Foil-based additive manufacturing system and method

What is claimed is: 1. A method of manufacturing a metal alloy component comprising n number of slices from n number of alloy foil sheets including a first alloy foil sheet, an nth alloy foil sheet, and a plurality of intermediate alloy foil sheets, the method comprising: sequentially stacking each of the n alloy foil sheets on top of each other such that each of the n alloy foil sheets engages a respective underlying layer comprising another of the n alloy foil sheets; joining each of the n alloy foil sheets to the respective underlying layer using a material joining laser after each respective sheet is stacked on the respective underlying layer by striking a focused laser beam of the laser on a free, unobstructed surface of the foil sheet to melt and weld each alloy foil sheet to its respective underlying layer, wherein the laser does not travel through any polymer, glass, or other material against or near the foil sheets; and removing material away from one or more of the n alloy foil sheets to shape said one or more of the n alloy foil sheets to correspond in shape with one or more respective slices of the metal alloy component; wherein said steps of joining each of the n alloy foil sheets to the respective underlying layer and removing alloy material from said one or more of the n alloy foil sheets are controlled based on shape data indicative of a shape of each of the n slices of the metal alloy component. 2. The method of claim 1 wherein the metal alloy is an amorphous metal alloy. 3. The method of claim 2 wherein the joining is performed in a cooling chamber containing a cooling fluid comprising argon or nitrogen gas. 4. The method of claim 3 wherein the cooling chamber has an internal temperature below about minus 50° C. 5. The method of claim 1 wherein the material joining laser is applied to the surface of the foil sheet in sequential paths that do not overlap an immediately previously formed weld path to reduce heat accumulation. 6. The method of claim 1 wherein the material joining laser is applied to the surface of the foil sheet by forming spot welds on the entire surface with each successive spot weld being formed where it does not overlap with an immediately previously formed spot weld to reduce heat accumulation. 7. The method of claim 6 wherein each spot weld is formed at a location which is at least 5 mm away from the location of the immediately previously formed spot weld. 8. The method of claim 6 wherein each spot weld is formed at a location on the surface where the spot weld does not overlap with any previous spot welds that have an age of less than 1 second. 9. The method of claim 1 comprising preliminarily attaching each foil sheet to the respective underlying layer prior to said joining. 10. The method of claim 9 wherein the preliminarily attaching comprises preliminarily attaching each foil sheet to the respective underlying layer by spot welding. 11. The method of claim 1 wherein the material joining laser passes through openings in a mask on the foil sheet to impact the free, unobstructed surface of the foil sheet, and wherein the mask has cooling passages for cooling the surface of the foil sheet. 12. The method of claim 1 wherein the metal alloy is an amorphous metal alloy, the method comprising: sequentially stacking each of n number of amorphous alloy foil sheets on top of each other such that each of the n amorphous alloy foil sheets engages a respective underlying layer comprising another of the n amorphous alloy foil sheets; joining each of the n amorphous alloy foil sheets to the respective underlying layer using a material joining laser after each respective sheet is stacked on the respective underlying layer by striking a focused laser beam of the laser on a free, unobstructed surface of the foil sheet to melt and weld each amorphous alloy foil sheet to its respective underlying layer, wherein the laser does not travel through any polymer, glass, or other material against or near the amorphous alloy foil sheets; and removing material away from one or more of the n amorphous alloy foil sheets to shape said one or more of the n amorphous alloy foil sheets to correspond in shape with one or more respective slices of the metal amorphous alloy component; wherein said steps of joining each of the n amorphous alloy foil sheets to the respective underlying layer and removing amorphous alloy material from said one or more of the n amorphous alloy foil sheets are controlled based on shape data indicative of a shape of each of the n slices of the metal amorphous alloy component. 13. The method of claim 12 wherein the joining is performed in a cooling chamber. 14. The method of claim 13 wherein the cooling chamber as an internal temperature below about minus 50° C. 15. The method of claim 12 wherein the material joining laser is applied to the surface of the amorphous alloy foil sheet in sequential paths that do not overlap an immediately previously formed path to reduce heat accumulation. 16. The method of claim 12 wherein the material joining laser is applied to the surface of the amorphous alloy foil sheet by forming spot welds on the entire surface with each successive spot weld being formed where it does not overlap with an immediately previously formed spot weld to reduce heat accumulation. 17. The method of claim 12 comprising preliminarily attaching each amorphous alloy foil sheet to the respective underlying layer by spot welding after each of said sequentially stacking step and before each of said joining step. 18. The method of claim 12 comprising preliminarily attaching each amorphous alloy foil sheet to the respective underlying layer by spot welding after each of said sequentially stacking step and before each of said joining step; wherein the joining is performed in a cooling chamber having an internal temperature below at least about minus 50° C.; wherein during joining the material joining laser is applied to the surface of the amorphous alloy foil sheet a) in sequential paths that do not overlap an immediately previously formed path to reduce heat accumulation, or b) by forming spot welds on the entire surface with each successive spot weld being formed where it does not overlap with an immediately previously formed spot weld to reduce heat accumulation; and cutting material away from one or more of the n amorphous alloy foil sheets by slicing through the foil sheet and separating foil sheet segments not joined to the underlying layer to shape said one or more of the n amorphous alloy foil sheets to correspond in shape with one or more respective slices of the metal amorphous alloy component; wherein said steps of joining each of the n amorphous alloy foil sheets to the respective underlying layer and removing amorphous alloy material from said one or more of the n amorphous alloy foil sheets are controlled based on shape data indicative of a shape of each of the n slices of the metal amorphous alloy component. 19. The method of claim 12 comprising, after said joining, cutting material away from one or more of the n amorphous alloy foil sheets by slicing through the foil sheet and separating foil sheet segments not joined to the underlying layer to shape said one or more of the n amorphous alloy foil sheets to correspond in shape with one or more respective slices of the metal amorphous alloy component. 20. The method of claim 12 wherein the material joining laser passes through openings in a mask on the amorphous alloy foil sheet to impact the free, un