Natural gas extraction using renewable energy

The invention claimed is: 1. A method of recovering natural gas from a subterranean hydrocarbon reservoir, comprising: applying an electrical current to a liquid condensation prevention system to heat a heat conducting element, wherein the electrical current is generated from at least one renewable energy source, wherein the liquid condensation prevention system comprising: the heat conducting element being positioned within a wellbore located in the subterranean hydrocarbon reservoir, wherein the heat conducting element is connected to a production tubing having a producing end disposed in the subterranean hydrocarbon reservoir and a recovery end located outside the wellbore, and wherein the production tubing is configured to pass gaseous natural gas from the producing end of the production tubing in the subterranean hydrocarbon reservoir to the recovery end of the production tubing outside the wellbore; the heat conducting element being electrically coupled with the at least one renewable energy source; the heat conducting element being in thermal communication with the subterranean hydrocarbon reservoir; applying the electrical current such that a temperature of the subterranean hydrocarbon reservoir at the producing end of the tubing remains above a cricondentherm temperature of the natural gas; monitoring a production rate of the subterranean hydrocarbon reservoir to identify a final production time, wherein the production rate matches a predetermined production rate at the final production; adjusting temperature of the subterranean hydrocarbon reservoir at the producing end to prevent liquid condensation at the final production time by adjusting the electrical current from the at least one renewable energy source; and recovering the natural gas from the subterranean hydrocarbon reservoir, wherein the at least one renewable energy source is solar energy and the solar energy is received by a solar cell, wherein a shunt resistance is greater than a load resistance of the solar cell, and wherein a load resistance is greater than a series resistance of the solar cell. 2. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the temperature of the subterranean hydrocarbon reservoir at the producing end is above the cricondentherm temperature of the natural gas by a temperature within a range of 100 Fahrenheit (° F.)-150° F. 3. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the final production time is within a range of 1000 hours-1500 hours. 4. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein a measured wellbore pressure value at the final production time is approximately half of an initial wellbore pressure value, wherein the measured wellbore pressure value and the initial wellbore pressure value are measured within the wellbore. 5. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the cricondentherm temperature can be achieved up to a distance within a range of 0.5 feet (ft)-2.5 ft from the wellbore during a subterranean hydrocarbon reservoir shut-in. 6. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the heat conducting element is a metal section perimetrically surrounding the wellbore. 7. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the heat conducting element is a current transformer, comprising: a primary winding; a secondary winding; the primary winding being electrically coupled with the secondary winding, wherein the electrical current applied to the primary winding induces a proportional electrical current at the secondary winding which is positioned adjacent the producing end of the production tubing; and the secondary winding being in thermal communication with the subterranean hydrocarbon reservoir, wherein heat generated at the secondary winding from the proportional electrical current is transferred to the subterranean hydrocarbon reservoir via conduction. 8. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the subterranean hydrocarbon reservoir is heated via electromagnetic heating: the heat conducting element is a conducting surface magnetically coupled with at least one magnet, comprising: inducing eddy currents on the conducting surface by changing a magnetic field applied to the conducting surface, wherein the magnetic field is changed via relative motion between the at least one magnet and the conducting surface; and dissipating heat into the subterranean hydrocarbon reservoir, wherein the eddy currents flowing through a resistance of the conducting surface generates heat. 9. The method of recovering natural gas from a subterranean hydrocarbon reservoir as of claim 1 , wherein the heat conducting element is at least one electric heating cable vertically suspended into the wellbore.