PDC cutter with chemical addition for enhanced abrasion resistance

We claim: 1. A superabrasive cutter, comprising: a polycrystalline diamond body comprising a plurality of diamond particles bonded to one another; about 0.01% to about 4% by weight of the diamond particles of a metal or metal alloy as evaluated prior to a high pressure high temperature process; and a catalyst that promotes diamond-to-diamond bonding of the diamond particles in the high pressure high temperature process, wherein the metal or the metal alloy is immiscible with the catalyst at sintering conditions in the high pressure high temperature process. 2. The superabrasive cutter of the claim 1 , wherein the metal or metal alloy is lead or an alloy thereof. 3. The superabrasive cutter of the claim 1 , further comprising a substrate attached to the polycrystalline diamond body. 4. The superabrasive cutter of claim 3 , wherein the polycrystalline diamond body exhibits a gradient of metal or metal alloy with a higher concentration of metal or metal alloy at a top surface of the polycrystalline diamond body than at an interface surface formed between the polycrystalline diamond body and the substrate. 5. The superabrasive cutter of the claim 1 , wherein the metal or metal alloy is present in an amount by weight of the superabrasive particles of less than about 2.0% as evaluated prior to the high pressure high temperature process. 6. The superabrasive cutter of the claim 1 , wherein the metal or metal alloy is distributed throughout the polycrystalline superabrasive particles. 7. The superabrasive cutter of the claim 1 , wherein the metal or metal alloy has a melting point lower than the catalyst. 8. The superabrasive cutter of claim 1 , wherein the catalyst is selected from a Group VIII metal. 9. The superabrasive cutter of claim 1 , wherein the catalyst is cobalt. 10. A method of making superabrasive cutter, comprising: mixing a metal or metal alloy with a plurality of diamond particles; wherein the metal or metal alloy is present in an amount by weight of the diamond material of about 0.01% to about 4% as evaluated prior to a high pressure high temperature process; providing a substrate attached to a superabrasive volume formed by the plurality of diamond particles with the metal or metal alloy, wherein the substrate comprises a catalyst; and subjecting the substrate and the superabrasive volume with the metal or metal alloy to conditions of elevated temperature and pressure in the high pressure high temperature process that is suitable for producing the polycrystalline diamond material, wherein the metal or metal alloy is immiscible with the catalyst at sintering conditions in the high pressure high temperature process. 11. The method of the claim 10 , further comprising surrounding the diamond particles with the metal or metal alloy to protect the diamond particles from converting to graphite. 12. The method of the claim 10 , further comprising increasing a density of the superabrasive volume by introducing the metal or metal alloy. 13. The method of the claim 10 , wherein the metal or metal alloy is lead an alloy thereof. 14. The method of the claim 10 , wherein the substrate is cemented tungsten carbide. 15. The method of the claim 10 , further comprising sandwiching the diamond particles with mixture of the metal or metal alloy between the substrate and the diamond particles without mixing with the metal or metal alloy. 16. A superabrasive cutter, comprising: a plurality of diamond particles bonded to one another in a polycrystalline diamond body; a catalyst that promotes diamond-to-diamond bonding of the diamond particles in a high pressure high temperature process; and lead or an alloy thereof distributed throughout the polycrystalline diamond body wherein an overall concentration of the lead or alloy thereof is less than that of the catalyst. 17. The superabrasive cutter of the claim 16 , wherein the lead or alloy thereof is present in an amount by weight of the diamond particles of less than about 2.0% as evaluated prior to a high pressure high temperature process. 18. The superabrasive cutter of the claim 16 , further comprises a substrate attached to the polycrystalline diamond body formed by the diamond particles. 19. The superabrasive cutter of the claim 16 , wherein the lead or alloy thereof is present in an amount by weight of the diamond particles of about 0.01% to about 4% as evaluated prior to a high pressure high temperature process. 20. The superabrasive cutter of the claim 16 , wherein the lead or alloy thereof is present in an amount by weight of the diamond particles of less than about 1.0% as evaluated prior to a high pressure high temperature process. 21. The superabrasive cutter of the claim 16 , wherein the lead or alloy thereof has a melting point lower than the catalyst.