Subterranean heating with dual-walled coiled tubing

What is claimed is: 1. A dual-walled coiled tubing heating arrangement for stimulation of subterranean hydrocarbon production, the arrangement comprising: an inner coiled tubing string defining a flowbore along a length of the inner coiled tubing string; an outer coiled tubing string radially surrounding the inner coiled tubing string; an electrically conductive pathway interconnecting the inner and outer coiled tubing strings; a radio frequency power source to provide electrical energy to the inner and outer coiled tubing strings to cause said inner and outer coiled tubing strings to heat a surrounding subterranean formation; and a downhole condition monitoring arrangement operably associated with the inner and outer coiled tubing strings to detect one or more downhole conditions, the downhole condition monitoring system having: a fiber optic cable having a plurality of Bragg grating sensors; and an optical time domain reflectometer which is operably interconnected with the fiber optic cable for transmitting optical pulses into the fiber optic cable and analyzing the light that is returned, reflected or scattered therein. 2. The dual-walled coiled tubing heating arrangement of claim 1 further comprising an isolator disposed radially between the inner and outer coiled tubing strings to ensure separation of the inner and outer coiled tubing strings. 3. The dual-walled coiled tubing heating arrangement of claim 2 wherein the isolator comprises a plurality of discrete spacer rings formed of non-conductive material. 4. The dual-walled coiled tubing heating arrangement of claim 2 wherein the isolator comprises a spacer sleeve formed of non-conductive material. 5. The dual-walled coiled tubing heating arrangement of claim 2 wherein the isolator comprises a non-conductive coating disposed upon at least one of: an outer radial surface of the inner coiled tubing string, and an inner radial surface of the outer coiled tubing string. 6. The dual-walled coiled tubing heating arrangement of claim 1 wherein the electrically conductive pathway comprises a conductive ring secured to both the inner and outer coiled tubing strings. 7. The dual-walled coiled tubing heating arrangement of claim 1 wherein the electrically conductive pathway comprises a conductive centralizer that is affixed to the inner coiled tubing string, the centralizer having radially outwardly extending bows contacting the outer coiled tubing string. 8. The dual-walled coiled tubing heating arrangement of claim 1 further comprising: a space defined radially between the inner coiled tubing string and the outer coiled tubing string; and the space is sealed near the distal ends of the inner and outer coiled tubing strings. 9. The dual-walled coiled tubing heating arrangement of claim 8 wherein the space is sealed with a slidable packer. 10. The dual-walled coiled tubing heating arrangement of claim 1 wherein: the outer coiled tubing string having a distal end; and the inner coiled tubing string presents an elongated portion which protrudes beyond the distal end of the outer coiled tubing string. 11. The dual-walled coiled tubing heating arrangement of claim 1 wherein: a metallic liner overlies a portion of either an outer radial surface of the inner coiled tubing string or an inner radial surface of the outer coiled tubing string; and the portion of the dual-walled coiled tubing heating arrangement which includes a liner provides for a reduced amount of heating for the formation. 12. A dual-walled coiled tubing heating arrangement for stimulation of subterranean hydrocarbon production, the arrangement comprising: an inner coiled tubing string defining a flowbore along a length of the inner coiled tubing string; an outer coiled tubing string radially surrounding the inner coiled tubing string; an electrically conductive pathway interconnecting the inner and outer coiled tubing strings; a radio frequency power source to provide electrical energy to the inner and outer coiled tubing strings to cause the inner and outer coiled tubing strings to heat a surrounding subterranean formation; an isolator disposed radially between the inner and outer coiled tubing strings to ensure separation of the inner and outer coiled tubing strings; a space defined radially between the inner coiled tubing string and the outer coiled tubing string; and the space is sealed near the distal ends of the inner and outer coiled tubing strings with a slidable packer. 13. The dual-walled coiled tubing heating arrangement of claim 12 further comprising a downhole condition monitoring arrangement operably associated with the inner and outer coiled tubing strings to detect one or more downhole conditions. 14. The dual-walled coiled tubing heating arrangement of claim 12 wherein the electrically conductive pathway comprises a conductive centralizer that is affixed to the inner coiled tubing string, the centralizer having radially outwardly extending bows contacting the outer coiled tubing string. 15. A method of stimulating hydrocarbon production from a subterranean formation by heating, the method comprising the steps of: forming a dual-walled coiled tubing assembly having an inner coiled tubing string, an outer coiled tubing string which radially surrounds the inner coiled tubing string, and a conductive path between the inner and outer coiled tubing strings; injecting the dual-walled coiled tubing assembly into a wellbore; operably associating a radio frequency power source with the inner and outer coiled tubing strings; energizing the dual-walled coiled tubing assembly with the radio frequency power source to cause the dual-walled coiled tubing assembly to propagate radio frequency heating to the formation; and detecting one or more downhole conditions with a downhole condition monitoring arrangement which is operably associated with the inner and outer coiled tubing strings and having a fiber optic cable with a plurality of Bragg grating sensors and an optical time domain reflectometer which is operably interconnected with the fiber optic cable for transmitting optical pulses into the fiber optic cable and analyzing the light that is returned, reflected or scattered therein. 16. The method of claim 15 further comprising the step of coiling the dual-walled coiled tubing assembly onto a coiled tubing reel prior to injecting the dual-walled coiled tubing assembly into the wellbore. 17. The method of claim 15 wherein: the inner coiled tubing string includes an elongated portion which protrudes axially beyond a distal end of the outer coiled tubing string; and wherein the elongated portion propagates heating into the formation.