Deep heat recovery gas turbine engine

We claim: 1. A method comprising: receiving a flow of a working fluid at a first heat exchanger of a gas turbine engine, the working fluid being a supercritical fluid; transferring, in the first heat exchanger, heat from the flow of the working fluid to a compressed air flow received from an air compressor of the gas turbine engine to reduce a temperature of the flow of the working fluid below a first threshold, the air compressor being fluidly coupled with a combustor of the gas turbine engine; receiving the flow of the working fluid from the first heat exchanger at a second heat exchanger of the gas turbine engine, the second heat exchanger being coupled in series with the first heat exchanger, the second heat exchanger transferring heat out of the flow of the working fluid to an ambient air flow to reduce the temperature of the flow of the working fluid from below the first threshold to below a second threshold; receiving the flow of the working fluid from the second heat exchanger at a fluid compressor and compressing the flow of the working fluid with the fluid compressor to increase the temperature of the flow of the working fluid from below the second threshold to above the second threshold; and receiving the compressed flow of the working fluid from the fluid compressor at a third heat exchanger, the third heat exchanger transferring heat from an exhaust output gas produced by the combustor to the compressed flow of the working fluid. 2. The method of claim 1 , wherein transferring heat out of the flow of the working fluid to the ambient air flow to reduce the temperature of the flow of the working fluid from below the first threshold to below the second threshold comprises reducing the temperature of the flow of the working fluid below a critical point and performing heat rejection in a transcritical mode of the working fluid. 3. The method of claim 1 , wherein transferring heat out of the flow of the working fluid to the ambient air flow to reduce the temperature of the flow of the working fluid from below the first threshold to below the second threshold comprises reducing the temperature of the flow of the working fluid to be above the critical point and performing heat rejection in a supercritical mode of the working fluid. 4. The method of claim 1 , wherein receiving the flow of the working fluid at the first heat exchanger comprises receiving the flow of the working fluid as a decompressed flow of working fluid output by an expander, the expander decompressing the flow of the working fluid following compression of the flow of working fluid by the fluid compressor. 5. A system comprising: an air compressor configured to compress a flow of intake air; a combustor configured to receive the compressed flow of intake air and provide exhaust output gas to produce thrust for an aircraft; a fluid compressor configured to compress a working fluid, the working fluid being carbon dioxide; an expander coupled to the fluid compressor and configured to receive and expand the compressed working fluid to generate mechanical energy and output a decompressed working fluid, wherein a temperature of the working fluid is reduced as the compressed working fluid expands; a compressed air heat exchanger positioned ahead of an inlet of the combustor and configured to recuperatively transfer heat from the decompressed working fluid to the compressed flow of intake air; an exhaust output gas heat exchanger positioned after an outlet of the combustor and configured to recuperatively transfer heat from the exhaust output gas of the combustor to the compressed working fluid; and an ambient air heat exchanger positioned to receive an ambient air flow and transfer heat from the decompressed working fluid into the ambient air flow to lower a temperature of the decompressed working fluid to within a temperature range of a transcritical mode of the working fluid. 6. The system of claim 5 , further comprising a working fluid heat exchanger positioned between the expander and the fluid compressor and configured to recuperatively transfer heat from the decompressed working fluid to the compressed working fluid. 7. The system of claim 5 , wherein at least two of the fluid compressor, the expander, or the air compressor are configured to rotate on respective separate and independent shafts. 8. The system of claim 5 , wherein the ambient air heat exchanger is a recuperative heat exchanger, and the ambient air flow heated by the ambient air heat exchanger comprises at least part of the flow of intake air provided to the air compressor. 9. The system of claim 5 , wherein the ambient air heat exchanger is a heat rejection heat exchanger, and the ambient air flow heated by the ambient air heat exchanger is a bypass air stream. 10. The system of claim 5 , wherein the fluid compressor, the expander, and the air compressor are all rotatably coupled to a single common shaft. 11. The system of claim 10 , wherein the single common shaft is coupled with a fan. 12. The system of claim 10 , wherein the single common shaft is coupled with a gear box. 13. A system comprising: a gas turbine engine comprising an air compressor fluidly coupled with a combustor, wherein the combustor is configured to provide an exhaust output gas; a first heat exchanger coupled in series with a second heat exchanger in a flow path of a working fluid to sequentially transfer heat out of the working fluid, the working fluid being a supercritical fluid; the first heat exchanger configured to recuperatively transfer heat from the working fluid to a compressed air flow received from the air compressor to reduce a temperature of the working fluid below a first threshold, and the second heat exchanger configured to transfer heat from the working fluid to an ambient air flow to reduce the temperature of the working fluid from below the first threshold to below a second threshold; a compressor included in the flow path downstream of the second heat exchanger, the compressor configured to receive the working fluid below the second threshold and compress the working fluid to increase the temperature of the compressed working fluid above the second threshold; and a third heat exchanger included in the flow path following the compressor, the third heat exchanger configured to recuperatively transfer heat from the exhaust output gas of the combustor to the compressed working fluid to increase the temperature of the compressed working fluid above a third threshold, the third threshold being greater than the first threshold. 14. The system of claim 13 , wherein the compressed air flow recuperatively heated by the first heat exchanger is provided to the combustor, the combustor configured to receive the compressed air flow recuperatively heated by the first heat exchanger and provide thrust for the gas turbine engine. 15. The system of claim 13 , wherein, the working fluid is carbon dioxide. 16. The system of claim 13 , further comprising an expander included in the flow path between the first heat exchanger and the third heat exchanger, the expander configured to receive and decompress the compressed working fluid received from the third heat exchanger and to output decompressed working fluid for receipt by the first heat exchanger as the working fluid. 17. The system of claim 13 , further comprising a fourth heat exchanger coupled in the flow path between the expander and the first heat exchanger, and between the compressor and third heat exchanger, the fourth heat exchanger configured to recuperatively transfer heat from the decompressed working