Proppant additives for hydraulic fracturing

What is claimed is: 1. A method comprising: performing a hydraulic fracturing of a geological formation by injection of a proppant mixture into the geological formation to form fractures in the geological formation, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the hydraulic fracturing results in a presence of the proppant additive particles within the formed fractures, wherein the proppant additive particles are configured with a first complex conductivity that is measurably different than a second complex conductivity exhibited by materials comprising the geological formation, wherein the complex conductivity includes a real conductivity and an imaginary conductivity; and imaging the fractures formed in the geological formation with electromagnetic energy at one or more frequencies in a manner so that the proppant additive particles function as a contrast agent due to the first complex conductivity of the proppant additive particles being measurably different from the second complex conductivity, wherein the imaginary conductivity is measured from a polarization induced in the proppant additive particles by the electromagnetic energy. 2. The method as recited in claim 1 , wherein the imaging is produced from measured phase shift responses over a range of the one or more frequencies. 3. The method as recited in claim 1 , wherein a volume percentage of the proppant additive particles is about 100% or less of the proppant mixture. 4. The method as recited in claim 1 , wherein the proppant additive particles have sizes in substantially a range of sizes of the proppant. 5. A method comprising: performing a hydraulic fracturing of a geological formation by injection of a proppant mixture into the geological formation to form fractures in the geological formation, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the hydraulic fracturing results in a presence of the proppant additive particles within the formed fractures, wherein the proppant additive particles are configured with a first complex conductivity that is measurably different than a second complex conductivity exhibited by materials comprising the geological formation, wherein the complex conductivity includes a real conductivity and an imaginary conductivity; and imaging the fractures formed in the geological formation with electromagnetic energy at one or more frequencies in a manner so that the proppant additive particles function as a contrast agent due to the first complex conductivity of the proppant additive particles being measurably different from the second complex conductivity, wherein a volume percentage of the proppant additive particles in the proppant mixture injected within the formed fractures is less than the electrical percolation threshold for distinguishing the real conductivity of the first complex conductivity from the real conductivity of the second complex conductivity. 6. A method comprising: performing a hydraulic fracturing of a geological formation by injection of a proppant mixture into the geological formation to form fractures in the geological formation, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the hydraulic fracturing results in a presence of the proppant additive particles within the formed fractures, wherein the proppant additive particles are configured with a first complex conductivity that is measurably different than a second complex conductivity exhibited by materials comprising the geological formation; and imaging the fractures formed in the geological formation with electromagnetic energy at one or more frequencies in a manner so that the proppant additive particles function as a contrast agent due to the first complex conductivity of the proppant additive particles being measurably different from the second complex conductivity, wherein the proppant additive particles comprise coke breeze particles. 7. The method as recited in claim 6 , wherein the proppant mixture further comprises nanoparticles having an electromechanical frequency response different than that of the proppant additive particles, and wherein the nanoparticles are configured to penetrate into the geological formation surrounding the formed fractures. 8. The method as recited in claim 6 , wherein the proppant mixture further comprises nanoparticles having an electromechanical frequency response different than that of the proppant additive particles, and wherein the imaging the fractures formed in the geological formation is performed with at least two different frequencies so that images produced from the electromechanical frequency response of the nanoparticles are different than images produced from the electromechanical frequency response of the proppant additive particles. 9. A method comprising: performing a hydraulic fracturing of a geological formation by injection of a proppant mixture into the geological formation to form fractures in the geological formation, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the hydraulic fracturing results in a presence of the proppant additive particles within the formed fractures, wherein the proppant additive particles are configured with a first complex conductivity that is measurably different than a second complex conductivity exhibited by materials comprising the geological formation; and imaging the fractures formed in the geological formation with electromagnetic energy at one or more frequencies in a manner so that the proppant additive particles function as a contrast agent due to the first complex conductivity of the proppant additive particles being measurably different from the second complex conductivity, wherein the proppant additive particles comprise zero valent iron particles. 10. A system comprising: hydraulic fracturing equipment configured to inject a proppant mixture into a geological formation to form fractures in the geological formation and result in a presence of the proppant additive particles within one or more of the formed fractures, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the proppant additive particles are configured with a first complex conductivity that is measurably different than a second complex conductivity exhibited by materials comprising the geological formation; and imaging equipment configured to produce images of the fractures formed in the geological formation with electromagnetic energy at one or more frequencies in a manner so that the proppant additive particles present within one or more of the formed fractures function as a contrast agent due to the first complex conductivity of the proppant additive particles being measurably different from the second complex conductivity, wherein the proppant mixture further comprises nanoparticles having an electromechanical frequency response different than that of the proppant additive particles, and wherein the nanoparticles are configured to penetrate into the geological formation surrounding the formed fractures. 11. The system as recited in claim 10 , wherein the complex conductivity includes a real conductivity and an imaginary conductivity. 12. A system comprising: hydraulic fracturing equipment configured to inject a proppant mixture into a geological formation to form fractures in the geological formation and result in a presence of the proppant additive particles within one or more of the formed fractures, wherein the proppant mixture comprises a liquid, proppant, and proppant additive particles, wherein the pro