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In various aspects, systems and methods are provided for operating a molten carbonate fuel cell assembly at increased power density. This can be accomplished in part by performing an effective amount of an endothermic reaction within the fuel cell stack in an integrated manner. This can allow for in

In various aspects, systems and methods are provided for operating a molten carbonate fuel cell assembly at increased power density. This can be accomplished in part by performing an effective amount of an endothermic reaction within the fuel cell stack in an integrated manner. This can allow for increased power density while still maintaining a desired temperature differential within the fuel cell assembly.

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1. A method for producing a fermented product, the method comprising: introducing a fuel stream comprising a reformable fuel into an anode of a molten carbonate fuel cell, an internal reforming element associated with the anode, or a combination thereof so as to provide a reformable fuel surplus rat

1. A method for producing a fermented product, the method comprising: introducing a fuel stream comprising a reformable fuel into an anode of a molten carbonate fuel cell, an internal reforming element associated with the anode, or a combination thereof so as to provide a reformable fuel surplus ratio of at least 2.0 at an anode fuel utilization of about 50% or less;introducing a cathode inlet stream comprising CO2 and O2 into a cathode of the fuel cell;generating electricity within the molten carbonate fuel cell;separating from the anode exhaust an H2-containing stream, a syngas-containing stream, or a combination thereof;processing biomass to produce at least one fermentation product and a fermentation exhaust; anddistilling the at least one fermentation product, at least some heat for distillation being provided by heat exchange with the anode exhaust, combustion of the syngas-containing stream, combustion of the H2-containing stream, electric heating using the electricity generated within the molten carbonate fuel cell, or a combination thereof,wherein the method further comprises one or more of the following:a) the cathode inlet stream comprises at least a portion of the fermentation exhaust;b) the processing step is done in the presence of H2O separated from the anode exhaust, H2O separated from the syngas-containing stream, H2O separated from the H2-containing stream, or a combination thereof;c) the reformable fuel comprises a portion of the fermentation product, the reformable fuel optionally containing at least 50 vol % of the fermentation product, the portion of the fermentation product optionally being a distilled portion of the fermentation product having a water to carbon ratio of about 1.5:1 to about 3.0:1;d) the processing step comprises separating a substantially fermentable biomass portion from a substantially non-fermentable biomass portion, the substantially non-fermentable biomass portion being processed in one or more thermal, chemical, and/or thermochemical processes in the presence of at least a portion of the H2-containing gas stream, at least a portion of the syngas-containing stream, or a combination thereof;e) an amount of the reformable fuel introduced into the anode of the molten carbonate fuel cell, the internal reforming element associated with the anode of the molten carbonate fuel cell, or the combination thereof, provides a reformable fuel surplus ratio of at least about 2.5;f) a reformable hydrogen content of reformable fuel introduced into the anode of the molten carbonate fuel cell, the internal reforming element associated with the anode of the molten carbonate fuel cell, or the combination thereof, is at least about 50% greater than an amount of hydrogen oxidized to generate electricity;g) an electrical efficiency for the molten carbonate fuel cell is between about 10% and about 40%, and a total fuel cell efficiency for the fuel cell is at least about 55%;h) the molten carbonate fuel cell is operated at a thermal ratio of about 0.25 to about 1.5;i) a ratio of net moles of syngas in the anode exhaust to moles of CO2 in a cathode exhaust is at least about 2.0, and optionally about 40.0 or less;j) a CO2 utilization in the cathode is at least about 60%;k) the molten carbonate fuel cell is operated at a first operating condition to generate electrical power and at least 100 mW/cm2 of waste heat, the first operating condition providing a current density of at least about 150 mA/cm2, and an effective amount of an endothermic reaction is performed to maintain a temperature differential between the anode inlet and an anode outlet of about 80° C. or less;l) the molten carbonate fuel cell is operated at a voltage VA of about 0.60 Volts to about 0.67 Volts;m) the cathode inlet stream comprises at least a portion of a combustion turbine exhaust, at least a portion of the anode exhaust being recycled into the anode;n) the cathode inlet stream comprises at least a portion of a combustion turbine exhaust, at least a portion of the anode exhaust being used as an anode recycle fuel for a combustion zone of the combustion turbine, an optional second fuel stream for the combustion zone of the combustion turbine optionally comprising at least about 30 vol % CO2 and/or at least about 35 vol % of a combination of CO2 and inerts;o) the cathode inlet stream comprises at least a portion of a combustion turbine exhaust, at least a first portion of the anode exhaust being used as an anode recycle fuel for a combustion zone of the combustion turbine, and at least a second portion of the anode exhaust being recycled into the anode of the molten carbonate fuel cell;p) the cathode inlet stream comprises at least a portion of a combustion turbine exhaust, the cathode inlet stream comprising at least about 20 vppm of NOx, and a cathode exhaust comprising less than about half of the NOx content of the cathode inlet stream;q) the method further comprises combusting at least a portion of the H2-containing gas stream to produce electricity, the combusting optionally being done in a combustion zone of a second turbine, and the cathode inlet stream optionally comprising at least a portion of a combustion turbine exhaust generated by combustion of a carbon-containing fuel;r) the method further comprises reacting at least a portion of the syngas-containing stream in the presence of a methanol synthesis catalyst under effective conditions for forming