A method of supplying crushed alkaline carbonate from a carbonate resource to a first calcining site having a design calcining capacity; solar calcining crushed carbonate within a prescribed carbon dioxide (CO2) delivery distance from a first enhancement location within a first hydrocarbon resource,
A method of supplying crushed alkaline carbonate from a carbonate resource to a first calcining site having a design calcining capacity; solar calcining crushed carbonate within a prescribed carbon dioxide (CO2) delivery distance from a first enhancement location within a first hydrocarbon resource, whereby generating CO2 with a local CO2 generating capacity and an alkaline oxide; forming a first enhancing fluid comprising generated CO2 and delivering it into the first enhancement site having an injector well weighted first enhancement location, whereby mobilizing hydrocarbon in the first enhancement site; producing a produced fluid comprising mobilized hydrocarbon and enhancing fluid; recovering liquid hydrocarbon from the produced fluid; wherein the prescribed CO2 delivery distance is less than 67% of a remote CO2 delivery distance, to the first enhancement location from a remote calcining site having an equal or greater design calcined CO2 generating capacity. Then solar calcining CO2 to enhance a second site.
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1. A calcining-EOR method of enhancing hydrocarbon recovery, using crushed carbonate having carbon dioxide (herein CO2) compounded with an alkaline-earth or alkali oxide, comprising: supplying crushed carbonate from a carbonate resource to a solar first calciner at a first calcining site having a lo
1. A calcining-EOR method of enhancing hydrocarbon recovery, using crushed carbonate having carbon dioxide (herein CO2) compounded with an alkaline-earth or alkali oxide, comprising: supplying crushed carbonate from a carbonate resource to a solar first calciner at a first calcining site having a local design solar calcined CO2 generating capacity;calcining the crushed carbonate at the first calcining site located within a prescribed solar CO2 delivery distance from a first enhancement location at a first enhancement site within a first hydrocarbon resource;forming a first enhancing fluid from captured CO2 comprising a portion of the solar generated CO2;injecting a portion of the first enhancing fluid into the first enhancement site, through enhancement injector wells; whereby mobilizing hydrocarbon in the first enhancement site having an enhancement injector well weighted first enhancement location;producing a produced fluid from the first enhancement site; andrecovering a liquid hydrocarbon from the produced fluid;wherein the prescribed solar CO2 delivery distance is less than about 67% of a remote CO2 delivery distance to the first enhancement location from a remote calcining site having an equal or greater remote design calcined CO2 generating capacity than the local design solar calcined CO2 generating capacity. 2. The calcining-EOR method of claim 1, wherein adjusting the number of injection wells to which enhancing fluid is delivered within the first enhancement site in proportion to the rate of carbon dioxide being captured plus the rate of CO2 being recycled, while delivering CO2 at a delivery rate greater than a 0.1 hydrocarbon pore volume HCPV per year of hydrocarbon resource encompassed by a plurality of production wells surrounding the injection wells. 3. The calcining-EOR method of claim 1, wherein supplying crushed carbonate to solar second calciner at a second calcining site located within 50% of the remote CO2 delivery distance from the first hydrocarbon resource. 4. The calcining-EOR method of claim 1, further comprising solar calcining carbonate at a second calcining site near the first hydrocarbon resource, forming a second enhancing fluid comprising solar calcined CO2, delivering the second enhancing fluid into a production enhancement site in the first hydrocarbon resource analogous to the first enhancement site, and recovering mobilized hydrocarbon from the production enhancement site. 5. The calcining-EOR method of claim 1, wherein supplying crushed carbonate comprises surface mining—crushing the carbonate resource with a rotating drum surface miner, and screening the crushed carbonate such that 98% is smaller than about 102 mm (4″) in size. 6. The calcining-EOR method of claim 1, further comprising transporting a portion of the generated alkaline oxide to a demand site farther away from the first calcining site than the remote CO2 delivery distance. 