Self-aligning travelling collimating lens for sweeping laser

What is claimed is: 1. A system comprising: an electrode layer transparent to at least one wavelength of light; an electro-optic material layer, the electro-optic material layer being transparent at the at least one wavelength of light; a photoconductive material layer, the photoconductive material layer being transparent at the at least one wavelength of light and sensitive to light of a second wavelength; and a first light source configured to generate a first light beam of the second wavelength that is characterized by an intensity profile, wherein the electrode layer, the electro-optic material layer, and the photoconductive material layer are arranged in a stack, the photoconductive material layer configured to, in response to receiving the first light beam, spatially modulate an electric field within the electro-optic material layer and cause the electro-optic material layer to form an optical lens for the at least one wavelength of light based on a localized change in refractive index induced by the spatially modulated electric field, wherein a phase profile of the optical lens corresponds to the intensity profile of the first light beam of the second wavelength. 2. The system of claim 1 , wherein an impedance of the photoconductive material layer illuminated by the first light beam of the second wavelength is a function of the intensity profile of the first light beam of the second wavelength. 3. The system of claim 2 , wherein the electric field in the electro-optic material layer is spatially modulated based on an impedance change in the photoconductive material layer corresponding to the intensity profile of the first light beam of the second wavelength. 4. The system of claim 2 , wherein, when not illuminated by the first light beam of the second wavelength, a magnitude of the impedance of the photoconductive material layer is at least ten times higher than a magnitude of an impedance of the electro-optic material layer. 5. The system of claim 1 , wherein the electrode layer, the electro-optic material layer, and the photoconductive material layer each have a curved shape. 6. The system of claim 5 , wherein the curved shape comprises at least a portion of a spherical surface. 7. The system of claim 1 , further comprising a second light source emitting a second light beam at the at least one wavelength, wherein the first light source and the second light source are configured to align the first light beam and the second light beam such that the optical lens caused by the first light beam collimates the second light beam. 8. The system of claim 7 , wherein the photoconductive material layer absorbs the first light beam and changes its conductivity in response to absorbing the first light beam. 9. The system of claim 7 , further comprising a beam combiner configured to combine the first light beam and the second light beam. 10. The system of claim 9 , wherein the beam combiner comprises a fiber-optic beam combiner. 11. The system of claim 7 , further comprising a scanning element configured to scan the aligned first light beam and second light beam to move the optical lens in the stack with the second light beam and collimate the second light beam by the optical lens during the scanning. 12. The system of claim 11 , wherein the scanning element comprises: a first scanning element for steering the first light beam; and a second scanning element for steering the second light beam, wherein the first scanning element is synchronized with the second scanning element. 13. The system of claim 1 , further comprising a mask configured to spatially modulate the intensity profile of the first light beam of the second wavelength. 14. The system of claim 13 , wherein the mask comprises a light intensity modulation function corresponding to the phase profile of the optical lens. 15. The system of claim 7 , wherein the second light beam comprises a series of pulses, and the first light beam comprises a continuous wave light beam or a series of pulses. 16. The system of claim 1 , further comprising a voltage source configured to apply a voltage signal between the electrode layer and at least one of the electro-optic material layer or the photoconductive material layer. 17. The system of claim 16 , wherein the voltage signal is applied between the electrode layer and at least one of the electro-optic material layer or the photoconductive material layer to generate the electric field, the electric field substantially parallel or orthogonal to the electro-optic material layer. 18. A method for making a self-aligning optical lens in a beam scanning system, the method comprising: forming a travelling lens stack, wherein forming the travelling lens stack comprises: forming a photoconductive material layer; forming an electro-optic material layer; and forming an electrode layer on a side of the electro-optic material layer that is opposite to the photoconductive material layer; disposing a first light source configured to generate a first light beam at a first wavelength, the first light source oriented relative to the photoconductive material layer to enable the first light source to direct the first light beam towards the photoconductive material layer, the first light beam characterized by an intensity profile; and connecting a voltage source to the electrode layer and the photoconductive material layer, the voltage source configured to apply a voltage signal across the photoconductive material layer and the electro-optic material layer to generate an electric field within the electro-optic material layer, wherein the photoconductive material layer is sensitive to the first light beam; and wherein the intensity profile of the first light beam corresponds to a phase profile of the optical lens such that the first light beam directed to the photoconductive material layer causes the optical lens to be formed in the travelling lens stack. 19. The method of claim 18 , further comprising: disposing a second light source capable of generating a second light beam at a second wavelength, the second light source oriented relative to the photoconductive material layer to enable the second light source to direct the second light beam towards the photoconductive material layer at a location where the first light beam is incident on the photoconductive material layer such that the second light beam is collimated by the optical lens in the travelling lens stack, the photoconductive material layer and the electro-optic material layer transparent to the second light beam. 20. The method of claim 18 , wherein an impedance of the photoconductive material layer is a function of light intensities of a beam spot of the first light beam on the photoconductive material layer. 21. The method of claim 18 , further comprising: disposing a beam intensity modulator between the first light source and the travelling lens stack, the beam intensity modulator configured to modulate the intensity profile of the first light beam according to the phase profile of the optical lens. 22. The method of claim 18 , further comprising: disposing a beam combiner between the first light source and the travelling lens stack, the beam combiner configured to align and combine the first light beam and a second light beam at a second wavelength, the photoconductive material layer and the electro-optic material layer transparent to the second light beam; and disposing a beam steering element between the beam combiner