Methods for chemical process heating with carbon capture

1 . A system for supplying thermal energy to an endothermic chemical process, the system comprising: a first reactor comprising a moving bed reducer; a second reactor comprising a combustor; a plurality of redox particles comprising a metal oxide based redox material; and an endothermic reactor; wherein the first reactor and the second reactor are interconnected and the system is configured to cycle the plurality of redox particles between the first reactor and the second reactor; wherein the plurality of redox particles have a first oxidation state and a second oxidation state, the second oxidation state being lower than the first oxidation state; wherein the first reactor is configured to receive a carbon-containing reactant and at least a portion of the plurality of redox particles, said portion of the plurality of redox particles being in the first oxidation state; wherein, within the first reactor, the plurality of redox particles flow downwards in a packed moving bed manner while the carbon-containing reactant flows upwards at a velocity below the minimum fluidizing velocity of the plurality of redox particles; wherein the carbon-containing reactant reacts with the plurality of redox particles in the first oxidation state within the first reactor, such that the carbon-containing reactant is oxidized to form an oxidation product and the plurality of redox particles are reduced from the first oxidation state to the second oxidation state; wherein the second reactor is configured to receive air and at least a portion of the plurality of redox particles, said portion of the plurality of redox particles being in the second oxidation state; wherein the plurality of redox particles in the second oxidation state react with the air in the second reactor, such that the plurality of redox particles are oxidized from the second oxidation state to the first oxidation state by the air; wherein the reaction within the first reactor, the reaction within the second reactor, one or more products of the reaction within the first reactor and/or the second reactor, or a combination thereof generates thermal energy; and wherein the endothermic reactor is configured to receive at least a portion of said thermal energy to drive the endothermic chemical process. 2 . The system of claim 1 , wherein the second reactor comprises a fluidized bed, a moving bed, or a combination thereof. 3 . The system of claim 1 , further comprising a third reactor comprising a particle oxidation reactor between and connected to both the first reactor and the second reactor, wherein the particle oxidation reactor is configured to contact the plurality of redox particles with an oxidizing gas to at least partially oxidize the plurality of redox particles. 4 . (canceled) 5 . The system of claim 3 , wherein the particle oxidation reactor is configured as a countercurrent moving bed reactor, a fluidized bed reactor, or a combination thereof. 6 . The system of claim 3 , wherein the oxidizing gas is not air. 7 . The system of claim 3 , wherein the oxidizing gas comprises steam, CO 2 , NO 2 , SO 2 , or a combination thereof. 8 . The system of claim 1 , wherein the first reactor comprises a group of moving bed stages, fluidized bed stages, or a combination thereof. 9 . (canceled) 10 . (canceled) 11 . The system of claim 1 , wherein the carbon-containing reactant comprises natural gas, coal, biomass, or a combination thereof. 12 . The system of claim 1 , wherein the carbon-containing reactant is produced in another process that is upstream or downstream of the endothermic reactor. 13 . The system of claim 12 , wherein the carbon-containing reactant is a slip stream of the products or a tail gas from the upstream or downstream process. 14 . The system of claim 1 , wherein the oxidation products comprise CO 2 , H 2 O, or a combination thereof. 15 . (canceled) 16 . (canceled) 17 . The system of claim 1 , wherein the plurality of redox particles comprise an iron oxide. 18 . The system of claim 1 , wherein the plurality of redox particles in the first oxidation state comprises Fe 2 O 3 , wherein the plurality of redox particles in the second oxidation state comprise FeO, or a combination thereof. 19 - 21 . (canceled) 22 . The system of claim 1 , wherein the endothermic reactor is a tube-type reactor. 23 . The system of claim 1 , wherein the endothermic reactor is embedded inside; the first reactor; the second reactor; a conduit fluidly connected to and downstream of the first reactor, the second reactor, or a combination thereof; or a combination thereof. 24 . The system of claim 1 , wherein the endothermic reactor is located horizontally and/or vertically inside the second reactor. 25 . The system of claim 1 , wherein the endothermic reactor forms an outer wall of the first reactor and/or the second reactor. 26 - 30 . (canceled) 31 . The system of claim 1 , wherein the endothermic reactor comprises a fixed bed packed by a catalyst. 32 . The system of claim 1 , wherein the endothermic chemical process comprises steam methane reforming, methane dry reforming, methane dehydrogenation, ethane dehydrogenation, propane dehydrogenation, ethylbenzene dehydrogenation, or a combination thereof. 33 - 42 . (canceled) 43 . A method for supplying thermal energy to an endothermic chemical process, the method comprising: contacting a carbon-containing reactant with at least a portion of a plurality of redox particles in a first reactor; wherein the first reactor is a moving bed reducer; wherein the plurality of redox particles comprise a metal oxide based redox material, and the plurality of redox particles have a first oxidation state and a second oxidation state; wherein said portion of the plurality of redox particles are in the first oxidation state; wherein, within the first reactor, the plurality of redox particles flow downwards in a packed moving bed manner while the carbon-containing reactant flows upwards at a velocity below the minimum fluidizing velocity of the plurality of redox particles; wherein the carbon-containing reactant reacts with the plurality of redox particles in the first oxidation state within the first reactor, such that the carbon-containing reactant is oxidized to form an oxidation product and the plurality of redox particles are reduced from the first oxidation state to the second oxidation state; transferring at least a portion of the plurality redox particles in the second oxidation state to a second reactor, the second reactor comprising a combustor; contacting said portion of the plurality of redox particles in the second oxidation state with air in the second reactor; wherein the plurality of redox particles in the second oxidation state react with the air in the second reactor, such that the plurality of redox particles are oxidized from the second oxidation state to the first oxidation state by the air; wherein the reaction within the first reactor, the reaction within the second reactor, one or more products of the reaction within the first reactor and/or the second reactor, or a combination thereof generates thermal energy; and transferring at least a portion of said thermal energy to an endothermic reactor to drive the endothermic chemical process. 44 - 83 . (canceled)