Cell voltage control through oxygen starvation for fuel cell systems

What is claimed is: 1. A vehicle power system comprising: a fuel cell including an oxidant inlet valve and an oxidant outlet valve; an external circuit connected to the fuel cell and having electrical contacts that move to and from an opened position and a closed position such that in the closed position and during operation the fuel cell powers an electric machine connected to the external circuit; and a controller programmed to initiate a command to supply an oxidant to the fuel cell such that responsive to a load being greater than a threshold amount, the controller positions the oxidant inlet valve and the oxidant outlet valve to provide an amount of oxidant to the fuel cell that is 80-100% of a full-capacity amount, and responsive to the load being less than the threshold amount, the controller positions the oxidant inlet valve and the oxidant outlet valve to provide an amount of oxidant to the fuel cell that is less than 80% of the full-capacity amount, and move the electrical contacts to the closed position prior to a current request and subsequent to metering the amount of oxidant such that a voltage increase of the fuel cell does not exceed a threshold voltage increase amount. 2. The vehicle power system of claim 1 , wherein the controller is programmed to meter the amount of oxidant via the oxidant inlet valve and the oxidant outlet valve such that a voltage of the fuel cell does not exceed a threshold voltage. 3. The vehicle power system of claim 1 , wherein the command to supply the oxidant to the fuel cell is executed during a start-up, idling, or stop event. 4. The vehicle power system of claim 1 , wherein the threshold amount is more than an idling load. 5. A vehicle comprising the electric machine connected to the external circuit of the vehicle power system of claim 1 . 6. A power system comprising: a fuel cell including an oxidant inlet valve and an oxidant outlet valve; an external circuit connected to the fuel cell and having electrical contacts that move to and from an opened position and a closed position such that in the closed position and during operation the fuel cell powers an electric machine connected to the external circuit; and a controller programmed to initiate a command to supply an oxidant to the fuel cell such that responsive to a load being greater than a threshold amount, the controller positions the oxidant inlet valve and the oxidant outlet valve to provide an amount of oxidant to the fuel cell that is 80-100% of a full-capacity amount, and responsive to the load being less than the threshold amount, the controller positions the oxidant inlet valve and oxidant outlet valve to provide an amount of oxidant to the fuel cell that is less than 80% of the full-capacity amount, and position the oxidant inlet valve and the oxidant outlet valve to meter the amount of oxidant and subsequently move the electrical contacts to the closed position such that a voltage increase of the fuel cell does not exceed a threshold voltage increase amount. 7. The vehicle power system of claim 1 , further comprising a bypass valve between a compressor in fluid communication with the fuel cell and the oxidant inlet valve, wherein the bypass valve is configured to release the oxidant such that the compressor does not exceed a threshold pressure. 8. The vehicle power system of claim 1 , wherein the oxidant inlet valve is configured to be positioned at a position, between open and close, corresponding to a predetermined voltage increase rate. 9. The vehicle power system of claim 1 , further comprising an additional valve downstream of the oxidant outlet valve, the additional valve being configured to coordinate with the oxidant inlet valve and the oxidant outlet valve to manage the amount of oxidant supplied to a cathode of the fuel cell. 10. The vehicle power system of claim 1 , wherein the oxidant inlet valve is configured to manage the amount of oxidant provided to a cathode of the fuel cell during a low load event as long as the fuel cell was previously in a hydrogen-protective-state. 11. The vehicle power system of claim 1 , wherein the oxidant inlet valve is configured to manage the amount of oxidant provided to a cathode of the fuel cell by ramping-up an oxidant flow rate. 12. The vehicle power system of claim 1 , wherein the oxidant inlet valve is configured to manage the amount of oxidant provided to a cathode of the fuel cell by stepping-up an oxidant flow rate when the fuel cell was not previously in a hydrogen-protective-state. 13. The power system of claim 6 , wherein the controller is programmed to meter the amount of oxidant via the oxidant inlet valve and the oxidant outlet valve such that a voltage of the fuel cell does not exceed a threshold voltage. 14. A vehicle comprising an electric machine configured to be powered by the power system of claim 6 .