Method of manufacture and the use of a functional proppant for determination of subterranean fracture geometries

What is claimed is: 1. A proppant particle comprising: a core comprising a functional component selected from the group consisting of a cathodoluminescent material, a carbon nanotube(s), carbon nanoparticles, a reactive compound, a magnetic material, a super magnetic material, a paramagnetic material, conductive graphite and combinations thereof wherein the functional component is distributed throughout a glass matrix, ceramic matrix, or a glass-ceramic matrix; and a ceramic shell coating the core, wherein the reactive compound comprises an acid, a base, an explosive or a combination thereof. 2. The proppant particle of claim 1 , wherein the functional component is incorporated in the proppant particle as a discrete phase. 3. The proppant particle of claim 1 , wherein the functional component is incorporated in the proppant particle as a solid solution, an alloy, or any combination thereof. 4. The proppant particle of claim 1 , wherein the reactive compound comprises an acid, a base, or any combination thereof. 5. The proppant particle of claim 1 , wherein said functional component further comprises metallic particulates. 6. The proppant particle of claim 1 , wherein said functional component further comprises metal oxide particulates. 7. The proppant particle of claim 1 , wherein the d-block element comprises vanadium, niobium, tantalum, or any combination thereof. 8. The proppant particle of claim 1 further comprising cobalt, rhodium, or both. 9. The proppant particle of claim 1 further comprising cobalt. 10. The proppant particle of claim 9 , wherein the cobalt comprises 59 Co, 60 Co, 60 Co or any combination thereof. 11. The proppant particle of claim 1 , wherein the d-block element comprises nickel, palladium, platinum, or any combination thereof. 12. The proppant particle of claim 1 , wherein the d-block element comprises nickel. 13. The proppant particle of claim 12 , wherein said nickel is nickel oxide powder and is present as a layer having a concentration of nickel oxide powder of approximately 30 wt % based on the total weight of the layer. 14. The proppant particle of claim 12 , wherein the nickel is in the form of fibers, rods, or both. 15. The proppant particle of claim 1 , wherein the functional component further comprises iron. 16. The proppant particle of claim 1 , further comprising magnetite. 17. The proppant particle of claim 1 , wherein the d-block element is present in the form of a magnetic, super magnetic, and/or paramagnetic material. 18. The proppant particle of claim 1 , wherein the functional component further comprises iron, manganese, zinc, chromium, zirconium, molybdenum, yttrium, titanium, or any combination thereof. 19. A method for determining the geometry of a fracture in a geologic formation, the method comprising: positioning a detector in a position to measure a magnetic field generated from the geologic formation; injecting a proppant of claim 1 into the fracture wherein the proppant comprises a d-block element from the Periodic Table of Elements; measuring the magnetic field generated from the geologic formation; and determining the geometry of the fracture from the measured magnetic field. 20. The method of claim 19 , wherein the detector comprises one or more superconducting quantum interference device (SQUID). 21. A method for determining the geometry of a fracture in a geologic formation, the method comprising: positioning one or more electrodes in a position to measure the electrical resistance of the geologic formation; injecting a proppant of claim 1 into the fracture wherein the proppant comprises a d-block element from the Periodic Table of Elements; measuring the electrical resistance of the geologic formation; and determining the geometry of the fracture from the measured electrical resistance. 22. A method for determining the geometry of a fracture in a geologic formation, the method comprising: positioning a ground penetrating radar detector in a position to radiate electromagnetic signals into the geologic formation and to detect electromagnetic signals reflected from the geologic formation; injecting a proppant of claim 1 into the fracture wherein the proppant comprises a d-block element from the Periodic Table of Elements; radiating electromagnetic signals into the geologic formation; measuring electromagnetic signals that are reflected from the geologic formation; and determining the geometry of the fracture from the reflected electromagnetic signals. 23. A method for determining the geometry of a fracture in a geologic formation, the method comprising: positioning a detector in a position to measure photons emitted from the geologic formation; injecting a proppant of claim 1 into the fracture wherein the proppant comprises a cathodoluminescent material; irradiating the proppant of claim 1 with an energy source sufficient to induce the cathodoluminescent material to emit photons; measuring the photons emitted from the geologic formation; and determining the geometry of the fracture from the measured photons. 24. The method of claim 23 , wherein the detector comprises an array of photomultiplier tubes, an array of photodetectors, photographic film, a CCD device, or a combination thereof, and wherein the detector is sent down hole to measure the photons emitted from the geologic formation. 25. A method for heating a proppant pack in a fracture in a geologic formation, the method comprising: providing a source of electromagnetic radiation; injecting a proppant of claim 1 into the fracture, wherein the proppant comprises carbon nanotubes, carbon nanoparticles, or a combination thereof; and irradiating the proppant with electromagnetic radiation sufficient to induce the proppant to generate heat. 26. The method of claim 25 , wherein the proppant further comprises a carrier fluid and the method comprises generating a sufficient amount of heat to degrade the carrier fluid. 27. The method of claim 25 , wherein crude oil is present in the fracture, the irradiating comprises generating sufficient heat to reduce the viscosity of the crude oil, and the method further comprises recovering the crude oil. 28. A method for etching rock in a fracture in a geologic formation, the method comprising: injecting a proppant of claim 1 into the fracture wherein the proppant comprises a ceramic matrix and an etching chemical; generating a sonic signal from a sonic signal source, of sufficient strength to liberate the etching chemical from the proppant; contacting the rock with the liberated etching chemical; and etching the rock with the etching chemical. 29. A method for determining the geometry of a fracture in a geologic formation, the method comprising: positioning a detector in a position where it is operable to measure sonic signals emitted from the geologic formation; injecting a proppant of claim 1 into the fracture, the proppant comprising an explosive material; detonating the explosive material to generate a sonic signal; detecting the sonic signal; and determining the geometry of the fracture from the sonic signal detected. 30. The method of claim 29 , wherein said detonating is triggered by fracturing, pressure, temperature, or chemical leaching, within the geologic formation and, optionally, further comprisin