Encapsulated microenergetic material

The invention claimed is: 1. A method of mapping fractures in a geological formation, comprising the steps of: providing a main borehole that extends into the geological formation, providing a side borehole that extends into the geological formation away from said main borehole and is isolated from the main borehole, providing a fluid in said side borehole that is isolated from said main borehole wherein said fluid enters the fractures in the geological formation, encapsulating energetic materials by directing an inner fluid of said energetic materials into an injection tube thru a droplet forming nozzle forming droplets of said energetic materials that flow through a middle fluid that is a polymer and encase said droplets of said energetic materials with said polymer to produce said energetic materials encapsulated in said polymer, positioning said energetic materials encapsulated in said polymer in the fractures in the geological formation together with said fluid in the fractures in the geological formation, positioning a charge in said fluid in said side borehole that is isolated from said main borehole, detonating said charge in said fluid in said side borehole energetically stimulating said fluid resulting in initiation of said energetic materials encapsulated in said polymer in the fractures in the geological formation, and mapping the fractures in the geological formation. 2. The method of mapping fractures in a geological formation of claim 1 wherein said step of encapsulating energetic materials to produce energetic materials encapsulated in said polymer comprises encapsulating triamino-trinitrobenzene (TATB) to produce energetic materials encapsulated in said polymer. 3. A method of mapping fractures in a geological formation, comprising the steps of: providing a main borehole that extends into the geological formation, providing a side borehole that extends into the geological formation away from said main borehole and is isolated from the main borehole, providing a fluid in said side borehole that is isolated from said main borehole wherein said fluid enters the fractures in the geological formation, encapsulating energetic materials by directing an inner fluid of said energetic materials into an injection tube thru a droplet forming nozzle forming droplets of said energetic materials that flow through a middle fluid that is a polymer and encase said droplets of said energetic materials with said polymer to produce said energetic materials encapsulated in said polymer, positioning said energetic materials encapsulated in said polymer in the fractures in the geological formation together with said fluid in the fractures in the geological formation wherein said step of positioning said energetic materials encapsulated in said polymer in the fractures in the geological formation includes positioning proppants with said energetic materials encapsulated in said polymer in said fractures in the geological formation, positioning a charge in said fluid in said side borehole that is isolated from said main borehole, detonating said charge in said fluid in said side borehole energetically stimulating said fluid resulting in initiation of said energetic materials in the fractures in the geological formation, and mapping the fractures in the geological formation. 4. The method of mapping fractures in a geological formation of claim 3 wherein said step of positioning said energetic materials encapsulated in said polymer and positioning proppants with said energetic materials encapsulated in said polymer in the fractures in the geological formation comprises positioning a mixture of said energetic materials encapsulated in said polymer and proppants in the fractures in the geological formation. 5. A method of mapping fractures in a geological formation wherein the geological formation has existing fractures and wherein it becomes desirable to do further expansion of the existing fractures, comprising the steps of: providing a main borehole that extends into the geological formation, providing a side borehole that extends into the geological formation away from said main borehole and is isolated from the main borehole, encapsulating energetic materials by directing an inner fluid of said energetic materials into an injection tube thru a droplet forming nozzle forming droplets of said energetic materials that flow through a middle fluid that is a polymer and encase said droplets of said energetic materials with said polymer to produce said energetic materials encapsulated in said polymer, injecting a fluid containing proppants and said encapsulated microenergetic material into the geological formation, recovering said fluid thereby positioning said proppants and said energetic materials encapsulated in said polymer in the existing fractures in the geological formation, wherein when it becomes desirable to do further expansion of the existing fractures, detonating said energetic materials encapsulated in said polymer, and mapping the fractures in the geological formation wherein said step of mapping the fractures in the geological formation comprises seismic mapping the fractures in the geological formation. 6. The method of mapping fractures in a geological formation of claim 5 wherein said step of mapping the fractures in the geological formation comprises acoustic seismic mapping the fractures in the geological formation.