Systems and methods for power generation based on surface air-to-water thermal differences

What is claimed is: 1. An apparatus comprising: first and second tanks each configured to receive and store a refrigerant under pressure; at least one generator configured to generate electrical power based on a flow of the refrigerant between the tanks during each of multiple power generation cycles; and a controller configured to control operation of a vehicle that includes the tanks and the at least one generator, the controller configured to cause the vehicle to dive in order to substantially equalize an amount of the refrigerant in the tanks prior to at least some of the Power generation cycles; wherein the first tank is configured to be one of cooled and warmed by one of ambient air and water to a first temperature; and wherein the second tank is configured to be one of warmed and cooled by another of the ambient air and the water to a second temperature different than the first temperature. 2. The apparatus of claim 1 , further comprising: a heat exchanger configured to exchange thermal energy between the first tank and the ambient air or the water. 3. The apparatus of claim 1 , further comprising: a heat exchanger configured to exchange thermal energy between the second tank and the ambient air or the water. 4. The apparatus of claim 1 , wherein the flow of the refrigerant between the tanks is based on at least one of a temperature differential and a pressure differential between the tanks. 5. The apparatus of claim 1 , further comprising: at least one turbine configured to turn based on the flow of the refrigerant; wherein the at least one generator is configured to generate the electrical power based on the turning of the at least one turbine. 6. The apparatus of claim 1 , further comprising: a first piston configured to move based on the flow of the refrigerant; and a second piston coupled to the first piston, the second piston configured to move hydraulic fluid; wherein the at least one generator is configured to generate the electrical power based on the movement of the hydraulic fluid. 7. The apparatus of claim 1 , wherein the controller is further configured to control the generation of the electrical power based on at least one of: a temperature trend associated with the ambient air; a temperature trend associated with the water; deployment data associated with a course to be traveled or a location of use of the apparatus; a calendar or seasonal timer associated with a time of year; and a power storage trend associated with a power storage of the apparatus. 8. A system comprising: a vehicle comprising a body, a power generation system, and a controller; wherein the power generation system comprises: first and second tanks each configured to receive and store a refrigerant under pressure; and at least one generator configured to generate electrical power based on a flow of the refrigerant between the tanks during each of multiple power generation cycles; wherein the first tank is configured to be one of cooled and warmed by one of ambient air and water to a first temperature; wherein the second tank is configured to be one of warmed and cooled by another of the ambient air and the water to a second temperature different than the first temperature; and wherein the controller is configured to cause the vehicle to dive in order to substantially equalize an amount of the refrigerant in the tanks prior to at least some of the power generation cycles. 9. The system of claim 8 , wherein: the first tank is configured to be cooled or warmed by the ambient air; and the power generation system further comprises a heat exchanger configured to exchange thermal energy between the first tank and the ambient air. 10. The system of claim 9 , wherein the heat exchanger is positioned within the body such that the heat exchanger is above a surface of the water when a portion of the body breaches the surface of the water. 11. The system of claim 8 , wherein: the first tank is configured to be cooled or warmed by the ambient air; and the first tank is positioned within the body such that the first tank is above a surface of the water when a portion of the body breaches the surface of the water. 12. The system of claim 8 , wherein: the second tank is configured to be warmed or cooled by the water; and the power generation system further comprises a heat exchanger configured to exchange thermal energy between the second tank and the water. 13. The system of claim 12 , wherein the heat exchanger is positioned within the body such that the heat exchanger is below a surface of the water when a portion of the body breaches the surface of the water. 14. The system of claim 8 , wherein: the second tank is configured to be warmed or cooled by the water; and the second tank is positioned within the body such that the second tank is below a surface of the water when a portion of the body breaches the surface of the water. 15. The system of claim 8 , wherein: the power generation system further comprises at least one turbine configured to turn based on the flow of the refrigerant; and the at least one generator is configured to generate the electrical power based on the turning of the at least one turbine. 16. The system of claim 8 , wherein: the power generation system further comprises: a first piston configured to move based on the flow of the refrigerant; and a second piston coupled to the first piston, the second piston configured to move hydraulic fluid; and the at least one generator is configured to generate the electrical power based on the movement of the hydraulic fluid. 17. A method comprising: generating electrical power based on a flow of refrigerant between first and second tanks during each of multiple power generation cycles, each of the tanks configured to receive and store the refrigerant under pressure; and controlling operation of a vehicle that includes the tanks, wherein controlling the operation of the vehicle comprises causing the vehicle to dive in order to substantially equalize an amount of the refrigerant in the tanks prior to at least some of the power generation cycles; wherein the first tank is one of cooled and warmed by one of ambient air and water to a first temperature; and wherein the second tank is one of warmed and cooled by another of the ambient air and the water to a second temperature different than the first temperature. 18. The method of claim 17 , wherein: the first tank is cooled or warmed by the ambient air; the second tank is warmed or cooled by the water; and the method further comprises at least one of: exchanging thermal energy between the first tank and the ambient air using a first heat exchanger; and exchanging thermal energy between the second tank and the water using a second heat exchanger. 19. The method of claim 17 , wherein the flow of the refrigerant between the tanks is based on at least one of a temperature differential and a pressure differential between the tanks. 20. The method of claim 17 , wherein: the first tank is cooled or warmed by the ambient air; the second tank is warmed or cooled by the water; the method further comprises causing a portion of the vehicle to breach a surface of the water; the first tank is cooled or warmed based on at least one of: a presence of the first tank above the surface of the water and a presence of a first heat exchanger above the surface of the water; and the second tank is warmed or cooled based on at least one of: a presence of the second ta