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A method of stabilizing a waste in a chemically bonded phosphate ceramic (CBPC). The method consists of preparing a slurry including the waste, water, an oxide binder, and a phosphate binder. The slurry is then allowed to cure to a solid, hydrated CBPC matrix. Next, bound water within the solid, hyd

A method of stabilizing a waste in a chemically bonded phosphate ceramic (CBPC). The method consists of preparing a slurry including the waste, water, an oxide binder, and a phosphate binder. The slurry is then allowed to cure to a solid, hydrated CBPC matrix. Next, bound water within the solid, hydrated CBPC matrix is removed. Typically, the bound water is removed by applying heat to the cured CBPC matrix. Preferably, the quantity of heat applied to the cured CBPC matrix is sufficient to drive off water bound within the hydrated CBPC matrix, but not to volatalize other non-water components of the matrix, such as metals and radioactive components. Typically, a temperature range of between 100° C.-200° C. will be sufficient. In another embodiment of the invention wherein the waste and water have been mixed prior to the preparation of the slurry, a select amount of water may be evaporated from the waste and water mixture prior to preparation of the slurry. Another aspect of the invention is a direct anyhydrous CBPC fabrication method wherein water is removed from the slurry by heating and mixing the slurry while allowing the slurry to cure. Additional aspects of the invention are ceramic matrix waste forms prepared by the methods disclosed above.

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The invention claimed is: 1. A method of stabilizing a radioactive waste in chemically bonded phosphate ceramic comprising: preparing a slurry comprising the radioactive waste, water, an oxide binder and a phosphate binder, wherein the oxide binder is MgO; allowing the slurry to cure to a solid hyd

