High temperature synthesis for power production and storage

The invention claimed is: 1. A high-pressure reservoir for containing a fluid comprising: a shaft bored into ground and the high pressure fluid reservoir in the shaft, wherein the high pressure fluid reservoir comprises a cylindrical wall; wherein the cylindrical wall sired to engage the shaft bored into the ground, the shaft having an upper end and a lower end; a bottom end cap fixed to a lower end of the cylindrical wall, wherein the bottom end cap is configured to engage the lower end of the shaft; a top end cap fixed to an upper end of the cylindrical wall wherein the top end cap is concave such that the top end cap extends below a top end of the cylindrical wall, wherein the bottom end cap, the top end cap, and the cylindrical wall define a subterranean chamber; a plug comprising a composite material, the plug having a lower face disposed on the concave top end cap and a peripheral face engaging the shaft; and at least one pressure port extending downwardly into the shaft and through the plug and the top end cap, the pressure port defining a fluid path to the subterranean chamber. 2. The high-pressure reservoir of claim 1 , wherein the reservoir is configured to retain fluid at pressures of at least 30 MPa. 3. The high-pressure reservoir of claim 1 , wherein the chamber has a volume of at least 21,000 cubic meters. 4. The high-pressure fluid storage reservoir of claim 1 , further comprising a plurality of rock bolts that are fixedly embedded in the plug and extend into rock surrounding the shaft. 5. The high-pressure fluid storage reservoir of claim 1 , wherein the cylindrical wall is grouted to the shaft. 6. The high-pressure fluid storage reservoir of claim 1 , wherein the composite material comprises concrete. 7. The high-pressure fluid storage reservoir of claim 1 , wherein the bottom end cap is convex. 8. The high-pressure fluid storage reservoir of claim 1 , further comprising an excavated material disposed in the shaft over the plug. 9. The high-pressure fluid storage reservoir of claim 1 , wherein the at least one pressure port comprises a plurality of high-pressure ports. 10. The high-pressure fluid storage reservoir of claim 1 , further comprising an above-ground containment portion disposed over the cylindrical wall and spaced apart from the cylindrical wall, wherein the at least one high-pressure port extends into the above-ground containment portion. 11. The high-pressure fluid storage reservoir of claim 10 , wherein the subterranean chamber is configured to retain nitrogen and the above-ground chamber is configured to retain liquid ammonia. 12. A method for constructing a fluid reservoir comprising: boring a shaft; constructing a fluid reservoir in the shaft, wherein the fluid reservoir comprises a cylindrical wall having an upper end and a lower end, a bottom end cap fixed to a lower end of the cylindrical wall wherein the bottom end cap is configured to engage the lower end of the shaft, and a top end cap fixed to an upper end of the cylindrical wall wherein the top end cap is concave such that the top end cap extends below a top end of the cylindrical wall, wherein the bottom end cap, the top end cap, and the cylindrical wall cooperatively define a subterranean chamber, wherein the fluid reservoir further comprises mortar that connects the fluid reservoir directly to a wall of the shaft; applying a plug comprising a composite material onto the fluid reservoir such that the plug covers the concave top end cap and directly engages the shaft; and at least one pressure port extending downwardly into the shaft and through the plug and the top end cap, the pressure port defining a fluid path to the subterranean chamber. 13. The method of claim 12 wherein the reservoir is configured to retain fluid at pressures of at least 30 MPa. 14. The method of claim 12 , wherein the subterranean chamber has a volume of at least 21,000 cubic meters. 15. The method of claim 12 , further comprising installing a plurality of rock bolts that are embedded in the plug and extend into rock surrounding the shaft. 16. The method of claim 12 , wherein the composite material comprises concrete. 17. The method of claim 12 , wherein the bottom end cap is convex. 18. The method of claim 12 , further comprising depositing excavated materials in the shaft onto the plug. 19. The method of claim 12 , further comprising an upper chamber comprising an above-ground chamber that is fluidly connected to the lower chamber by the at least one pressure port. 20. The method of claim 19 , wherein the lower chamber is configured to retain nitrogen and the above-ground chamber is configured to retain liquid ammonia.