7. The calcining-EOR method of claim 3, further comprising injecting enhancing fluid into a first plurality of injection wells; initially delivering blocking fluid into a second plurality of peripheral injection wells surrounding the first plurality of injection wells at the first enhancement site, followed by injecting enhancing fluid into the second plurality of peripheral wells. 8. The calcining-EOR method of claim 1, wherein beginning delivery of enhancing fluid before a primary hydrocarbon production declines to about 75% of a peak primary hydrocarbon production. 9. The calcining-EOR method of claim 1, wherein calcining carbonate using indirect heating comprising one of heat recuperation and heat regeneration. 10. The calcining-EOR method of claim 1, wherein using CO2 alternating an aqueous fluid comprising water to enhance hydrocarbon recovery. 11. A calcining hydrocarbon recovery method, comprising: surface mining an alkaline carbonate at a carbonate site in a carbonate resource comprising carbon dioxide (herein CO2) compounded with one or more alkaline oxides of calcium and/or magnesium;crushing mined carbonate and supplying crushed carbonate to a first calcining site;solar calcining a portion of the crushed carbonate at the first calcining site, whereby solar generating CO2 and an alkaline oxide;forming a first enhancing fluid comprising a portion of the solar generated CO2;delivering a portion of the first enhancing fluid through a plurality of injection wells into a first enhancement site comprising mobilizable hydrocarbon with a injector well weighted first enhancement location within a prescribed solar CO2 delivery distance from the first calcining site, whereby forming mobilized hydrocarbon;producing, from the first enhancement site, a produced fluid comprising mobilized hydrocarbon and produced enhancing fluid;separating, from the produced fluid, a recovered hydrocarbon and residual enhancing fluid; and recycling a portion of the residual enhancing fluid to the first enhancement site;wherein the prescribed solar CO2 delivery distance is less than about 60% of a scalar average alkali demand distance DADC, of a demand weighted average of one or more absolute scalar distances from the first mean enhancement location to one or more alkali demand locations selected from one or more population demand centers, and one or more industrial demand centers, having a combined alkali demand for alkaline oxide greater than a design rate of alkaline oxide generation in one or more calciners comprising a solar calciner installed to calcine carbonate at the first calcining site. 12. The calcining recovery method of claim 11, further comprising solar calcining carbonate at a second calcining site within the prescribed solar CO2 delivery distance of a second enhancement site in the first hydrocarbon resource, forming a second enhancing fluid, and delivering the second enhancing fluid to mobilize hydrocarbon at a second enhancement site. 13. The calcining recovery method of claim 12, wherein delivering the second enhancing fluid at the second calcining site at a second delivery rate more than three times a first delivery rate of delivering the enhancing fluid at the first calcining location. 14. The calcining recovery method of claim 12, wherein mobilizing hydrocarbon in a proving enhancement site in a second hydrocarbon resource by delivering a portion of one of the first enhancing fluid and the second enhancing fluid. 15. The calcining recovery method of claim 14, wherein delivering a third enhancing fluid comprising CO2 from outside the second hydrocarbon region to a second production enhancement site located within the second hydrocarbon resource at less than a prescribed analogous resource distance from the proving enhancement site, and mobilizing hydrocarbon in the second production enhancement site. 16. The calcining recovery method of claim 15, wherein the third enhancing fluid comprises CO2 recovered from a calcining site near a remote alkaline oxide demand center comprising one of a population region and an industrial site located farther away than the prescribed solar CO2 delivery distance from the second production enhancement site. 17. The calcining recovery method of claim 12, wherein delivering crushed carbonate to a proving carbonate calcining site located within the prescribed solar CO2 delivery distance from the proving enhancement site in the second hydrocarbon resource, solar calcining the crushed carbonate and delivering a portion of enhancing fluid comprising solar CO2 formed thereby to mobilize hydrocarbon in the proving enhancement site. 18. The calcining recovery method of claim 13, wherein screening the crushed carbonate and supplying screened limestone with the prescribed screen size of about 76 mm (3″) in size for calcining. 