I don't quite understand why a sigmoid function is seen as more useful (for neural networks) than a step function... hoping someone can explain this for me. Thanks in advance.
The (Heaviside) step function is typically only useful within singlelayer perceptrons, an early type of neural networks that can be used for classification in cases where the input data is linearly separable.
However, multilayer neural networks or multilayer perceptrons are of more interest because they are general function approximators and they are able to distinguish data that is not linearly separable.
Multilayer perceptrons are trained using backpropapagation. A requirement for backpropagation is a differentiable activation function. That's because backpropagation uses gradient descent on this function to update the network weights.
The Heaviside step function is nondifferentiable at x = 0 and its derivative is 0 elsewhere. This means gradient descent won't be able to make progress in updating the weights and backpropagation will fail.
The sigmoid or logistic function does not have this shortcoming and this explains its usefulness as an activation function within the field of neural networks.

2This is a beautiful answer. Builds up the required context and comes in for the kill. Thank you! – MadRabbit May 17 '18 at 18:27
It depends on the problem you are dealing with. In case of simple binary classification, a step function is appropriate. Sigmoids can be useful when building more biologically realistic networks by introducing noise or uncertainty. Another but compeletely different use of sigmoids is for numerical continuation, i.e. when doing bifurcation analysis with respect to some parameter in the model. Numerical continuation is easier with smooth systems (and very tricky with nonsmooth ones).

I think the most common case for sigmoid activation is simply regression. – runDOSrun Dec 26 '15 at 14:18