Control of fracture growth during well operation

What is claimed is: 1. A system for controlling fracture growth during operation of a well, the system comprising: one or more physical processors configured by non-transitory machine-readable instructions to: obtain fracture information for a layer, the fracture information characterizing a height of a fracture within the layer; obtain fracture limit information for the fracture, the fracture limit information characterizing a limit on change of the height of the fracture during fluid injection at an injection well in a reservoir; obtain layer stress information for the layer, the layer stress information characterizing stress in the layer; obtain bounding layer stress information for a bounding layer above the layer, the bounding layer stress information characterizing stress in the bounding layer; determine a dissipation equilibrium value for the fluid injection at the injection well based on the height of the fracture and the limit on change of the height of the fracture during the fluid injection at the injection well; determine an injection pressure limit for the fluid injection at the injection well based on the dissipation equilibrium value, the stress in the layer, and the stress in the bounding layer; and perform the fluid injection at the injection well based on the injection pressure limit determined using the dissipation equilibrium value, the stress in the layer, and the stress in the bounding layer, the fluid injection at the injection well promoting recovery of hydrocarbon through one or more production wells in the reservoir, wherein the injection pressure of the injection well is automatically controlled to not rise above the injection pressure limit, further wherein automatically preventing the injection pressure from rising above the injection pressure limit contains growth of the fracture within the bounding layer during the fluid injection. 2. The system of claim 1 , wherein the fluid injection includes waterflooding. 3. The system of claim 2 , wherein the waterflooding displaces or sweeps oil in the reservoir. 4. The system of claim 1 , wherein the limit on change of the height of the fracture during the well operation includes a maximum amount by which the height of the fracture is allowed to be changed during the fluid injection at the injection well. 5. The system of claim 1 , wherein the dissipation equilibrium value is determined based on a ratio of the limit on change of the height of the fracture during the fluid injection at the injection well to the height of the fracture. 6. The system of claim 5 , wherein the dissipation equilibrium value is a point on a dissipation equilibrium line, the point associated with the limit on change of the height of the fracture during the fluid injection at the injection well and the injection pressure limit for the fluid injection at the injection well. 7. The system of claim 6 , wherein the dissipation equilibrium line separates pressure values resulting in a negative change in dissipation rate of fluid flow from pressure values resulting in a positive change in dissipation rate of fluid flow. 8. The system of claim 1 , wherein the dissipation equilibrium value for the fluid injection at the injection well is determined based on the height of the fracture and the limit on change of the height of the fracture during the fluid injection at the injection well responsive to a non-slipping interface existing between the layer and the bounding layer, and the limit on change of the height of the fracture during the fluid injection at the injection well being less than the height of the fracture. 9. The system of claim 8 , wherein the dissipation equilibrium value for the fluid injection at the injection well is determined as one responsive to a slipping interface existing between the layer and the bounding layer. 10. The system of claim 9 , wherein the dissipation equilibrium value for the fluid injection at the injection well is determined as one responsive to the non-slipping interface existing between the layer and the boundary layer, and the limit on change of the height of the fracture during the fluid injection at the injection well being greater than the height of the fracture. 11. A method for controlling fracture growth during operation of a well, the method comprising: obtaining fracture information for a layer, the fracture information characterizing a height of a fracture within the layer; obtaining fracture limit information for the fracture, the fracture limit information characterizing a limit on change of the height of the fracture during fluid injection at an injection well in a reservoir; obtaining layer stress information for the layer, the layer stress information characterizing stress in the layer; obtaining bounding layer stress information for a bounding layer above the layer, the bounding layer stress information characterizing stress in the bounding layer; determining a dissipation equilibrium value for the fluid injection at the injection well based on the height of the fracture and the limit on change of the height of the fracture during the fluid injection at the injection well; determining an injection pressure limit for the fluid injection at the injection well based on the dissipation equilibrium value, the stress in the layer, and the stress in the bounding layer; and performing the fluid injection at the injection well based on the injection pressure limit determined using the dissipation equilibrium value, the stress in the layer, and the stress in the bounding layer, the fluid injection at the injection well promoting recovery of hydrocarbon through one or more production wells in the reservoir, wherein the injection pressure of the injection well is automatically controlled to not rise above the injection pressure limit, further wherein automatically preventing the injection pressure from rising above the injection pressure limit contains growth of the fracture within the bounding layer during the fluid injection. 12. The method of claim 11 , wherein the fluid injection includes waterflooding. 13. The method of claim 12 , wherein the waterflooding displaces or sweeps oil in the reservoir. 14. The method of claim 11 , wherein the limit on change of the height of the fracture during the well operation includes a maximum amount by which the height of the fracture is allowed to be changed during the fluid injection at the injection well. 15. The method of claim 11 , wherein the dissipation equilibrium value is determined based on a ratio of the limit on change of the height of the fracture during the fluid injection at the injection well to the height of the fracture. 16. The method of claim 15 , wherein the dissipation equilibrium value is a point on a dissipation equilibrium line, the point associated with the limit on change of the height of the fracture during the fluid injection at the injection and the injection pressure limit for the fluid injection at the injection well. 17. The method of claim 16 , wherein the dissipation equilibrium line separates pressure values resulting in a negative change in dissipation rate of fluid flow from pressure values resulting in a positive change in dissipation rate of fluid flow. 18. The method of claim 11 , wherein the dissipation equilibrium value for the fluid injection at the injection well is determined based on the height of the fracture and the limit on change of the height of the fracture during the fluid injection at the injection well responsive to a non-slipping interface existing between the layer and the bou