19. The calcining recovery method of claim 13, further delivering enhancing fluid and mobilizing hydrocarbon at a plurality of enhancement sites, wherein a production well weighted production distance, to a mean enhancement center of the plurality of enhancement sites, from a mean solar calcining center of a plurality of calcining sites comprising a solar calciner near the first hydrocarbon resource, is less than about 50% of the average alkali demand distance, of the demand weighted scalar distances to the mean enhancement center from a plurality of said alkali demand locations having collectively an equal or greater alkaline demand than the design calcining capacity of plurality of calcining sites. 20. The calcining recovery method of claim 11, wherein delivering enhancing fluid into the plurality of injection wells at the rate of recovering enhancing fluid plus generating enhancing fluid using at least 85% of an enhancing fluid generating design capacity of the one or more calciners, and configuring the number of injection wells to maintain the enhancing fluid delivery pressure between 75% and 100% of a prescribed safe delivery pressure. 21. The calcining recovering method of claim 11, wherein beginning delivery of enhancing fluid before a beginning of hydrocarbon production or before a primary hydrocarbon production rate reaches an inflection point where an accelerating rise in the primary hydrocarbon production rate changes to a decelerating rise. 22. The calcining recovery method of claim 11, wherein proving a reserve of CO2 enhanced hydrocarbon production within the first hydrocarbon resource within 24 months of first delivering enhancing fluid. 23. The calcining recovery method of claim 11, wherein delivering enhancing fluid into the first enhancement site at a rate of more than 0.2 HCPV/year of the hydrocarbon resource served by the plurality of injection wells delivering the enhancing fluid. 24. A method of calcining-proving hydrocarbon recovery, comprising: mining at a first mining site a carbonate resource comprising a carbonate of calcium and/or magnesium, within a prescribed mining distance from a first hydrocarbon enhancement site in a first hydrocarbon resource;crushing the carbonate and delivering a portion of the crushed carbonate to a solar first calciner at a first calcining site having a local calcining design capacity;calcining the portion of the delivered crushed carbonate, whereby solar generating carbon dioxide (herein CO2) and alkaline oxide;delivering an enhancing fluid comprising a portion of the solar generated CO2 into a first enhancement site, whereby mobilizing a hydrocarbon;producing, from the first enhancement site, a produced fluid comprising mobilized hydrocarbon and enhancing fluid; andseparating, from the produced fluid, a recovered hydrocarbon and a recovered fluid comprising CO2;wherein recovering hydrocarbon with a hydrocarbon production profile for a duration sufficient to prove a first reserve of CO2 co-producible hydrocarbon; andwherein the prescribed mining distance is less than about 50% of a remote calcining distance, to the first enhancement site from a remote calciner site having a remote design calcining capacity equal to or greater than the local calcining design capacity. 25. The calcining-proving method of claim 24, wherein delivering sufficient enhancing fluid for a duration sufficient to demonstrate a CO2-enhanced hydrocarbon recovery rate greater than a base primary hydrocarbon production recovery rate without the enhancing fluid, and projecting a CO2 enhanceable hydrocarbon reserve above a base projected hydrocarbon reserve. 26. The calcining-proving method of claim 25, wherein identifying a first inflection point showing a declining rate of increase in the hydrocarbon production rate; and wherein delivering sufficient enhancing fluid for a duration long enough to cause a second inflection point with an accelerating rate of increase in the hydrocarbon production rate, whereby showing a production enhancement by an increasing rate of increase in the hydrocarbon production rate. 27. The calcining-proving method of claim 25, further comprising showing that a second hydrocarbon resource having a mining distance from the first mining site less than about 50% of the remote calcining distance is analogous to the first hydrocarbon resource, and projecting the demonstrated CO2 enhanced hydrocarbon recovery at the first hydrocarbon site onto the second analogous resource, to project a second reserve of CO2 enhanceable hydrocarbon in the second analogous resource. 