Is there a difference between using fzero and fsolve for a single variable equation?
Yes, there is. I'll just mention the most straightforward difference between the two:
Here's a simple example: Consider the function Using fsolve
Not zero, but close. Using fzero
It cannot find a zero. Consider another example with the function
However, Apart from this major difference, there are differences in implementations and the algorithms used. For that, I'll refer you to the online documentation on the functions (see the links above). 


While I like the answer given by yoda, I'll just add a few points. Yes, there is a difference between the two functions, since they have different underlying algorithms. There must be a difference then. So what you need to do is to understand the algorithms! This is true of any comparison between different tools in matlab, both of which should yield a solution. You can think of fzero as a sophisticated version of bisection. If you give a bisection algorithm two end points of an interval that brackets a root of f(x), then it can pick a mid point of that interval. This allows the routine to cut the interval in half, since now it MUST have a new interval that contains a root of f(x). Do this operation repeatedly, and you will converge to a solution with certainty, as long as your function is continuous. If fzero is given only one starting point, then it tries to find a pair of points that bracket a root. Once it does, then it follows a scheme like that above. As you can see, such a scheme will work very nicely in one dimension. However, it cannot be made to work as well in more than one dimension. So fsolve cannot use a similar scheme. You can think of fsolve as a variation of Newton's method. From the starting point, compute the slope of your function at that location. If you approximate your function with a straight line, where would that line cross zero? So essentially, fsolve uses a scheme where you approximate your function locally, then use that approximation to extrapolate to a new location where it is hoped that the solution lies near to that point. Then repeat this scheme until you have convergence. This scheme will more easily be extended to higher dimensional problems than that of fzero. You should, nay, must see the difference. But also, you need to understand when one scheme will succeed and the other fail. In fact, the algorithms used are more sophisticated than what I have described, but those descriptions encapsulate the basic ideas. 

