Catalytic alkane conversion

The invention claimed is: 1. A reverse-flow reactor, comprising: first and second thermal masses, each having first and second portions, the first and second portions together comprising ≥99.0 wt. % of the first or second thermal mass as the case may be, wherein the first and second thermal masses each include one or more passages adapted for fluid flow; first, second, third, fourth, and fifth regions, wherein (i) the first and second regions are adjacent, non-overlapping regions, (ii) the third and fourth regions are adjacent, non-overlapping regions, (iii) the first region contains the first portion of the first thermal mass and the second region contains the second portion of the first thermal mass, (iv) the third region contains the first portion of the second thermal mass and the fourth region contains the second portion of the second thermal mass, (v) the fifth region is a non-overlapping region located between the second and third regions, and (vi) the fifth region is adapted for fluid communication between the first and second thermal masses and optionally for fluid mixing; at least one first reaction zone located in the second region, at least one of the reaction zones containing at least one hydrocarbon conversion catalyst, the catalyst being (i) at least one hydrogen transfer catalyst and/or at least one first oxydehydrogenation catalyst, and the hydrocarbon conversion catalyst being in fluid communication with the passages of the first thermal mass; at least one first sorbent zone in the first region, the first sorbent zone containing at least one olefin-selective sorbent that is in fluid communication with the passages of the first thermal mass; at least one second reaction zone located in the third region, at least one of the reaction zones containing at least one second oxydehydrogenation catalyst that is in fluid communication with the passages of the second thermal mass; and at least one second sorbent zone in the fourth region, the second sorbent zone containing at least one olefin-selective sorbent that is in fluid communication with the second thermal mass. 2. A flow-through reactor for producing olefin, comprising: (a) a reactor vessel configured for fluid-flow; (b) at least one hydrocarbon conversion catalyst located within the reactor vessel, the hydrocarbon conversion catalyst being configured for contact with the fluid-flow and including (i) at least one oxidative coupling catalyst and/or (ii) at least one oxydehydrogenation catalyst; (c) at least one sorbent located in the reactor vessel, the sorbent being selective for olefin sorption and configured for contact with the fluid-flow; and (d) at least one thermal mass located in the reactor vessel, the thermal mass being configured for contact with the fluid-flow, and at least a portion of the fluid-flow contacting part of the thermal mass being located between the hydrocarbon conversion catalyst and the sorbent. 3. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent is a copper salt-treated zeolite 4A, a copper salt-treated zeolite X, a copper salt-treated zeolite Y, a copper salt-treated alumina, or a copper salt-treated silica. 4. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent is a clay sorbent impregnated with silver ion. 5. The flow-through reactor of claim 2 , in which the olefin-selective sorbent is a copper salt-treated zeolite 4A, a copper salt-treated zeolite X, a copper salt-treated zeolite Y, a copper salt-treated alumina, or a copper salt-treated silica. 6. The flow-through reactor of claim 2 , in which the olefin-selective sorbent is a clay sorbent impregnated with silver ion. 7. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent comprises a copper compound or a silver compound supported on silica, a copper compound or a silver compound supported on alumina, a copper compound or a silver compound supported on MCM-41 zeolite, a copper compound or a silver compound supported on 4A zeolite, a copper compound or a silver compound supported on a carbon molecular sieve, or a copper or silver compound supported on a polymer resin. 8. The reverse-flow reactor of claim 2 , in which the olefin-selective sorbent comprises a copper compound or a silver compound supported on silica, a copper compound or a silver compound supported on alumina, a copper compound or a silver compound supported on MCM-41 zeolite, a copper compound or a silver compound supported on 4A zeolite, a copper compound or a silver compound supported on a carbon molecular sieve, or a copper or silver compound supported on a polymer resin. 9. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent comprises a Faujasite zeolite. 10. The reverse-flow reactor of claim 2 , in which the olefin-selective sorbent comprises a Faujasite zeolite. 11. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent comprises a metal-organic framework, an iron-organic framework or a metal-organic framework having at least one redox-active metal center. 12. The reverse-flow reactor of claim 2 , in which the olefin-selective sorbent comprises a metal-organic framework, an iron-organic framework or a metal-organic framework having at least one redox-active metal center. 13. The reverse-flow reactor of claim 1 , in which the olefin-selective sorbent comprises an aluminophosphate. 14. The reverse-flow reactor of claim 2 , in which the olefin-selective sorbent comprises an aluminophosphate.