28. The calcining-proving method of claim 24, wherein a first local trial solar CO2 delivery distance, to the center of a first trial enhancement site HT1 from the local solar first calciner at the solar first calcining site, is less than about 67% of a first remote CO2 delivery distance, to the first enhancement or hydrocarbon trial site HT1 from a first remote calciner at a remote calcining site, having an equal or greater remote CO2 generating capacity than the local CO2 generating capacity of the local solar first calciner. 29. The calcining-proving method of claim 24, wherein a first local production solar CO2 delivery distance, to a center of the first production enhancement site HP1 from the solar second calciner at a second calcining site, may be less than about 50% of a second remote CO2 delivery distance, to the center of first enhancement site HP1 from the location of a second remote calciner at a remote calcining site, wherein the second remote calciner has an equal or greater remote CO2 generating capacity than the local CO2 generating capacity of the local solar second calciner. 30. The calcining-proving method of claim 24, wherein a local mean solar CO2 delivery distance, to a first hydrocarbon center HC1 of the first hydrocarbon resource H1, weighted by an oil in place, from the mean of locations of the solar first calciner location and the solar second calciner, is less than about 40% of a remote mean CO2 delivery distance to the first hydrocarbon center HC1 of hydrocarbon resource H1 from the mean of the location of the nearest first remote calciner and the location of the next nearest second remote calciner, together having an equal or greater CO2 generating capacity than the combined capacity of the solar first calciner and the solar second calciner. 31. The calcining-proving method of claim 24, wherein a first local solar CO2 production delivery distance to the first hydrocarbon center HC1 of first hydrocarbon resource H1 from the solar second calciner is less than about 65% of a remote alkali demand distance for alkaline oxide DADC, from the first hydrocarbon center HC1 to an alkali demand center ADP of a first remote population region P1 such as is supplied by the first remote calciner and a second remote population region P2, such as is supplied by the second remote calciner. 32. The calcining-proving method of claim 24, wherein a mean solar CO2 delivery distance to the first resource weighted hydrocarbon center HC1 of first hydrocarbon resource H1 from a production weighted solar calcining center SCCT of a plurality of nearby operating calciners comprising a solar calciner having a combined design alkaline oxide generating capacity, is less than about 50% of a remote mean demand distance CM of an alkali demand weighted average of scalar distances from the first hydrocarbon center HC1 to an a plurality of one or more of the first population center PC1, the second population center PC2, the first industrial user IU1 and the second industrial user IU2, having an alkali demand for alkaline oxide greater than the local combined design alkaline oxide production capacity of the plurality of nearby operating calciners. 33. The calcining-proving method of claim 24, wherein a mean alkali demand distance, of the average scalar distances from an area weighted mean enhancement location HE1, of the first hydrocarbon trial site HT1 and the first production enhancement site HP1, to one or more remote alkali demands for alkaline oxide, comprising one or more of population centers and one or more industrial users, is greater than a production distance, to the first mean enhancement location HE1 from the first mean supply location CS1 of the mining site comprising quarry Q1 and quarry Q2, wherein the remote alkali demand is greater than the combined local calcining design capacity. 34. The calcining-proving method of claim 24, further comprising providing a buffer store of surface mined carbonate sufficient to generate CO2 to deliver to the first enhancement site enhancing fluid comprising CO2 at 85% of the local calcining design capacity for at least six months. 35. The calcining-proving method of claim 24, wherein proving enhanced liquid hydrocarbon production from the first hydrocarbon resource within 12 months of first delivering enhancing fluid. 36. The calcining-proving method of claim 24, wherein proving the enhanceable hydrocarbon resource at a second nearby or analogous enhancement site with CO2 from one of an existing CO2 source and a relocatable CO2 source, and then calcining to generate CO2 from crushed carbonate at the second nearby enhancement site.
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