Composite feedstock for additive manufacturing

What is claimed is: 1. A feedstock for additive manufacturing, the feedstock comprising: a core including a binder system and a powder material suspended in the binder system, the powder material including a sinterable powder, the binder system including a primary binder and a secondary binder, a net shape of the powder material retainable by the primary binder during a primary debind process, a net shape of the powder material retainable by the secondary binder during a thermal sintering cycle, and at least one of the primary binder and the secondary binder including a first polymer; and a jacket about the core, the jacket including a second polymer, and the jacket having a mechanical performance greater than a mechanical performance of the core at a temperature substantially below an extrusion temperature for the feedstock. 2. The feedstock of claim 1 , wherein the mechanical performance of the core and jacket is measured by any one of the: area under a curve of a stress-strain test, a Shore hardness, a Rockwell hardness, an Izod impact energy, a Charpy impact energy, and a tensile yield strength, and a tensile ultimate strength. 3. The feedstock of claim 1 , wherein the powder material has a concentration in the core within ±10 volume percent of a tap density of the powder material. 4. The feedstock of claim 1 , wherein the second polymer has a molecular weight greater than a molecular weight of the first polymer. 5. The feedstock of claim 1 , wherein the binder system includes two or more polymers, and wherein the second polymer has a molecular weight greater than an average of the molecular weights of the two or more polymers in the binder system. 6. The feedstock of claim 1 , wherein the binder system includes the second polymer. 7. The feedstock of claim 1 wherein the second polymer has a Shore D hardness greater than a Shore D hardness of the first polymer at the temperature substantially below the extrusion temperature of the feedstock. 8. The feedstock of claim 1 , wherein the second polymer has a melt temperature higher than a melt temperature of the first polymer. 9. The feedstock of claim 1 , wherein, at a temperature of about twenty-three degrees Celsius, the feedstock is spoolable without fracture on a spool with a diameter of at most thirty-six inches and at least about a diameter of the feedstock. 10. The feedstock of claim 1 , wherein, at a temperature of about twenty-three degrees Celsius, the feedstock is substantially rigid. 11. The feedstock of claim 1 , wherein the second polymer of the jacket has a polymer chain longer than a polymer chain of the first polymer of the binder system. 12. The feedstock of claim 1 , wherein the jacket contains an amount of the powder material. 13. The feedstock of claim 12 , wherein a volumetric percentage of the powder material in the jacket is less than a volumetric percentage of the powder material in the core. 14. The feedstock of claim 13 , wherein a volumetric percentage of the powder material in the jacket is substantially equal to a volumetric percentage of the powder material in the core. 15. The feedstock of claim 13 , wherein the secondary binder is formed in part by the second polymer, and a volumetric percentage of the second polymer in the jacket is greater than a volumetric percentage of the second polymer in the core. 16. The feedstock of claim 1 , wherein the first polymer is polystyrene. 17. The feedstock of claim 1 , wherein the second polymer is one or more of polystyrene, polypropylene, polyethylene, and poly(methyl methacrylate). 18. The feedstock of claim 1 , wherein the secondary binder includes one or more of polypropylene, polyethylene, and poly(methyl methacrylate). 19. A method of fabricating a feedstock, the method comprising: extruding a continuous core including a binder system and a powder material, the powder material having a concentration in the continuous core within ±10 volume percent of a tap density of the powder material, the binder system including a primary binder and a secondary binder, a net shape of the powder material retainable by the primary binder during a primary debind process, and a net shape of the powder material retainable by the secondary binder during a thermal sintering cycle, at least one of the primary binder and the secondary binder including a first polymer, and the powder of the powder material including a sinterable powder; and forming a jacket of a jacket material about the continuous core. 20. The method of claim 19 , wherein, at about twenty-three degrees Celsius, the jacket material has a Shore hardness greater than a Shore hardness of the continuous core. 21. The method of claim 19 , wherein the binder system includes a low molecular weight polymer, the jacket includes a crosslinker for the low molecular weight polymer, and a polymerization of the low molecular weight polymer is triggerable by the crosslinker to form longer chain polymers at an extrusion temperature for the feedstock. 22. The method of claim 21 , wherein the low molecular weight polymer has a molecular weight no greater than one hundred thousand g/mol. 23. The method of claim 21 , wherein the extrusion temperature is at least one hundred degrees Celsius. 24. The method of claim 19 , wherein forming the jacket includes coextruding the jacket material around the continuous core. 25. The method of claim 19 , wherein forming the jacket includes spraying the jacket material onto the continuous core or dipping the continuous core in the jacket material.