The effect you're looking for is called chromatic abberation, you can it look up at Wikipedia. You were given a solution already, but I think it's my duty being a physicist, to give you a deeper understanding of what is going on, and how the effect can be generalized.
Remember that every camera has some aperture and light usually is described as waves. The interaction of waves with an aperture is called diffraction, but when it comes down mathematically it's just a convolution of the wave function with the fourier transform of the aperture function. Diffraction depends on the wavelength, so this creates a spatial shift depending on the color. The other effect contributing is dispersion, i.e. the dependence on refraction of the wavelength. Again diffraction can be described by a convolution.
Now convolutions can be chained up, yielding a total convolution kernel. In the case of Gauss blurring filter the convolution kernel is a Gauss distribution identical in all channels. But you can have different convolution kernels for each target channel. What @bernie suggestet are actually box convolution kernels, shifted by a few pixels in each channel.
This is a nice tutorial about convolution filtering with GLSL. You may use for loops as well instead of unrolling the loops.
I suggest you use some Gauss shaped kernels, with the blurring for red and blue being stronger than green, and of course slightly shifted center points.