An image processing technique, which is based on 2-D ensemble empirical mode decomposition, is developed to decompose the thermal images at wind-wave surfaces with various wind conditions. Four components attributed to different flow processes, including the gravity waves, parasitic capillary waves, Langmuir circulations, and the streamwisely elongated coherent vortices induced by wind shear, and the corresponding contribution fractions are derived. In the lowest wind speed case, coherent vortices contribute the most to the surface signatures, and Langmuir circulations contribute the least. As wind speed grows, the contribution of coherent vortices decreases; in contrast, the contribution of Langmuir circulations keeps growing and becomes competitive with that of other flow processes in moderate wind conditions. The contribution of gravity waves does not change much with the present cases, except the micro-breaking case, in which the contribution of gravity waves is much larger than the others, since the signatures induced by spilling breakers are classified into the attribution of gravity waves. The capillary waves contribute little to the thermal images, but become significant at the present highest wind speed, which may also be attributed to the spanwisely elongated small vortices due to fully wave breaking. The surface streaky signatures attributed to the coherent vortices can be further identified utilizing the image segmentation techniques, and the statistics of spanwise streak spacing can therefore be calculated. It is found that the distributions of streak spacing from low to high wind speed match log-normal probability density distributions. Furthermore, the mean streak spacing decreases as wind speed grows; the non-dimensional mean streak spacing in viscous length scale, however, increases with wind speed, different from that of wall turbulent boundary layer, which is a constant 100 viscous unit.