Additive manufacturing using aluminum-containing wire

What is claimed is: 1. A method of fabricating an article by additive manufacturing, the method comprising: providing a wire configured to serve as a source of metal that forms an entire article, the wire comprising: a sheath having a steel composition, and a core surrounded by the sheath, the core comprising aluminum (Al) at a concentration between 3 weight % and 20 weight % on the basis of the total weight of the wire, wherein the wire comprises carbon (C), manganese (Mn) and nickel (Ni), wherein [Ni]<10 weight % and a nickel equivalent defined by 2[Mn]+[Ni]+30[C] >30 weight %, wherein [Mn], [Ni] and [C] represent weight percentages of respective elements on the basis of the total weight of the wire, and wherein the Al is in an elemental form or is alloyed with a different metal element in the wire; applying an energy sufficient to form molten droplets of the metal; and depositing the molten droplets to form a plurality of layers of beads in a layer-by-layer fashion to fabricate the entire article by three-dimensional printing, wherein the entire article incorporates the Al as an alloying element. 2. The method of fabricating the article according to claim 1 , wherein depositing the molten droplets comprises forming a plurality of stacked layers of beads that form a substantial portion of the article. 3. The method of fabricating the article according to claim 1 , wherein applying the energy comprises applying energy sufficient to generate a plasma arc between the wire and a workpiece to cause the formation of the molten droplets. 4. The method of fabricating the article according to claim 1 , wherein applying the energy comprises resistively heating the wire while directing a laser beam over a workpiece to cause the formation of the molten droplets. 5. The method of fabricating the article according to claim 1 , wherein the method comprises applying the energy and depositing according to a gas metal arc welding (GMAW) process. 6. The method of fabricating the article according to claim 1 , wherein the method comprises applying the energy and depositing according to a self-shielded flux-cored arc-welding (FCAW-S) process without a shielding gas. 7. The method of fabricating the article according to claim 1 , wherein the method comprises applying the energy and depositing according to a gas tungsten arc welding (GTAW) process or a plasma arc welding (PAW) process in which applying the energy comprises applying the energy to an electrode that is different than the wire. 8. The method of fabricating the article according to claim 1 , wherein providing the wire comprises providing a metal-cored wire. 9. The method of fabricating the article according to claim 1 , wherein providing the wire comprises providing a self-shielded flux-cored arc welding (FCAW-S) wire, wherein the core comprises a fluxing agent comprising an oxide of a metal other than Al or Mn or a fluoride of a metal other than Al or Mn. 10. The method of fabricating the article according claim 1 , wherein the core comprises manganese (Mn) at a concentration between 10 weight % and 60 weight % on the basis of the total weight of the wire, wherein Mn is in an elemental form or is alloyed with a different metal element. 11. The method of fabricating the article according claim 10 , wherein the core further comprises one or more of: copper (Cu) at a concentration greater than zero weight % and less than 10 weight % on the basis of the total weight of the wire; and cobalt (Co) at a concentration greater than zero weight % and less than 10 weight % on the basis of the total weight of the wire, wherein a total concentration of the one or more of Cu and Co is greater than zero weight % and less than 10 weight % on the basis of the total weight of the wire. 12. The method of fabricating the article according claim 1 , wherein the wire comprises one or more of: nickel (Ni) at a concentration greater than zero weight % and less than 50 weight % on the basis of the total weight of the wire; carbon (C) at a concentration greater than zero weight % and less than 2.5 weight % on the basis of the total weight of the wire; and nitrogen (N) at a concentration greater than zero weight % and less than 2 weight % on the basis of the total weight of the wire. 13. The method of fabricating the article according claim 1 , wherein the wire further comprises N, Cu and Co at respective concentrations such that 2[Mn]+[Ni]+30[C]+20[N]+0.3[Cu]+0.3[Co] is between 10 weight % and 80 weight %, wherein [Mn], [Ni], [C], [N], [Cu] and [Co] represent weight percentages of respective elements on the basis of the total weight of the wire. 14. The welding wire of claim 1 , wherein the Al is present at a concentration between 4 weight % and 6.5 weight %, the [Mn] is between 18 weight % and 25 weight % and the nickel equivalent is present at a concentration of 30 to 50 weight %. 15. The welding wire of claim 14 , wherein the concentration of Ni is between 2 weight % and 10 weight %. 16. The welding wire of claim 14 , wherein within respective ranges of Al and the nickel equivalent, an amount of BCC phase present in the layers of beads is proportional to the concentration of Al while being inversely proportional to the concentration of the nickel equivalent. 17. A method of fabricating an article by additive manufacturing, the method comprising: providing a wire configured to serve as a source of metal that forms an entire article, the wire comprising a core surrounded by a sheath and a composition such that beads formed by quenching molten droplets formed by melting the wire has a bead composition including, on the basis of a total weight of the beads, iron (Fe) at a concentration between 50 weight % and 85 weight %, aluminum (Al) at a concentration between 3 weight % and 20 weight %, carbon (C), manganese (Mn) and nickel (Ni), wherein [Ni]<10 weight % and a nickel equivalent defined by 2[Mn]+[Ni]+30[C] >30 weight %, and wherein [Mn], [Ni] and [C] represent weight percentages of respective elements; and depositing molten droplets formed from the wire to form a plurality of layers of the beads in a layer-by-layer fashion to fabricate the entire article by three-dimensional printing, wherein the entire article incorporates the Al as an alloying element. 18. The method of fabricating the article according to claim 17 , further comprising applying an energy sufficient to generate a plasma arc between the wire and a workpiece to cause the formation of the molten droplets. 19. The method of fabricating the article according to claim 17 , further comprising resistively heating the wire while directing a laser beam over a workpiece to cause the formation of the molten droplets. 20. The method of fabricating the article according claim 17 , wherein the beads comprise manganese (Mn) at a concentration between 10 weight % and 60 weight %, on the basis of the total weight of the beads. 21. The method of fabricating the article according to claim 17 , wherein the beads have aluminum (Al) at a concentration between 4 weight % and 6.5 weight % and manganese (Mn) at a concentration between 15 weight % and 25 weight % on the basis of the total weight of the beads. 22. The method of fabricating the article according claim 17 , wherein the beads have face-centered cubic (FCC) austenite exceeding 30% on the basis of a total volume of the beads. 23. The method of fabricating the article according claim 17 , wherein the core comprises: aluminum (Al)