Seamless, and/or graded transition from sintered alternative-binders-based impermeable concrete to glass for architectural and industrial applications

What is claimed is: 1. A composite unibody structure that seamlessly transitions from an opaque portion to a translucent or transparent portion in a graded composition, the composite unibody structure comprising an advanced ceramic-glass composite structure with varying ratios of a geopolymer or an alkali-activated binder (AAB) material to glass across a length and/or depth of the composite unibody structure, the composite unibody structure comprising: the opaque portion made from a composition having a first ratio of the geopolymer or alkali-activated binder (AAB) material to the glass; the translucent or transparent portion made from a composition having a second ratio of the geopolymer or alkali-activated binder (AAB) material to the glass, the first ratio higher than the second ratio; and a transition portion that seamlessly transitions as a graded composition from the opaque portion to the translucent or transparent portion along a gradual gradient from the first ratio to the second ratio; wherein the composite unibody structure is arranged in the graded composition and then sintered. 2. The composite unibody structure of claim 1 , wherein the geopolymer is produced from metakaolin, a derivative thereof, or fly ash, or a composite of geopolymer and glass powder. 3. The composite unibody structure of claim 1 , wherein the geopolymer or alkali-activated binder (AAB) material is engineered to have a coefficient of thermal expansion that matches a coefficient of thermal expansion of the glass. 4. The composite unibody structure of claim 1 , wherein the translucent or transparent portion is transparent. 5. The composite unibody structure of claim 1 , wherein the translucent or transparent portion is translucent. 6. The composite material of claim 1 , wherein the transition from the opaque material to the transparent material is stepwise graded. 7. The composite material of claim 1 , wherein the transition from the opaque material to the transparent material is continuously graded. 8. A process for preparing a composite material of claim 1 , the process comprising contacting a geopolymer with a glass and sintering the geopolymer contacted glass to form the material. 9. The unibody composite structure of claim 1 , wherein the transition portion gradually transitions from the composition of 100% of geopolymer at the opaque portion to the composition of 100% of glass at the translucent portion. 10. The unibody composite structure of claim 1 , wherein the opaque portion is made from a composition having the first ratio of a mortar to glass; the translucent or transparent portion is made from a composition having the second ratio of a mortar to glass; the mortar including geopolymer and sand. 11. The unibody composite structure of claim 1 , wherein the transition portion gradually transitions from the composition of 95% of geopolymer and 5% of glass at the opaque portion to the composition of 5% of geopolymer and 95% of glass at the translucent portion. 12. The unibody composite structure of claim 1 , further comprising an additional opaque portion made from 100% geopolymer or AAB at an end of the opaque portion. 13. The unibody composite structure of claim 1 , further comprising an additional translucent portion made from 100% glass at an end of the translucent portion. 14. The composite structure of claim 1 , wherein a porosity increases and an optical gradient decreases from the translucent or transparent portion to the opaque portion. 15. The functional graded composite ceramic structure of claim 1 comprising a unibody structure seamlessly transitioning from an opaque end to an translucent end along a length of the unibody structure in a continuously or stepwise graded composition, the unibody structure made from heating a composite mixture in a mold to a sintering temperature, wherein the composite mixture is a mixture of concrete powder and crushed glass, the concrete made from a geopolymer or an alkali-activated binder (AAB) or a mortar, a ratio of the concrete powder to crushed glass and distribution varying along a length and/or depth of the mold based on a desired structural, thermal, and optical performance.