Alternative path cooling of a high temperature fuel cell

What is claimed is: 1. A method for thermally managing a fuel cell provided on a vehicle, with an ambient environment surrounding the vehicle, the method comprising: directing oxygen to a reactant portion of the fuel cell from an oxygen source continuously closed from the ambient environment surrounding the vehicle; directing fuel to the reactant portion of the fuel cell from a fuel source continuously closed from the ambient environment surrounding the vehicle; utilizing the oxygen and fuel in a chemical reaction within the reactant portion of the fuel cell to create a product and waste heat; capturing a non-reactant ambient coolant from the ambient environment surrounding the vehicle; directing an entire portion of the non-reactant ambient coolant to a non-reactant portion of the fuel cell, wherein the non-reactant portion of the fuel cell is thermally coupled to, and isolated from direct fluid communication with, the reactant portion of the fuel cell, so that the non-reactant ambient coolant is completely isolated from the oxygen and fuel, the non-reactant ambient coolant absorbing a portion of the waste heat from the reactant portion of the fuel cell to create heated coolant; and directing the heated coolant from the non-reactant portion of the fuel cell. 2. The method of claim 1 , wherein directing an entire portion of the non-reactant ambient coolant to the non-reactant portion of the fuel cell comprises directing ram air through the non-reactant portion of the fuel cell to create heated air. 3. The method of claim 1 , wherein directing an entire portion of the non-reactant ambient coolant to the non-reactant portion of the fuel cell comprises directing ambient airflow through a compressor configured to pressurize the ambient airflow and to direct the ambient airflow to the non-reactant portion of the fuel cell. 4. The method of claim 3 , further comprising directing the heated coolant from the non-reactant portion of the fuel cell, in the form of heated ambient airflow, through a turbine configured to drive the compressor. 5. The method of claim 1 , further comprising directing the heated coolant from the non-reactant portion of the fuel cell through a turbine configured to create mechanical energy from a flow of the heated coolant, wherein the turbine is coupled to a generator, enabling production of electricity from the mechanical energy created by the turbine. 6. The method of claim 1 , further comprising directing a portion of the heated coolant from the non-reactant portion of the fuel cell to the non-reactant ambient coolant prior to directing the non-reactant ambient coolant to the non-reactant portion of the fuel cell to increase a temperature of the non-reactant ambient coolant and decrease a temperature differential between the non-reactant ambient coolant and the reactant portion of the fuel cell. 7. A method for thermally managing a fuel cell provided on a vehicle, with an ambient environment surrounding the vehicle, the method comprising: directing oxygen to a reactant portion of the fuel cell from an oxygen source continuously closed from the ambient environment surrounding the vehicle; directing fuel to the reactant portion of the fuel cell from a fuel source continuously closed from the ambient environment surrounding the vehicle, wherein the oxygen and fuel chemically react within the reactant portion of the fuel cell to create a product and waste heat; directing a non-reactant airflow, from the ambient environment surrounding the vehicle through a compressor operative to pressurize the non-reactant airflow; directing an entire portion of the non-reactant airflow pressurized in the compressor to a non-reactant portion the fuel cell, wherein the non-reactant portion of the fuel cell is thermally coupled to, and isolated from direct fluid communication with, the reactant portion of the fuel cell, so that the non-reactant ambient coolant is completely isolated from the oxygen and fuel; transferring waste heat from the reactant portion of the fuel cell to the non-reactant airflow via the non-reactant portion of the fuel cell to create a waste heat airflow; directing the waste heat airflow out of the non-reactant portion of the fuel cell to a turbine to create mechanical energy; and utilizing the mechanical energy from the turbine to drive the compressor. 8. The method of claim 7 , further comprising utilizing the mechanical energy from the turbine to drive a generator. 9. The method of claim 7 , further comprising recirculating a portion of the waste heat airflow to the non-reactant airflow prior to directing an entire portion of the non-reactant airflow from the compressor to the non-reactant portion of the fuel cell to increase a temperature of the non-reactant airflow and decrease a temperature differential between the non-reactant airflow and the reactant portion of the fuel cell.