Optical element comprising at least one holographic diffusive element

The invention claimed is: 1. An optical element configured to be worn in front of an eye of a wearer, the optical element having two main surfaces, wherein the optical element comprises at least one holographic diffusive element having diffusive properties resulting from spatial variations of refractive index of said holographic diffusive element, said spatial variation of refractive index being greater than 0.001 at at least one given wavelength, on a distance less than 30 μm. 2. The optical element according to claim 1 , wherein the two main surfaces are configured so that a refractive power based on a prescription for the eye of the wearer is provided. 3. The optical element according to claim 1 , wherein the at least one holographic diffusive element extends over only part of one of the two main surfaces or over an entirety of one of the two main surfaces. 4. The optical element according to claim 1 , wherein the at least one holographic diffusive element is a holographic gradient diffusive element, the holographic gradient diffusive element having a diffusion efficiency which increases from a center of the holographic diffusive element to a periphery of the holographic diffusive element. 5. The optical element according to claim 1 , wherein the at least one holographic diffusive element has a diffusion efficiency between 5 and 50% at the at least one given wavelength within a predetermined range. 6. The optical element according to claim 1 , the spatial variations of refractive index being configured such that: for at least one angular direction of incidence, when the optical element is exposed to a source beam of light originating from said angular direction of incidence, the source beam of light is scattered by at least one holographic diffusive element, forming at least one beam of scattered light, each said beam of scattered light being centered on a respective central angular direction, defined as an angular direction exhibiting a maximum luminance value, and each said beam of scattered light exhibiting a respective angle of diffusion, defined as a full width at half maximum of luminance, which has a wanted value comprised between 2° and 40° according at least one direction. 7. The optical element according to claim 1 , wherein said spatial variations of refractive index are configured so that the at least one holographic diffusive element has an optical function of scattering light to illuminate a retina of said eye so as to slow down a progression of an abnormal refraction of the eye. 8. The optical element according to claim 1 , wherein the at least one holographic diffusive element is a holographic diffusive mirror. 9. The optical element according to claim 8 , wherein the at least one holographic diffusive element has a diffusion efficiency between 1 and 5% at the at least one given wavelength within a predetermined range. 10. An optical equipment configured to be worn in front of a wearer eye, comprising: an optical element wherein the optical element comprises at least one holographic diffusive element having diffusive properties resulting from spatial variations of refractive index of said holographic diffusive element, said spatial variation of refractive index being greater than 0.001 at at least one given wavelength, on a distance less than 30 μm; and a light source arranged to light at the at least one given wavelength on the at least one optical element. 11. The optical equipment according to claim 10 , further comprising a motion sensor configured to acquire a signal as function of a motion of the wearer, wherein the light source is lit on when the acquired signal has a predetermined value. 12. A method for recording a holographic medium onto an optical lens, the method comprising: providing an unrecorded optical lens comprising a recording medium extending over an area of interest, the unrecorded optical lens having two main surfaces; providing a diffusive object; and recording a holographic diffusive element on the recording medium by simultaneously illuminating the area of interest with: a reference beam being a beam of coherent light, and an object beam being a beam of coherent light scattered through the diffusive object to obtain a recorded optical lens, wherein the diffusive object, the reference beam and the object beam are configured so that the recorded holographic diffusive element has diffusive properties resulting from spatial variations of refractive index of said holographic diffusive element, said spatial variation of refractive index being greater than 0.001 at at least one given wavelength, on a distance less than 30 μm. 13. The method according to claim 12 , wherein, while recording the holographic diffusive element, the reference beam and the object beam form two separate beams that are respectively directed towards opposite main surfaces of the unrecorded optical lens. 14. A method for recording a holographic medium onto an optical lens, the method comprising: providing an unrecorded optical lens comprising a recording medium extending over an area of interest, the unrecorded optical lens having two main surfaces; modelling optical properties of a diffusive object; and recording a holographic diffusive element on the recording medium by simultaneously illuminating the area of interest with: a reference beam being a beam of coherent light, and an object beam simulating a beam of coherent light which would be scattered by the diffusive object to obtain a recorded optical lens, wherein the diffusive object, the reference beam and the object beam are configured so that the recorded holographic diffusive element has diffusive properties resulting from spatial variations of refractive index of said holographic diffusive element, said spatial variation of refractive index being greater than 0.001 at at least one given wavelength, on a distance less than 30 μm. 15. The method according to claim 14 , wherein, while recording the holographic diffusive element, the reference beam is provided by a source; and the object beam is provided by a spatial light modulator used as a programmable diffuser and reflector, the reference beam being directed towards a first one of the two main surfaces and the object beam being directed towards a second one of the two main surfaces.