High energy blasting

What is claimed is: 1. A method of fragmenting and fracturing rock for subsequent comminution and mineral recovery, the method comprising drilling blastholes in a blast zone, loading the blastholes with explosives and then firing the explosives in the blastholes in a single cycle of drilling, loading and blasting, wherein the blast zone comprises a high energy blast zone in which blastholes are partially loaded with a first explosive to provide a high energy layer of the high energy blast zone having a powder factor of at least 1.75 kg of explosive per cubic meter of unblasted rock in the high energy layer and in which at least some of those blastholes are also loaded with a second explosive to provide a low energy layer of the high energy blast zone, the high energy layer being beneath the low energy layer, said low energy layer having a powder factor that is at least a factor of two lower than the powder factor of said high energy layer, wherein the blasting comprises blasting in the high energy zone by firing the explosives in the high and low energy layers sequentially, the first explosive in the high energy layer being fired after the second explosive in the low energy layer. 2. A method according to claim 1 , wherein the low energy layer has a powder factor of at most 1.5 kg of second explosive per cubic meter of unblasted rock in the low energy layer. 3. A method according to claim 1 , wherein the low energy layer has a depth or thickness, in a direction perpendicularly away from the high energy layer, of at least 2 m. 4. A method according to claim 1 , wherein the high energy layer has a powder factor of at least 2.5 kg of first explosive per cubic meter of unblasted rock in the high energy layer. 5. A method according to claim 1 , wherein at least those blastholes in the high energy zone loaded with both first explosive and second explosive have a first diameter portion loaded with the first explosive and a second diameter portion loaded with the second explosive, and wherein the first diameter is greater than the second diameter. 6. A method according to claim 1 , wherein, relative to the second explosive, the first explosive has at least one of a greater density, a greater blast energy per unit mass, and a greater blast velocity of detonation. 7. A method according to claim 1 , wherein the first explosive is the same as the second explosive. 8. A method according to claim 1 , wherein the blasting of the second explosive in the low energy layer results in a blanket of blasted material over the high energy layer. 9. A method according to claim 1 , wherein any charge of the explosive to be fired in the high energy layer is fired at least about 500 ms after firing the nearest charge of the explosive in the low energy layer. 10. A method according to claim 9 , wherein a first charge of the explosive to be fired in the high energy layer is fired at least about 500 ms after firing the last charge of the explosive in the low energy layer. 11. A method according to claim 1 , wherein the blasting is in an open cut mine in which the blastholes extend downwardly, and wherein at least some of the blastholes in the high energy blast zone loaded with first explosive are also loaded with further explosive to provide a second low energy layer between the high energy layer and toes of the blastholes in the high energy blast zone, said second low energy layer having a powder factor that is at least a factor of two lower than the powder factor of the high energy layer. 12. A method according to claim 1 , wherein the blasting is in an underground mine and the first explosive and the second explosive are loaded, respectively, closer to a collar of the blastholes and closer to a toe of the blastholes, and wherein at least some of the blastholes in the high energy blast zone loaded with first explosive are also loaded with further explosive to provide a second low energy layer between the high energy layer and the collars of the blastholes in the high energy blast zone, said second low energy layer having a powder factor that is at least a factor of two lower than the powder factor of the high energy layer. 13. A method according to claim 1 , wherein the blast zone has a perimeter, and the high energy blast zone is isolated from the perimeter by a low energy blast zone comprising blastholes that are drilled, loaded and blasted in said single cycle, said blastholes in the low energy blast zone being loaded with explosive to provide a powder factor that is at least a factor of two lower than the powder factor of the high energy layer of the high energy blast zone. 14. A method according to claim 13 , wherein the low energy blast zone has a powder factor of at most 1.5 kg of explosive per cubic meter of unblasted rock in the low energy blast zone. 15. A method according to claim 13 , wherein the low energy blast zone extends entirely around the high energy blast zone. 16. A method according to claim 13 , wherein the explosives in the high energy blast zone are fired according to at least one of: after at least the nearest explosive in the low energy blast zone has been fired; at least about 500 ms after at least the nearest explosive in the low energy blast zone has been fired; after all of the explosive in the low energy blast zone has been fired; and at least about 500 ms after all of the explosive in the low energy blast zone has been fired. 17. A method according to claim 8 , wherein the rock blasted in the high energy blast zone remains within the blast zone. 18. In open cut mining for recoverable mineral, a method of blasting rock comprising drilling blastholes in a blast zone, loading the blastholes in the blast zone with explosives and then firing the explosives in the blastholes in the blast zone in a single cycle of drilling, loading and blasting, wherein: the blast zone comprises a high energy blast zone in which blastholes are partially loaded with a first explosive to provide a high energy layer of the high energy blast zone having a powder factor of at least 1.75 kg of explosive per cubic meter of unblasted rock in the high energy layer and in which at least some of those blastholes are also loaded with a second explosive to provide a low energy layer of the high energy blast zone, the low energy layer having a powder factor that is at least a factor of two lower than the powder factor of the high energy layer, and the high energy layer being beneath the low energy layer; and the blast zone has a perimeter from which the high energy blast zone is isolated by a low energy blast zone comprising blastholes that are drilled, loaded and blasted in the single cycle, the blastholes in the low energy blast zone being loaded with explosive to provide a powder factor that is at least a factor of two lower than the powder factor of the high energy layer of the high energy blast zone. 19. A method according to claim 18 , wherein the low energy layer has a powder factor of at most 1.5 kg of second explosive per cubic meter of unblasted rock in the low energy layer. 20. A method according to claim 18 , wherein the low energy layer has a depth or thickness, in a direction perpendicularly away from the high energy layer, of at least 2 m. 21. A method according to claim 18 , wherein the high energy layer has a powder factor of at least 2.5 kg of first explosive per cubic meter of unblasted rock in the high energy layer. 22. A method according to claim 18 , wherein at least those blastholes in the high ene