Layered arrangement, hot-gas path component, and process of producing a layered arrangement

What is claimed is: 1. A hot gas path component, the hot gas path component comprising a layered arrangement, the layered arrangement including: a substrate layer; a ceramic matrix composite layer; and a non-metal spacer between the substrate layer and the ceramic matrix composite layer configured to define a plurality of pockets, the non-metal spacer having a composition distinct from each of the substrate layer and the ceramic matrix composite layer, wherein the plurality of pockets contain a substance including a property of greater thermal insulation than the substrate layer, wherein the substrate layer, the ceramic matrix composite layer and the non-metal spacer form a plurality of completely enclosed pockets, preventing flow into each of the plurality of completely enclosed pockets; and wherein the hot gas path component is a component along a hot gas path of a turbine. 2. The hot gas path component of claim 1 , wherein the substrate layer is a nickel-based superalloy. 3. The hot gas path component of claim 1 , wherein the composition of the non-metal spacer includes a ceramic. 4. The hot gas path component of claim 1 , wherein the composition of the non-metal spacer includes a thermal barrier coating material. 5. The hot gas path component of claim 1 , wherein the non-metal spacer is formed from a yttria-stabilized zirconia. 6. The hot gas path component of claim 1 , wherein the substance includes air, the substance being trapped in the plurality of pockets within the layered arrangement. 7. The hot gas path component of claim 1 , wherein the layered arrangement is a side wall of a turbine nozzle. 8. The hot gas path component of claim 1 , wherein the layered arrangement is an airfoil surface. 9. The hot gas path component of claim 1 , wherein the layered arrangement is a turbine shroud. 10. The hot gas path component of claim 1 , wherein the non-metal spacer includes a ridge extending along the layered arrangement. 11. The hot gas path component of claim 1 , wherein the non-metal spacer includes intersecting ridges. 12. The hot gas path component of claim 1 , wherein the substance includes a thermally insulating substance. 13. The hot gas path component of claim 1 , wherein the non-metal spacer is mechanically secured to one or both of the substrate layer and the ceramic matrix composite layer. 14. The hot gas path component of claim 1 , wherein the non-metal spacer is bonded to the substrate layer or the ceramic matrix composite layer. 15. The hot gas path component of claim 1 , wherein the non-metal spacer has a thermal conductivity that is less than one-third of the thermal conductivity of the substrate layer. 16. The hot gas path component of claim 1 , wherein the substrate layer is at least 10 mils thick, the ceramic matrix composite layer is at least 20 mils thick, and the non-metal spacer includes a maximum thickness dimension of at least 30 mils. 17. A hot path component, comprising: a nickel-based superalloy layer; a ceramic matrix composite layer; and a ceramic spacer between the nickel-based superalloy layer and the ceramic matrix composite layer configured to define a plurality of pockets, the ceramic spacer having a composition distinct from the ceramic matrix composite layer, wherein the ceramic spacer is mechanically secured to one or both of the nickel-based superalloy layer and the ceramic matrix composite layer, wherein the ceramic spacer is bonded to the nickel-based superalloy layer or the ceramic matrix composite layer, wherein the plurality of pockets contain a substance including a property of greater thermal insulation than the nickel-based superalloy layer, wherein the nickel-based superalloy layer, the ceramic matrix composite layer and the ceramic spacer form a plurality of completely enclosed pockets, preventing flow into each of the plurality of completely enclosed pockets; and wherein the hot gas path component is a component along a hot gas path of a turbine. 18. A process for producing a hot gas path component of a including a layered arrangement, the process comprising securing a non-metal spacer between a substrate layer and a ceramic matrix composite layer of the layered arrangement, and incorporating the layered arrangement into the hot gas path component, wherein: the non-metal spacer is configured to define a plurality of pockets; the plurality of pockets contain a substance including a property of greater thermal insulation than the substrate layer; the non-metal spacer includes a composition distinct from each of the substrate layer and the ceramic matrix composite layer; the substrate layer, the ceramic matrix composite layer and the non-metal spacer form a plurality of completely enclosed pockets, preventing flow into each of the plurality of completely enclosed pockets; and the hot gas path component is a component along a hot gas path of a turbine.