An ideal low pass filter will keep all spatial frequencies below a nominal spatial frequency, and remove all spatial frequencies above it. Unfortunately, a true ideal low pass filter has infinite support (i.e., has an infinitely large non-zero spatial extend). Even a practical approximation to an ideal low pass filter has large spatial support.

A Gaussian, on the other hand, isn't ideal in terms of which frequencies it filters out. A Gaussian in the spatial domain turns out to be a Gaussian in the spatial frequency domain. That is, it doesn't produce very sharp spatial frequency selectivity. The advantage though is that the spatial support of the filter is small. People use Gaussian filters for this because they are convenient mostly. Filtering with a Gaussian tends to look "natural" compared to ideal low pass filters, which can generate ringing artifacts.

A Lanczos filter (windowed sinc filter) is also another choice as it will have a small spatial support and will approximate an ideal filter better than a Gaussian.

However, which is better for your image largely depends on what you want to do. While there's significant theory behind it, qualitative choices like this in image processing are largely an art.