Power producing gas separation system and method

I claim: 1. A power producing system configured to utilize a flue gas output from a flue gas generating assembly, wherein the flue gas comprises carbon dioxide and oxygen and the power producing system comprises: a first heat exchanger configured to receive the flue gas output from the flue gas generating assembly, and adjust a temperature of the flue gas to be in a range of 500-650° C.; a fuel cell comprising an anode section and a cathode section, the cathode section of the fuel cell being configured to receive inlet oxidant gas that contains the flue gas output from the first heat exchanger; and a gas separation assembly configured to receive anode exhaust output from the anode section of the fuel cell and comprising: a chiller assembly configured to cool the anode exhaust to a predetermined temperature so as to liquefy carbon dioxide in the anode exhaust, a gas separation device configured to receive the anode exhaust cooled by the chiller assembly and separate the liquefied carbon dioxide from residual fuel gas, and a heat recovery assembly configured to recover waste heat from cathode exhaust output from the cathode section of the fuel cell, wherein the heat recovery assembly and the chiller assembly are configured such that said waste heat recovered by the heat recovery assembly is utilized to drive the chiller assembly; and an oxidizer configured to receive residual fuel gas separated by the gas separation device, receive temperature-adjusted flue gas directly from the first heat exchanger, oxidize the residual fuel gas to heat the flue gas, and output heated flue gas directly to the cathode section of the fuel cell. 2. The power producing system of claim 1 , wherein the cathode section of the fuel cell is configured to receive inlet oxidant gas that consists of all or part of the flue gas output by the flue gas generating assembly. 3. The power producing system of claim 1 , wherein the chiller assembly comprises one or more absorption chillers. 4. The power producing system of claim 1 , wherein the gas separation assembly further comprises a water removal assembly configured to separate water from the anode exhaust and output water-separated anode exhaust, wherein the chiller assembly is configured to receive the water-separated anode exhaust. 5. The power producing system of claim 4 , wherein the gas separation assembly further includes a compressor configured to compress the water-separated anode exhaust output from the water removal assembly prior to the water-separated anode exhaust being conveyed to the chiller assembly. 6. The power producing system of claim 4 , wherein the gas separation assembly further includes a shift reactor configured to convert carbon monoxide in the anode exhaust to carbon dioxide prior to the anode exhaust being conveyed to the water removal assembly. 7. The power producing system of claim 1 , wherein the first heat exchanger is configured to utilize waste heat in the cathode exhaust for heating the flue gas output by the flue gas generating assembly to the temperature in the range of 500-650° C. 8. The power producing system of claim 5 , wherein the compressor is configured to compress the anode exhaust to at least 200 psi and wherein the chiller assembly is configured to chill the anode exhaust to −40° C. or warmer based on the compressor outlet pressure. 9. The power producing system of claim 1 , wherein the fuel cell is an internal reforming Molten Carbonate Fuel Cell (MCFC). 10. The power producing system of claim 1 , further comprising said flue gas generating assembly. 11. The power producing system of claim 1 , wherein the gas separation device comprises a flash drum. 12. The power production system of claim 10 , wherein the cathode section of the fuel cell is configured to receive inlet oxidant gas that exclusively consists of all or part of the flue gas output by the flue gas generating assembly. 13. The power producing system of claim 1 , wherein the flue gas generating assembly is selected from the group consisting of (i) a fossil-fueled flue gas generating assembly, (ii) a boiler, (iii) a combustor, and (iv) a furnace and a kiln of a cement factory. 14. The power producing system of claim 1 , further comprising a second heat exchanger configured to utilize waste heat in the cathode exhaust for heating fuel gas to be input to the anode section. 15. A gas separation method for use in a power producing system utilizing a flue gas output from a flue gas generating assembly, wherein the flue gas comprises carbon dioxide and oxygen and the method comprises: receiving the flue gas output from the flue gas generating assembly at a first heat exchanger; using the first heat exchanger to adjust a temperature of the flue gas to be in a range of 500-650° C.; outputting the temperature-adjusted flue gas from the first heat exchanger directly to an oxidizer; operating a fuel cell having an anode section and the cathode section, wherein anode exhaust is output from the anode section of the fuel cell during operating of the fuel cell; recovering waste heat from cathode exhaust output from the cathode section of the fuel cell; cooling the anode exhaust to a predetermined temperature in a chiller assembly so as to liquefy the carbon dioxide in the anode exhaust while utilizing the waste heat from the cathode exhaust to drive the chiller assembly; and after cooling the anode exhaust in the chiller assembly, separating the liquefied carbon dioxide from residual fuel gas in a gas separation device; wherein the oxidizer receives residual fuel gas separated in the separating step and the temperature-adjusted flue gas from the first heat exchanger, oxidizes the residual fuel gas to heat the flue gas, and outputs heated flue gas directly to the cathode section of the fuel cell. 16. The gas separation method of claim 15 , wherein all or part of the flue gas output by the flue gas generating assembly is provided to the cathode section of the fuel cell exclusively as the inlet oxidant gas. 17. The gas separation method of claim 15 , wherein the chiller assembly comprises one or more absorption chillers. 18. The gas separation method of claim 15 , further comprising separating water from the anode exhaust and outputting water-separated anode exhaust prior to separating the carbon dioxide and the residual fuel in the anode exhaust. 19. The gas separation method of claim 18 , further comprising compressing water-separated anode exhaust prior to separating the carbon dioxide and the residual fuel in the anode exhaust. 20. The gas separation method of claim 19 , further comprising converting carbon monoxide in the anode exhaust to carbon dioxide prior to separating water from the anode exhaust. 21. The gas separation method of claim 15 , wherein the first heat exchanger utilizes waste heat recovered from the cathode exhaust for heating the flue gas output by the flue gas generating assembly to the temperature in the range of 500-650° C. 22. The gas separation method of claim 19 , wherein said compressing comprises compressing the water-separated anode exhaust to at least 200 psi and wherein the predetermined temperature is −40° C. or warmer. 23. The gas separation method of claim 15 , wherein the flue gas generating assembly is a fossil-fueled flue gas generating assembly. 24. The gas separation method of claim 15 , wherein the flue gas generating assembly is a boiler. 25. The gas separa