Thermal process systems

What is claimed is: 1 . A thermal process system, comprising: a retort assembly comprising a retort chamber defining a longitudinal axis, wherein the retort assembly is configured to: substantially contain one or more gases in the retort chamber during a thermal process; and house substrate material within the retort chamber; and a heating assembly comprising a plurality of heating elements adjacent to the retort chamber, wherein the plurality of heating elements is configured to selectively generate two or more heating zones at different axial positions along the longitudinal axis within a heating region. 2 . The thermal process system of claim 1 , wherein, to selectively generate the two or more heating zones, the plurality of heating elements is configured to: generate, by a first set of heating elements of the plurality of heating elements at a first axial position, a first heating zone; and generate, by a second set of heating elements of the plurality of heating elements at a second axial position, a second heating zone. 3 . The thermal process system of claim 1 , wherein a ratio of a length of the heating region to a width of the retort chamber is greater than or equal to about 10. 4 . The thermal process system of claim 1 , wherein the retort assembly comprises: an inlet at a first end configured to discharge an inlet gas mixture into the retort chamber; and an outlet at a second end configured to receive an outlet gas mixture from the retort chamber, wherein the inlet and the outlet are configured to define flow of the gas mixtures through the retort chamber, and wherein the retort assembly is configured to bypass at least a portion of the flow of the gas mixtures around or through the substrate material. 5 . The thermal process system of claim 4 , wherein the retort assembly further comprises one or more porous pipes extending along the longitudinal axis and configured to discharge the inlet gas mixture into the substrate material. 6 . The thermal process system of claim 4 , wherein the retort assembly comprises a retort lid positioned at at least one of the first end or the second end and configured to secure against the retort chamber of the retort assembly, and wherein the respective first end or second end is configured to permit passage of the substrate material in a consolidated form. 7 . The thermal process system of claim 6 , wherein the retort lid is configured to secure a seal between the retort lid and the retort chamber. 8 . The thermal process system of claim 1 , further comprising: a vessel housing positioned around the retort chamber and the plurality of heating elements; and insulation material between positioned between the retort chamber and the vessel housing. 9 . The thermal process system of claim 1 , further comprising a frame configured to position the substrate material in the retort chamber. 10 . The thermal process system of claim 1 , further comprising a computing device configured to selectively control the plurality of heating elements to generate a single heating zone of the two or more heating zones. 11 . The thermal process system of claim 1 , wherein the thermal process system is a pyrolysis reactor configured to generate hydrogen gas from a hydrocarbon through pyrolysis. 12 . The thermal process system of claim 1 , wherein the substrate material comprises lunar regolith particles. 13 . A method, comprising: containing, by a retort assembly of a thermal process system, one or more gases in a retort chamber of the retort assembly during a thermal process, wherein the retort assembly comprising a retort chamber defining a longitudinal axis, and wherein the retort assembly houses substrate material within the retort chamber; and maintaining, by a heating assembly of the thermal process system, the one or more gases at thermal process conditions by selectively generating, by a plurality of heating elements of the heating assembly, two or more heating zones at different axial positions along the longitudinal axis within a heating region, wherein the plurality of heating elements is adjacent to the retort chamber. 14 . The method of claim 13 , wherein selectively generating the two or more heating zones comprises at least: generating, by a first set of heating elements of the plurality of heating elements at a first axial position, a first heating zone at a first time to deposit a product solid on a first portion of the substrate material; and generating, by a second set of heating elements of the plurality of heating elements at a second axial position, a second heating zone at a second time to deposit the product solid on a second portion of the substrate material. 15 . The method of claim 14 , wherein the first time and the second time correspond to a desired loading threshold of the respective first portion and second portion of the substrate material. 16 . The method of claim 15 , wherein the desired loading threshold is greater than about 95 percent of a maximum loading capacity of the substrate material. 17 . The method of claim 13 , further comprising: receiving, by an inlet at a first end of the retort assembly, an inlet gas mixture into the retort chamber; and discharging, by an outlet at a second end of the retort assembly, an outlet gas mixture from the retort chamber, and wherein the inlet and the outlet are configured to define flow of the inlet and outlet gas mixtures through the retort chamber. 18 . The method of claim 13 , wherein maintaining a temperature of the one or more gases in a retort volume within the retort chamber above about 400° C. 19 . The method of claim 13 , wherein the thermal process system is a pyrolysis reactor configured to generate hydrogen gas from a hydrocarbon through pyrolysis. 20 . The method of claim 13 , wherein the substrate material comprises lunar regolith particles.