Light activated piezoelectric converter

What is claimed is: 1. A light activated piezoelectric converter comprising: a foundation; a vane comprising: a first section comprising a first surface between a proximate end of the first section and a distal end of the first section, where the proximate end of the first section is coupled to the foundation, and where the first surface has a first emissivity; and a second section comprising a second surface between a proximate end of the second section and a distal end of the second section, where the proximate end of the second section is coupled to the foundation, and where the second surface has a second emissivity, where the first emissivity minus the second emissivity is equal to at least 0.1, and where the second surface borders the first surface over a common boundary and the second surface is co-planer with the first surface over a portion of the common boundary; a piezoelectric material coupled to a single section of the vane, where the single section is either the first section of the vane or the second section of the vane; a first electrode in electrical contact with the piezoelectric material; and a second electrode in electrical contact with the piezoelectric material. 2. The light activated piezoelectric converter of claim 1 where a reference plane is parallel with the second surface and the first surface over the portion of the common boundary and where the vane is configured to place a stress on the piezoelectric material parallel to the reference plane when the distal end of the first section deflects in a direction parallel to the reference plane. 3. The light activated piezoelectric converter of claim 2 where the vane has a length L where the length L extends from the proximate end of the first section to the distal end of the first section and where the length L is parallel to the reference plane, and where the vane has a height H perpendicular to the reference plane and a width W perpendicular to the height H and perpendicular to the length L, and where the width W is greater than the height H, and the length L is at least 5 times greater than the height H. 4. The light activated piezoelectric converter of claim 1 further comprising an atmosphere surrounding the vane, and where the first surface and the second surface are separated by the portion of the common boundary by a distance less than or equal to 10 mean free paths of the atmosphere. 5. The light activated piezoelectric converter of claim 3 further comprising an energy harvesting circuit in electrical communication with the first electrode and the second electrode where the energy harvesting circuit comprises a storage capacitor and where the energy harvesting circuit is configured to charge the storage capacitor utilizing a voltage between the first electrode and the second electrode and configured to discharge the storage capacitor when a voltage limit is present across the storage capacitor. 6. The light activated piezoelectric converter of claim 5 where the energy harvesting circuit comprises an AC/DC rectifier in electrical communication with the first electrode and the second electrode, and where the AC/DC rectifier is configured to charge the storage capacitor. 7. The light activated piezoelectric converter of claim 1 further comprising: an atmosphere surrounding the vane; a radiant flux impinging the first surface and the second surface, and the radiant flux generating a first temperature on the first surface and a second temperature on the second surface, where the first temperature is greater than the second temperature, and the first temperature and the second temperature generating a temperature gradient and generating a thermal creep force in a direction from the first surface to the second surface and parallel to the first surface and the second surface over the portion of the common boundary, and the thermal creep force generating a deflection of the vane; and the deflection of the vane generating a stress on the piezoelectric material and the piezoelectric material generating a voltage between the first electrode and the second electrode. 8. The light activated piezoelectric converter of claim 7 where the atmosphere surrounding the vane comprises air at a pressure of at least 80 kPa, and where a total width W is equal to a first section width added to a second section width, where the first section width is a dimension of the first surface perpendicular to the portion of the common boundary and the second section width is a dimension of the second surface perpendicular to the portion of the common boundary, and where the total width is less than 100 microns. 9. The light activated piezoelectric converter of claim 1 further comprising: an axle having a longitudinal axis where the axle is coupled to the foundation; and a second vane in mechanical contact with the axle and configured to revolve around the longitudinal axis of the axle. 10. The light activated piezoelectric converter of claim 9 further comprising: an atmosphere surrounding the vane; a radiant flux impinging the first surface of the vane and the second surface of the vane, and the radiant flux generating a first temperature on the first surface of the vane and a second temperature on the second surface of the vane, where the first temperature is greater than the second temperature, and the first temperature and the second temperature generating a temperature gradient and generating a thermal creep force in a direction from the first surface of the vane to the second surface of the vane and parallel to the first surface of the vane and the second surface of the vane over the portion of the common boundary, and the thermal creep force generating a deflection of the vane; the radiant flux impinging the first surface of the second vane and the second surface of the second vane, and the radiant flux generating a third temperature on the first surface of the second vane and a fourth temperature on the second surface of the second vane, where the third temperature is greater than the fourth temperature, and the third temperature and the fourth temperature generating a second temperature gradient and generating a second thermal creep force in a direction from the first surface of the second vane to the second surface of the second vane, and the second thermal creep force generating a revolution of the second vane around the longitudinal axis, and the second vane positioning between the radiant flux and vane during at least some part of the revolution around the longitudinal axis; and the deflection of the vane generating a stress on the piezoelectric material and the piezoelectric material generating a voltage between the first electrode and the second electrode. 11. A system for generating a voltage using a radiant flux comprising: a light activated piezoelectric converter, where the light activated piezoelectric converter comprises: a foundation; a vane comprising: a first section comprising a first surface between a proximate end of the first section and a distal end of the first section, where the proximate end of the first section is coupled to the foundation, and where the first surface has a first emissivity; and a second section comprising a second surface between a proximate end of the second section and a distal end of the second section, where the proximate end of the second section is coupled to the foundation, and where the second surface has a second emissivity, where the first emissivity minus the second emissivity is equal to at least 0.1, and where the second surface borders the first surface over a common boundary and the second surface is co-planer with the first surface over a portion of the common boundary;