tree. If the sum on this interval is greater than 0, then you have an intersection.
sort all x's
t = segment tree on 2n-1 cells
for all x's
r = rectangle for which this x is
if this is left boundary
if t.sum(r.bottom, r.top-1)>0 // O(log N) request
you have occurence
t.add(r.bottom, r.top-1, 1) // O(log N) request
t.subtract(r.bottom, r.top-1) // O(log N) request
You should implement it carefully taking into account whether you consider a touch to be an intersection or not, and this will affect your treatment of equal numbers. If you consider touch an intersection, then all you need to do is, when sorting y's, make sure that of all points with equal coordinates all tops go after all bottoms, and similarly when you sort x's, make sure that of all equal x's all lefts go before all rights.