Controlling hydraulic fracture growth using stress shadows

What is claimed is: 1. A method for controlling the growth of a hydraulic fracture using a stress shadow generated during a hydraulic fracturing operation, comprising: selecting a stage pair comprising a first stage and a second stage for which hydraulic fractures are to be generated via a hydraulic fracturing operation; hydraulic fracturing the first stage to generate a corresponding first hydraulic fracture; controlling a magnitude of a stress shadow originating from the first hydraulic fracture by varying at least one parameter of the hydraulic fracturing operation, wherein the stress shadow is controlled so as to provide a second hydraulic fracture of a target fracture shape for the second stage; and hydraulic fracturing the second stage to generate the second hydraulic fracture with the target fracture shape. 2. The method of claim 1 , comprising executing the method for a group of stages comprising at least one additional stage by: hydraulic fracturing the at least one additional stage to generate at least one corresponding hydraulic fracture; and controlling magnitudes of stress shadows originating from the first hydraulic fracture and the at least one additional hydraulic fracture by varying at least one parameter of the hydraulic fracturing operation, where the stress shadows are controlled so as to provide the second hydraulic fracture with the target fracture shape. 3. The method of claim 1 , wherein the at least one parameters comprises at least one of: a number of stage buffers; a well spacing; a well stacking; a fracture order; a time between the hydraulic fracturing of the first stage and the second stage; a stage spacing; a cluster spacing; a cluster orientation; a number of clusters in a stage; a pad design; a number of fracture crews per development; a fracture plug design; a pressure in at least one interacting well; or a fracturing fluid design. 4. The method of claim 1 , further comprising, prior to the hydraulic fracturing of the second stage, assessing the magnitude of the stress shadow using at least one of fracture diagnostics or fracture modeling. 5. The method of claim 4 , further comprising, if the magnitude of the stress shadow has not been effectively controlled, varying at least one other parameter of the hydraulic fracturing operation prior to the hydraulic fracturing of the second stage. 6. The method of claim 1 , comprising selecting the stage pair comprising the first stage and the second stage by: selecting a stage of a first well as the first stage; and selecting a corresponding stage of a second well in an adjoining bench as the second stage. 7. The method of claim 1 , comprising selecting the stage pair comprising the first stage and the second stage by: selecting a stage of a parent well as the first stage; and selecting a corresponding stage of a child well as the second stage; and wherein controlling the magnitude of the stress shadow originating from the first hydraulic fracture for the first stage corresponding to the parent well by varying the at least one parameter of the hydraulic fracturing operation comprises increasing a pressure in the parent well to temporarily increase the magnitude of the stress shadow originating from the first hydraulic fracture while the second stage corresponding to the child well is hydraulically fractured. 8. The method of claim 1 , further comprising predetermining the target fracture shape for the second hydraulic fracture based on at least one of net pay maps or data from previous production operations. 9. The method of claim 1 , wherein the first stage is positioned at least partially above the second stage, wherein the target fracture shape comprises a large lateral dimension to cover a wider area within a corresponding bench, and wherein controlling the magnitude of the stress shadow originating from the first hydraulic fracture by varying the at least one parameter of the hydraulic fracturing operation comprises setting the at least one parameter such that a higher magnitude stress shadow is achieved so as to generate the second hydraulic fracture in a primarily lateral direction. 10. The method of claim 1 , wherein the first stage is positioned at least partially to one side of the second stage, wherein the target fracture shape comprises a large vertical dimension, and wherein controlling the magnitude of the stress shadow originating from the first hydraulic fracture by varying the at least one parameter of the hydraulic fracturing operation comprises setting the at least one parameter such that a higher magnitude stress shadow is achieved so as to generate the second hydraulic fracture in a primarily vertical direction. 11. The method of claim 1 , comprising executing the method for a plurality of stage pairs to generate a plurality of corresponding hydraulic fractures with target fracture shapes. 12. The method of claim 11 , comprising: generating a modified well spacing plan for a field in which the wells corresponding to the plurality of stage pairs are located, wherein the modified well spacing plan comprises fewer wells than an original well spacing plan; and implementing the modified well spacing plan in the field, wherein the modified well spacing plan results in a substantially similar amount of hydrocarbon production as compared to the original well spacing plan. 13. The method of claim 11 , comprising: generating a modified completion plan for at least one drilled but uncompleted well that is located in a field in which the wells corresponding to the plurality of stage pairs are located, wherein the modified completion plan comprises a lower fracturing fluid utilization than an original completion plan; and implementing the modified completion plan in the field, wherein the modified completion plan results in a substantially similar amount of hydrocarbon production as compared to the original completion plan. 14. A hydrocarbon well system, comprising: a first well in a first bench; a second well in a second bench, wherein the first bench and the second bench are positioned such that interacting hydraulic fractures can be generated for corresponding stages of the first well and the second well, wherein a first stage of the first well comprises a corresponding first hydraulic fracture, wherein a second stage of the second well comprises a second hydraulic fracture of a target fracture shape, wherein the first hydraulic fracture is generated prior to the second hydraulic fracture, and wherein a magnitude of a stress shadow originating from the first hydraulic fracture during a corresponding hydraulic fracturing operation is utilized to provide the target fracture shape for the second hydraulic fracture; and a computing system that is communicably coupled to the first well and the second well, wherein the computing system comprises: a processor; and a non-transitory, computer-readable storage medium comprising program instructions that are executable by the processor to cause the processor to control the magnitude of the stress shadow originating from the first hydraulic fracture by varying at least one parameter of the hydraulic fracturing operation. 15. The hydrocarbon well system of claim 14 , comprising at least one additional well with at least one corresponding hydraulic fracture, wherein the magnitudes of stress shadows originating from the first hydraulic fracture and the at least one additional hydraulic fracture during the hydraulic fracturing operation are utilized to provide the target fracture shape for the second hydraulic fracture. 16. The hydro