Internally heated concentrated solar power (CSP) thermal absorber

We claim: 1. An internally heated energy generating system, comprising: a housing; a light-transparent reservoir, comprising a material that is transparent to sunlight rays, that forms a portion of a curved exterior side of the housing and is configured to allow the sunlight rays to enter into the housing by penetrating through the curved exterior side of the housing; an energy generating device; and at least one heating unit configured to preheat the energy generating device to expedite a startup time of the energy generating device to increase efficiency of a production of energy, wherein the at least one heating unit each comprises a heating device that generates heat and a fin, wherein one end of the fin is connected to an end of the heating device and an opposite end of the fin is submerged into a liquid contained within the light-transparent reservoir, thereby allowing the heating device to heat the liquid via the fin, wherein the liquid is a liquid alkali metal. 2. The internally heated energy generating system of claim 1 , wherein the energy generating device comprises a concentrated solar power (CSP) thermal absorber. 3. The internally heated energy generating system of claim 2 , wherein the concentrated solar power (CSP) thermal absorber comprises: the housing that comprises a thermal barrier, wherein the thermal barrier divides the interior of the housing into a hot chamber and a cold chamber; the light-transparent reservoir located in the hot chamber of the housing; at least one alkali metal thermal-to-electric converter (AMTEC) cell disposed within the thermal barrier such that one end of the AMTEC cell is located in the cold chamber and another end of the AMTEC cell is located in the hot chamber; and an artery return channel that allows for the liquid to return from the cold chamber to the hot chamber. 4. The internally heated energy generating system of claim 3 , wherein the at least one heating unit further comprises an additional heating device that generates heat, wherein the additional heating device is attached to the end of the AMTEC cell that is located in the hot chamber, and wherein the additional heating device is able to heat the liquid. 5. The internally heated energy generating system of claim 1 , wherein the fin is manufactured from metal. 6. The internally heated energy generating system of claim 1 , wherein the at least one heating unit further comprises an additional heating device that generates heat; wherein one end of the additional heating device is submerged into the liquid, thereby allowing the additional heating device to heat the liquid. 7. The internally heated energy generating system of claim 1 , wherein the at least one heating unit further comprises a heating element that generates heat, wherein the heating element is attached to an outside of the light-transparent reservoir, plated to the outside of the light-transparent reservoir, mounted to the outside of the light-transparent reservoir, attached to an inside of light-transparent reservoir, plated to the inside of the light-transparent reservoir, or mounted to the inside of the light-transparent reservoir, and wherein the heating element is able to heat the liquid. 8. The internally heated energy generating system of claim 7 , wherein the heating element comprises a transparent conductor material. 9. The internally heated energy generating system of claim 8 , wherein the transparent conductor material comprises one of indium tin oxide or a conductive nanoparticles material in a carrier coating. 10. The internally heated energy generating system of claim 1 , wherein the liquid alkali metal is one of liquid sodium (Na), liquid lithium (Li), liquid potassium (K), or liquid rubidium (Rb). 11. A method for providing an internally heated energy generating system, the method comprising: providing an energy generating device, a housing, a light-transparent reservoir that comprises a material that is transparent to sunlight rays and that forms a portion of a curved exterior side of the housing, and at least one heating unit; entering, by the sunlight rays, into the housing by penetrating through the curved exterior side of the housing; generating, by a heating device of the at least one heating unit, heat to preheat the energy generating device to expedite a startup time of the energy generating device to increase efficiency of a production of energy; and heating, by the heating device via a fin connected to an end of the heating device wherein an opposite end of the fin is submerged in a liquid contained within the light-transparent reservoir, the liquid, wherein the liquid is a liquid alkali metal. 12. The method for providing an internally heated energy generating system of claim 11 , wherein the energy generating device comprises a concentrated solar power (CSP) thermal absorber. 13. The method for providing an internally heated energy generating system of claim 12 , wherein the concentrated solar power (CSP) thermal absorber comprises: the housing that comprises a thermal barrier, wherein the thermal barrier divides the interior of the housing into a hot chamber and a cold chamber; the light-transparent reservoir located in the hot chamber of the housing; at least one alkali metal thermal-to-electric converter (AMTEC) cell disposed within the thermal barrier such that one end of the AMTEC cell is located in the cold chamber and an other end of the AMTEC cell is located in the hot chamber; and an artery return channel that allows for the liquid to return from the cold chamber to the hot chamber. 14. The method for providing an internally heated energy generating system of claim 13 , wherein the preheating comprises generating, by an additional heating device of the at least one heating unit, heat, wherein the additional heating device is attached to the end of the AMTEC cell that is located in the hot chamber such that the additional heating device heats the liquid. 15. The method for providing an internally heated energy generating system of claim 11 , wherein the fin is manufactured from metal. 16. The method for providing an internally heated energy generating system of claim 11 , wherein the preheating comprises generating, by an additional heating device of the at least one heating unit, heat, wherein one end of the additional heating device is submerged into the liquid such that the additional heating device heats the liquid. 17. The method for providing an internally heated energy generating system of claim 11 , wherein the preheating comprises generating, by a heating element of the at least one heating unit, heat, wherein the heating element is attached to an outside of the light-transparent reservoir, plated to the outside of the light-transparent reservoir, mounted to the outside of the light-transparent reservoir, attached to an inside of light-transparent reservoir, plated to the inside of the light-transparent reservoir, or mounted to the inside of the light-transparent reservoir such that the heating element heats the liquid. 18. The method for providing an internally heated energy generating system of claim 17 , wherein the heating element comprises a transparent conductor material. 19. The method for providing an internally heated energy generating system of claim 18 , wherein the transparent conductor material comprises one of indium tin oxide or a conductor nanoparticles material in a carrier coating. 20. The method for providing an internally heated energy generating s