Fuel cell system having enhanced CO2 capture

What is claimed is: 1. A carbon dioxide capture system for removing carbon dioxide from a flue gas produced by a combustion power plant, comprising: a molten carbonate electrolysis cell comprising an electrolysis cell anode and an electrolysis cell cathode; a molten carbonate fuel cell comprising a fuel cell anode and a fuel cell cathode; a flue gas supply line connected to the electrolysis cell cathode and configured to supply the flue gas received from the combustion power plant; a first exhaust stream connection line connected to the electrolysis cell cathode and to the fuel cell cathode; and a second exhaust stream connection line connected to the fuel cell anode; wherein the electrolysis cell cathode is configured (i) to receive the flue gas from the flue gas supply line, and (ii) to output a first exhaust stream to the first exhaust stream connection line such that the first exhaust stream comprises a first concentration of carbon dioxide that is greater than a concentration of carbon dioxide in the flue gas; wherein the fuel cell cathode is configured to receive the first exhaust stream from the first exhaust stream connection line; and wherein the fuel cell anode is configured to output a second exhaust stream to the second exhaust stream connection line such that the second exhaust stream comprises a second concentration of carbon dioxide that is greater than the first concentration of carbon dioxide. 2. The system according to claim 1 , wherein the flue gas further comprises oxygen and the first exhaust stream further comprises oxygen, and wherein the first exhaust stream comprises a higher concentration of oxygen than the flue gas. 3. The system according to claim 1 , further comprising a third exhaust stream connection line connected to the electrolysis cell anode, wherein the electrolysis cell anode is configured to output a third exhaust stream comprising hydrogen to the third exhaust stream connection line. 4. The system according to claim 3 , wherein the electrolysis cell anode is configured to output the third exhaust stream such that the third exhaust stream comprises at least 95% hydrogen. 5. The system according to claim 3 , wherein the third exhaust stream connection line is connected to the fuel cell anode, and the fuel cell anode is configured to receive the third exhaust stream from the third exhaust stream connection line. 6. The system according to claim 1 , wherein the fuel cell anode is configured to output the second exhaust stream such that the second exhaust stream comprises about 70% carbon dioxide. 7. The system according to claim 1 , further comprising a sequester system connected to the second exhaust stream connection line, wherein the sequester system is configured to receive the second exhaust stream from the second exhaust stream connection line and configured to cool and condense the second exhaust stream such that liquid carbon dioxide is produced. 8. The system according to claim 3 , further comprising a fourth exhaust stream connection line connected to the molten carbonate fuel cell cathode, wherein the fuel cell is configured to output a fourth exhaust stream to the fourth exhaust stream connection line such that the fourth exhaust stream is substantially depleted of carbon dioxide. 9. A method for removing carbon dioxide from a flue gas produced by a combustion power plant, the method comprising: providing a carbon dioxide capture system comprising: a molten carbonate electrolysis cell comprising an electrolysis cell anode and an electrolysis cell cathode, a molten carbonate fuel cell comprising a fuel cell anode and a fuel cell cathode, a flue gas supply line connected to the electrolysis cell cathode and configured to supply the flue gas received from the combustion power plant, a first exhaust stream connection line connected to the electrolysis cell cathode and to the fuel cell cathode, and a second exhaust stream connection line connected to the fuel cell anode; receiving at the electrolysis cell cathode the flue gas from the flue gas supply line; outputting from the electrolysis cell cathode a first exhaust stream to the first exhaust stream connection line such that the first exhaust stream comprises a first concentration of carbon dioxide that is greater than a concentration of carbon dioxide in the flue gas; receiving at the fuel cell cathode the first exhaust stream from the first exhaust stream connection line; and outputting from the fuel cell anode a second exhaust stream to the second exhaust stream connection line such that the second exhaust stream comprises a second concentration of carbon dioxide that is greater than the first concentration of carbon dioxide. 10. The method according to claim 9 , further comprising a third exhaust stream connection line connected to the electrolysis cell anode, wherein the electrolysis cell anode outputs a third exhaust stream comprising hydrogen to the third exhaust stream connection line. 11. The method according to claim 10 , wherein the electrolysis cell anode outputs the third exhaust stream such that the third exhaust stream comprises at least 95% hydrogen. 12. The method according to claim 10 , wherein the third exhaust stream connection line is connected to the fuel cell anode, and the fuel cell anode is configured to receive the third exhaust stream from the third exhaust stream connection line. 13. The method according to claim 9 , further comprising: providing a sequester system connected to the second exhaust stream connection line, wherein the sequester system receives the second exhaust stream from the second exhaust stream connection line and cools and condenses the second exhaust stream such that liquid carbon dioxide is produced.