Segment pressing of shaped charge powder metal liners

What is claimed is: 1. A shaped charge liner, comprising: a plurality of liner segments for a shaped charge configured to perforate a sidewall of a wellbore upon detonation, wherein the plurality of liner segments comprises: a tip liner segment comprising a first group of compacted metal powder having a hollow cone shape with a trailing interface end disposed opposite a tip end, wherein the trailing interface end has a larger diameter than the tip end, and wherein the tip liner segment is configured to be disposed in a shaped charge casing of the shaped charge; and a base liner segment comprising a second group of compacted metal powder having a truncated hollow cone shape with a trailing base end disposed opposite a leading base interface end, wherein the trailing base end has a larger diameter than the leading base interface end, and wherein the base liner segment is configured to be disposed at least partially within the shaped charge casing, wherein each of the plurality of liner segments has a distinct density gradient along an axial length of the liner segment, wherein each of the plurality of liner segments are stacked and pressed together to form a single continuous liner, and wherein a variation between the distinct density gradients determines a momentum gradient of the single continuous liner that thereby affects a desired jetting profile through the sidewall of the wellbore upon detonation. 2. The shaped charge liner of claim 1 , wherein each liner segment of the plurality of liner segments comprises at least one interface feature configured to interface with a corresponding interface feature of an adjacent liner segment in the shaped charge casing to restrain at least lateral movement between the liner segment and the adjacent liner segment. 3. The shaped charge liner of claim 2 , wherein the at least one interface feature of each liner segment comprises a protrusion, a recess, or some combination thereof. 4. The shaped charge liner of claim 1 , wherein the density gradient comprises a first mean density between about 10 g/cm 3 to about 22 g/cm 3 at a leading end of each liner segment of the plurality of liner segments and a second mean density at a trailing end of each liner segment of the plurality of liner segments, wherein the second mean density is between about 95 percent to about 99 percent of the first mean density, and wherein the trailing end has a greater diameter than the leading end. 5. The shaped charge liner of claim 1 , wherein an axial length of each liner segment is between about 12 percent to about 50 percent of a combined axial length of the plurality of liner segments. 6. The shaped charge liner of claim 1 , wherein a thickness of each liner segment is between about 0.035 inches to about 0.11 inches. 7. The shaped charge liner of claim 1 , wherein the first group of compacted metal powder and the second group of compacted metal powder each comprise at least one metal or at least one metal alloy powder selected from the group consisting of iron, steel, copper, brass, bronze, manganese, molybdenum, nickel, tungsten, bismuth, tin, lead, tantalum, aluminum, an alloy thereof, and combinations thereof. 8. The shaped charge liner of claim 1 , where the plurality of liner segments further comprises at least one intermediate liner segment configured to be disposed between the tip liner segment and the base liner segment in the shaped charge casing, and wherein the tip liner segment, the intermediate liner segment, and the base liner segment are configured to stack in the shaped charge casing to form a hollow cone shape. 9. The shaped charge liner of claim 8 , wherein the at least one intermediate liner segment comprises a first intermediate liner segment and a second intermediate liner segment, wherein the first intermediate liner segment is disposed adjacent the tip liner segment, and wherein the second intermediate liner segment is disposed adjacent the base liner segment. 10. The shaped charge liner of claim 1 , wherein each of the plurality of liner segments has a distinct axial length based on a desired density gradient profile for the shaped charge liner. 11. The shaped charge liner of claim 10 , wherein the desired density gradient profile is characterized by one or more step changes in density. 12. The shaped charge liner of claim 11 , wherein the increased diameter of the trailing interface end relative to the tip end is based at least in part on a slant angle of the tip liner segment. 13. The shaped charge liner of claim 12 , wherein an axial length of the tip liner segment is between 12 and 50 percent of a combined axial length of the plurality of liner segments. 14. The shaped charge liner of claim 13 , wherein the tip liner segment further comprises graphite as lubricant. 15. The shaped charge liner of claim 10 , wherein the plurality of liner segments comprises between 2 and 8 liner segments. 16. The shaped charge liner of claim 15 , wherein the first group of compacted metal powder or the second group of compacted metal powder has at least one metal different from the other, wherein the difference further affects a desired jetting profile through the sidewall upon detonation. 17. The shaped charge liner of claim 1 , wherein the base liner segment comprises pure copper or a copper and lead alloy; and the tip liner segment comprises tungsten. 18. The shaped charge liner of claim 17 , wherein at least one liner segment of the plurality of liner segments is in a green state, wherein the green state comprises compaction of a liner segment into a desired shape without sintering or fusing. 19. The shaped charge liner of claim 1 , wherein each of the plurality of liner segments has the same axial length.