Proppant transport efficiency system and method

We claim: 1. A perforating gun comprising: a gun carrier having a longitudinal axis; a plurality of perforating charges housed within the gun carrier; wherein the plurality of perforating charges in the gun carrier are arranged to form plural clusters and to be discharged in a given stage of a well casing, wherein the plural clusters are associated with the given stage; wherein when deployed downhole, at least some of the plurality of perforating charges associated with one or more clusters of the plural clusters (i) are angled toe-ward, and (ii) have a precision shaped charge configuration that generates a constant entry hole, to create corresponding toe-ward angled perforation tunnels that achieve a predetermined proppant transport profile in the given stage; and wherein the predetermined proppant transport profile is defined by (A) distributing a first set proportion of (1) a proppant fraction and (2) a fluid fraction of a slurry in the corresponding toe-ward angled perforation channels associated with the one or more clusters, and (B) distributing a second set proportion of the proppant fraction and the fluid fraction of the slurry in perforation tunnels associated with other clusters of the plural clusters. 2. The perforating gun of claim 1 , wherein at least some of the plurality of perforating charges are reactive shaped charges. 3. The perforating gun of claim 1 , wherein the predetermined proppant transport profile comprises an even proppant distribution amongst each of the plural clusters. 4. The perforating gun of claim 1 , wherein the plurality of charges are phased equally around the longitudinal axis of the perforating gun. 5. The perforating gun of claim 1 , wherein the plurality of charges are positioned such that spacing between two adjacent said plurality of charges is equal. 6. The perforating gun of claim 1 , wherein the precision shaped charge configuration achieves for each of the plurality of toe-ward angled perforation tunnels an entrance hole diameter within 20% of a target entrance hole diameter. 7. The perforating gun of claim 1 , wherein each of the plurality of toe-ward angled perforation tunnels comprise an entrance hole configured with burrs. 8. The perforating gun of claim 1 , wherein an angle of each of the plurality of toe-ward angled perforating tunnels relative to a longitudinal axis of the well casing ranges from 5° to 90°. 9. The perforating gun of claim 1 , wherein an angle of each of the toe-ward angled plurality of tunnels relative to a longitudinal axis of the well casing is equal. 10. A perforating gun system comprising: a plurality of perforating guns comprising a gun carrier, and a plurality of perforating charges housed within the gun carrier; wherein the plurality of perforating charges in the gun system are arranged to form plural clusters and to be discharged in a given stage of a well casing, wherein the plural clusters are associated with the given stage; wherein when deployed downhole, at least some of the plurality of perforating charges associated with one or more clusters of the plural clusters (i) are angled toe-ward, and (ii) have a precision shaped charge configuration that generates a constant entry hole, to create corresponding toe-angled perforation tunnels that achieve a predetermined proppant transport profile in the given stage; and wherein the predetermined proppant transport profile is defined by (A) distributing a first set proportion of (1) a proppant fraction and (2) a fluid fraction of a slurry in the corresponding toe-ward angled perforation channels associated with the one or more clusters, and (B) distributing a second set proportion of the proppant fraction and the fluid fraction of the slurry in perforation tunnels associated with other clusters of the plural clusters. 11. The perforating gun system of claim 10 , wherein each of the plurality of perforating charges are reactive shaped charges. 12. The perforating gun system of claim 10 , wherein the predetermined proppant transport profile comprises an even proppant distribution amongst each of the plural clusters. 13. The perforating gun system of claim 10 , wherein the plurality of perforating charges are phased equally around a longitudinal axis of the plurality of perforating guns. 14. The perforating gun system of claim 10 , wherein the plurality of charges are positioned such that spacing between two adjacent said plurality of charges is equal. 15. The perforating gun system of claim 10 , wherein the precision shaped charge configuration achieves for each of the plurality of toe-angled perforation tunnels an entrance hole diameter within 20% of a target entrance hole diameter. 16. The perforating gun system of claim 10 , wherein each of the plurality of perforation tunnels comprise an entrance hole configured with burrs. 17. The perforating gun system of claim 10 , wherein an angle of each of the plurality of perforating tunnels relative to a longitudinal axis of the well casing ranges from 5° to 90°. 18. The perforating gun system of claim 10 , wherein an angle of the plurality of tunnels relative to a longitudinal axis of the well casing is equal. 19. A perforating method comprising: providing a perforating gun system comprising one or more perforating guns in a gun string, each gun comprising a gun carrier, and a plurality of perforating charges housed within the gun carrier, the plurality of perforating charges forming plural clusters that belong to a given stage; selecting an arrangement for each perforation charge, wherein at least some of the plurality of perforating charges associated with one or more clusters of the plural clusters (i) are angled toe-ward and (ii) have a precision shaped charge configuration that generates a constant entry hole, to create corresponding toe-ward angled perforation tunnels that achieve a predetermined proppant transport profile in the given stage; deploying the perforating gun system into the well casing in the given stage; and perforating the given stage to create the corresponding toe-ward angled perforation tunnels, wherein each of the plurality of tunnels are oriented in a predetermined arrangement and have the predetermined proppant transport profile, wherein the predetermined proppant transport profile is defined by (A) distributing a first set proportion of (1) a proppant fraction and (2) a fluid fraction of a slurry in the corresponding toe-ward angled perforation channels associated with the one or more clusters, and (B) distributing a second set proportion of the proppant fraction and the fluid fraction of the slurry in perforation tunnels associated with other clusters of the plural clusters. 20. The perforating method of claim 19 , wherein each of a plurality of angles of each of the plurality of perforation tunnels relative to the longitudinal axis of the casing ranges from 5° to 90°. 21. The perforating method of claim 19 , wherein the precision shaped charge configuration achieves for each of the plurality of perforation tunnels an entrance hole diameter within 20% of a target entrance hole diameter.