Power generation using buoyancy-induced vortices

Therefore, at least the following is claimed: 1. A vortex generation system, comprising: a nucleating obstruction that nucleates a columnar vortex from preheated air in a surface momentum boundary layer; an array of hybrid vanes distributed about the nucleating obstruction, each of the hybrid vanes comprising a first vane section in the surface momentum boundary layer and a second vane section above the first vane section, where: the first vane section is configured to impart a first angular momentum on the preheated air in the surface momentum boundary layer as the preheated air is drawn through the first vane section to form the columnar vortex over the nucleating obstruction, where the preheated air has been heated in the surface momentum boundary layer over an uncovered surface outside the array of hybrid vanes by surface heating, the uncovered surface extending outward from the array of hybrid vanes; and the second vane section is configured to impart a second angular momentum on preheated air drawn through the second vane section from a thermal boundary layer outside the array of hybrid vanes; and a set of turbine blades positioned over the nucleating obstruction, the set of turbine blades configured to extract power from the columnar vortex. 2. The vortex generation system of claim 1 , wherein a height of the first vane section is less than a height of the second vane section and a width of the first vane section is greater than a width of the second vane section. 3. The vortex generation system of claim 2 , wherein the height of the first vane section is a predefined fraction of the height of the second vane section. 4. The vortex generation system of claim 2 , wherein the first and second vane sections extend inward from a pivot point at a proximal end, and the first vane section comprises a tapered end at a distal end opposite the pivot point, a height of the tapered end increasing from the distal end of the first vane section. 5. The vortex generation system of claim 1 , wherein each of the hybrid vanes further comprises a third vane section above the second vane section, the third vane section configured to impart a third angular momentum on preheated air drawn through the third vane section from the thermal boundary layer outside the array of hybrid vanes. 6. The vortex generation system of claim 1 , further comprising a partition including a central opening, the partition positioned between the first vane section and the second vane section and extending around the array of hybrid vanes. 7. The vortex generation system of claim 6 , wherein a width of the partition is approximately a width of the second vane section. 8. The vortex generation system of claim 1 , wherein the first vane section has a curved geometry. 9. The vortex generation system of claim 1 , wherein the second vane section comprises a first portion configured to pivot about a first end of the second vane section and a second portion configured to pivot about a midpoint of the second vane section. 10. The vortex generation system of claim 1 , further comprising: a generator coupled to the set of turbine blades, the generator configured to generate electrical power from the power extracted by the set of turbine blades. 11. The vortex generation system of claim 1 , wherein the surface heating of the preheated air in the surface momentum boundary layer is produced by waste heat. 12. The vortex generation system of claim 11 , wherein a position of the vanes is adjusted based upon monitored characteristics of the stationary columnar vortex. 13. A method for power extraction from a buoyancy-induced vortex, comprising: establishing a thermal plume; imparting angular momentum to preheated boundary layer air entrained by the thermal plume to form a stationary columnar vortex, the angular momentum imparted to the preheated boundary layer air at a plurality of angles by an array of hybrid vanes distributed on a surface about the thermal plume, where the preheated boundary layer air is heated by surface heating in a surface boundary layer along an uncovered surface surrounding and outside the array of hybrid vanes; and extracting power from the stationary columnar vortex through turbine blades positioned within the stationary columnar vortex. 14. The method of claim 13 , wherein the hybrid vanes of the array comprise a first vane section in the surface boundary layer and an second vane section above the first vane section, where: the first vane section is configured to impart angular momentum at a first angle on the preheated boundary layer air in the surface boundary layer as the preheated boundary layer air is drawn through the first vane section; and the second vane section is configured to impart angular momentum at a second angle on the preheated boundary layer air drawn through the second vane section from a thermal boundary layer outside the array of hybrid vanes. 15. The method of claim 14 , wherein the first vane section is positioned at the first angle and the second vane section is positioned at the second angle. 16. The method of claim 15 , wherein positioning of the second vane section is varied to adjust a core diameter of the stationary columnar vortex. 17. The method of claim 13 , wherein the hybrid vanes of the array are configured to continuously vary in pitch over a vertical height of the hybrid vanes, the variation in pitch imparting angular momentum to the preheated boundary layer air at the plurality of angles. 18. The method of claim 17 , wherein a bottom potion of the hybrid vanes is positioned at a first angle and a top of the hybrid vanes is positioned at a second angle with the pitch of the hybrid vanes continuously varying between the first angle and the second angle. 19. The method of claim 18 , wherein the second angle is varied to adjust a core diameter of the stationary columnar vortex. 20. The method of claim 13 , wherein the thermal plume is established over a nucleating obstruction.