methanol to produce at least one methanol-containing stream and one or more streams comprising gaseous or liquid products, and optionally recycling at least a portion of the one or more streams comprising gaseous or liquid products to form at least a portion of the cathode inlet stream;s) the method further comprises optionally sending one or more CO2-containing streams derived from one or more first refinery processes to the cathode inlet, separating CO2 from at least a portion of the anode exhaust to form a CO2-rich gas stream having a CO2 content greater than a CO2 content of the anode exhaust, and a CO2-depleted gas stream having a CO2 content less than the CO2 content of the anode exhaust, and delivering the CO2-depleted gas stream to one or more second refinery processes;t) the method further comprises separating CO2 from at least a portion of the anode exhaust to produce a CO2-rich stream having a CO2 content greater than a CO2 content of the anode exhaust and a CO2-depleted gas stream having an H2 content greater than an H2 content of the anode exhaust, and using at least a portion of the CO2-depleted gas stream in an ammonia synthesis process, in a process for synthesis of an organic nitrogen-containing compound, or in both;u) the method further comprises withdrawing, from an anode exhaust, a first gas stream comprising CO, the anode exhaust having a pressure of about 500 kPag or less, introducing the first gas stream withdrawn from the anode exhaust into a process for production of iron and/or steel, and optionally withdrawing a second gas stream comprising H2 from the anode exhaust and, if withdrawn, using the second gas stream as fuel for heating in the process for production of iron and/or steel;v) the method further comprises generating an anode exhaust comprising H2, CO, H2O, and at least about 20 vol % CO2, reacting at least a portion of the anode exhaust under effective Fischer-Tropsch conditions in the presence of a shifting Fischer-Tropsch catalyst to produce at least one gaseous product and at least one non-gaseous product, wherein a CO2 concentration in the at least a portion of the anode exhaust is at least 80% of a CO2 concentration in the anode exhaust, and recycling at least a portion of the at least one gaseous product to the cathode inlet;w) the method further comprises generating an anode exhaust comprising H2, CO, CO2, and H2O, and having a ratio of H2 to CO of at least about 2.5:1, reducing the ratio of H2 to CO in at least a portion of the anode exhaust to a ratio of about 1.7:1 to about 2.3:1 to form a classic syngas stream, which also has a CO2 concentration that is at least 60% of a CO2 concentration in the anode exhaust, reacting the classic syngas stream under effective Fischer-Tropsch conditions in the presence of a non-shifting Fischer-Tropsch catalyst to produce at least one gaseous product and at least one non-gaseous product, and optionally recycling at least a portion of the at least one gaseous product to the cathode inlet; andx) the method further comprises generating an anode exhaust: comprising H2, CO, and CO2, having a ratio of H2 to CO of at least about 2.5:1, and having a CO2 content of at least about 20 vol %, removing water and CO2 from at least a portion of the anode exhaust to produce an anode effluent gas stream, the anode effluent gas stream having a concentration of water that is less than half of a concentration of water in the anode exhaust, having a concentration of CO2 that is less than half of a concentration of CO2 in the anode exhaust, or a combination thereof, the anode effluent gas stream also having a ratio of H2 to CO of about 2.3:1 or less, and reacting at least a portion of the anode effluent gas stream over a non-shifting Fischer-Tropsch catalyst to produce at least one gaseous product and at least one non-gaseous product. 2. The method of claim 1, wherein the cathode inlet stream comprises at least a portion of the anode exhaust, at least a portion of any gas stream withdrawn from the anode exhaust, or a combination thereof. 3. The method of claim 1, wherein the cathode inlet stream comprises at least a portion of an exhaust from a combustion reaction, an exhaust from a combustion turbine, or a combination thereof. 4. The method of claim 1, wherein CO2 is separated from the anode exhaust, from any gas stream withdrawn from the anode exhaust, or a combination thereof, at least a portion of the separated CO2 optionally being combined with a at least a portion of the fermentation exhaust. 5. The method of claim 1, wherein H2O is separated from the anode exhaust, from any gas stream withdrawn from the anode exhaust, or a combination thereof. 6. The method of claim 1, further comprising separating H2O from the anode exhaust, and using the separated H2O during the processing of the biomass to produce the at least one fermentation product. 7. The method of claim 1, wherein generating electricity within the molten carbonate fuel cell comprises operating the fuel cell at a fuel utilization, the fuel utilization being selected based on at least one of an electrical demand of the processing of the biomass, a heat demand of the processing of the biomass, and a heat demand of the distillation of the fermentation product. 8. The method of claim 1, wherein the at least one fermentation product comprises ethanol. 9. The method of claim 1, further comprising separating from an anode exhaust a CO2-rich stream, and using the CO2-rich stream as part of a photosynthetic algae growth process. 10. The method of claim 1, wherein the reformable fuel is derived from algae biomass generated in an algae growth pond. 11. The method of claim 1, further comprising separating from an anode exhaust a CO2-rich stream, and sending at least a portion of the CO2-rich stream to the cathode inlet. 12. The method of claim 1, wherein at least some of the heat for distillation is provided based on combustion of a fermentation product. 13. The method of claim 1, wherein the anode exhaust has a molar ratio of H2:CO of at least about 3.0:1. 14. The method of claim 1, wherein the molten carbonate fuel cell is operated at a thermal ratio of about 0.25 to about 1.15. 15. The method of claim 1, wherein the reformable fuel is derived from biomass by anaerobic digestion of biomass residue produced by the processing of the biomass. 16. The method of claim 15, wherein at least some of the reformable fuel is derived from biomass by partial oxidation and/or gasification of biomass residue produced by the processing of the biomass.