The invention claimed is: 1. A method of stabilizing a radioactive waste in chemically bonded phosphate ceramic comprising: preparing a slurry comprising the radioactive waste, water, an oxide binder and a phosphate binder, wherein the oxide binder is MgO; allowing the slurry to cure to a solid hydrated chemically bonded phosphate ceramic matrix; and removing bound water from the solid hydrated chemically bonded phosphate ceramic matrix, wherein the hydrated ceramic matrix is heated to a select temperature between a lower first temperature where the bound water begins to be driven from the hydrated ceramic matrix and a higher second temperature where non-water components of the hydrated ceramic matrix are volatilized. 2. The method of claim 1 wherein the waste and the water have been mixed prior to the preparation of the slurry and further comprising removing a select amount of water from the waste and water mixture prior to preparation of the slurry. 3. The method of claim 1 further comprising removing water from the slurry while mixing the slurry or allowing the slurry to cure. 4. The method of claim 3 wherein the water is removed from the slurry through evaporation by heating, and wherein the slurry is heated to a select curing temperature between a first curing temperature where water is removed from the slurry as it cures and a second curing temperature where non-water components of the slurry are volatilized. 5. The method of claim 1 further comprising adding a select amount of a reducing agent or an oxidizing agent to the waste or the slurry prior to allowing the slurry to cure. 6. The method of claim 1 wherein the waste has a first pH level, and further comprising adding a neutralizing material to the waste before allowing the slurry to cure to at least partially neutralize the waste so the waste has a second pH level different from the first pH level. 7. The method of claim 1, further comprising adding a beta-absorptive, gamma-absorptive, alpha-absorptive, or neutron-absorptive material directly to the waste before allowing the mixed slurry to cure. 8. The method of claim 1, further comprising dewatering the waste during or before the waste is combined with the oxide binder and the phosphate binder. 9. The method of claim 1, further comprising adding a neutralizing material to the waste to at least partially neutralize the waste before the waste is combined with the oxide binder and the phosphate binder. 10. The method of claim 1 further comprising at least partially de-watering the waste before allowing the slurry to cure. 11. The method of claim 1, further comprising adding an H.sub.2 getter agent to the waste or the slurry to reduce H.sub.2 gas generation. 12. The method of claim 1 wherein the waste is an acidic waste, further comprising neutralizing the waste with at least one metal oxide. 13. The method of claim 1 wherein the waste is a basic waste, having a pH level further comprising reducing the pH level by adding a neutralizing agent. 14. The method of claim 1, further comprising adding a salt to the slurry to control reaction rates during mixing of the slurry. 15. The method of claim 1, further comprising adding a stabilizing agent or a reducing agent to the waste or the slurry to decrease solubility of constituents of the waste. 16. The method of claim 1, further comprising adding an exothermic agent to the waste or the slurry that reacts and heats the waste or the slurry. 17. The method of claim 1, further comprising adding to the waste or the slurry a shielding agent for neutrons, alpha particles, beta particles, or gamma particles in the waste to provide an at least partially self-shielding waste. 18. The method of claim 1 wherein the hydrated ceramic matrix is in a vacuum chamber and the bound water is removed from the hydrated ceramic matrix by reducing a chamber pressure. 19. The method of claim 1 wherein the lower first temperature is approximately 100° C. and the higher second temperature is approximately 200° C. 20. A method of stabilizing a radioactive waste in chemically bonded phosphate ceramic comprising: providing a mixture of the radioactive waste and water; removing a select amount of water from the waste and water mixture to form a residual waste and water mixture; preparing a slurry comprising the residual waste and water mixture, an oxide binder and a phosphate binder wherein the oxide binder is MgO; allowing the slurry to cure to a solid chemically bonded phosphate ceramic matrix, wherein the solid chemically bonded phosphate ceramic matrix comprises bound water molecules; and removing the bound water molecules from the solid chemically bonded phosphate ceramic matrix by heating. 21. The method of claim 20 wherein the select amount of water is removed from the waste and water mixture through evaporation by heating. 22. The method of claim 20 wherein the quantity of water removed from the waste and water mixture is selected to result in a solids content within the waste and water mixture, after the removal step, of equal to or less than 90% measured by weight of the residual waste and water mixture. 23. Method of claim 20 wherein the phosphate binder is KH2PO4. 24. The method of claim 20 further comprising adding a select amount of a reducing agent or an oxidizing agent to the waste or the slurry prior to allowing the slurry to cure. 25. A method of stabilizing a radioactive waste in chemically bonded phosphate ceramic comprising: preparing a slurry comprising radioactive waste, an oxide binder and a phosphate binder, wherein the oxide binder is MgO; removing a select amount of water from the slurry while mixing the slurry or allowing the slurry to cure; allowing the slurry to cure to a solid chemically bonded phosphate ceramic matrix; and driving off bound water from the solid chemically bonded phosphate ceramic matrix to form a solid matrix having reduced weight wherein driving off bound water from the solid chemically bonded phosphate ceramic matrix includes heating the solid chemically bonded phosphate ceramic matrix to a select temperature between a first temperature where the bound water begins to be driven off from the solid chemically bonded phosphate ceramic matrix and a higher second temperature where non-water components of the solid chemically bonded phosphate ceramic matrix are volatilized. 26. The method of claim 25 wherein removing the select amount of water from the slurry includes heating the slurry to a temperature greater than approximately 100° C., and wherein the first temperature for removing bound water from the solid chemically bonded phosphate ceramic matrix is approximately 100° C. and the second temperature for removing bound water from the solid chemically bonded phosphate ceramic matrix is approximately 200° C. 27. The method of claim 25 wherein the waste comprises a liquid waste. 28. A method of stabilizing a radioactive waste in chemically bonded phosphate ceramic comprising: providing a mixture of the radioactive waste and water; removing a select amount of water from the waste and water mixture to form a residual waste and water mixture; preparing a slurry comprising the residual waste and water mixture, an oxide binder and a phosphate binder, wherein the oxide binder is MgO; allowing the slurry to cure to a solid chemically bonded phosphate ceramic matrix; and removing bound water from the solid chemically bonded phosphate ceramic matrix, wherein removing bound water from the solid chemically bonded phosphate ceramic matrix includes heating the solid chemically bonded phosphate ceramic matrix to a select temperature between a first temperature where the bound water begins to be removed from the solid chemically bonded phosphate ceramic matrix and a higher second temperature where non-water components of the solid chemically bonded phosphate ceramic matrix are volatilized. 29. The method of claim 28 wherein removing the select amount of water from the waste and water mixture includes heating the waste and water mixture to a temperature greater than approximately 100° C., and wherein the first temperature for removing bound water from the solid chemically bonded phosphate ceramic matrix is approximately 100° C. and the second temperature for removing bound water from the solid chemically bonded phosphate ceramic matrix is approximately 200° C.