Defrosting apparatus with repositionable electrodes

What is claimed is: 1. A thermal increase system with a cavity for containing a load, the thermal increase system comprising: a first repositionable electrode disposed in the cavity; a first bus bar disposed in the cavity, the first repositionable electrode being physically and electrically connectable to the first bus bar; a second repositionable electrode disposed in the cavity; a second bus bar disposed in the cavity, the second repositionable electrode being physically and electrically connectable to the second bus bar; a plurality of shelf support structures disposed within the cavity, wherein the plurality of shelf support structures is configured to support the first and second repositionable electrodes at a plurality of heights within the cavity; and a radio frequency signal source electrically connected to one or both of the first repositionable electrode and the second repositionable electrode via the first bus bar and the second bus bar, respectively, the radio frequency signal source being configured to provide radio frequency energy to either or both of the first repositionable electrode and the second repositionable electrode. 2. The thermal increase system of claim 1 , wherein the first bus bar includes a first plurality of ports, the second bus bar includes a second plurality of ports, the first repositionable electrode plugs into one of the first plurality of ports, and the second repositionable electrode plugs into one of the second plurality of ports. 3. The thermal increase system of claim 1 , further comprising: a variable impedance matching network coupled between the radio frequency signal source and either or both of the first repositionable electrode and the second repositionable electrode and having a variable impedance, wherein the variable impedance matching network is configured to adjust the variable impedance based on one or more parameters of the radio frequency energy selected from the group consisting of: reflected power, both forward and reflected power, and an S11 parameter. 4. The thermal increase system of claim 1 , further comprising: a first repositionable shelf attached to the first repositionable electrode; and a second repositionable shelf attached to the second repositionable electrode, wherein the first repositionable shelf and the second repositionable shelf are supported by the plurality of shelf support structures. 5. The thermal increase system of claim 4 , further comprising: a first plurality of standoff isolators that attach the first repositionable shelf to the first repositionable electrode and that provide separation between the first repositionable shelf and the first repositionable electrode to electrically isolate the first repositionable shelf from the first repositionable electrode; and a second plurality of standoff isolators that attach the second repositionable shelf to the second repositionable electrode, and that provide separation between the second repositionable shelf and the second repositionable electrode to electrically isolate the second repositionable shelf from the second repositionable electrode. 6. The thermal increase system of claim 5 , wherein a standoff isolator of the first plurality of standoff isolators comprises: a cylindrical portion at a first end of the standoff isolator; a threaded portion at a second end of the standoff isolator opposite the first end, the threaded portion being inserted through a hole in the first repositionable electrode; and a threaded cap screwed onto the threaded portion to affix the standoff isolator to the first repositionable electrode. 7. The thermal increase system of claim 6 , wherein the cylindrical portion of the standoff isolator comprises a through-hole, and the first repositionable shelf comprises a rod that extends through the through-hole to attach the standoff isolator to the first repositionable shelf. 8. The thermal increase system of claim 1 , wherein the radio frequency signal source is further configured to provide a first balanced radio frequency signal to the first repositionable electrode via the first bus bar, and to provide a second balanced radio frequency signal to the second repositionable electrode via the second bus bar. 9. The thermal increase system of claim 1 , wherein the second repositionable electrode is electrically connectable to a ground terminal through the second bus bar. 10. A system, comprising: a containment structure forming a cavity; a first bus bar disposed in the cavity, the first bus bar including a first plurality of ports at a variety of heights from a bottom of the cavity; a first repositionable electrode disposed in the cavity at a first selectable height, one of the first plurality of ports receiving a first connector portion of the first repositionable electrode to electrically connect the first repositionable electrode to a first port of the first plurality of ports of the first bus bar; a second repositionable electrode disposed in the cavity at a second selectable height that is different from the first selectable height so that the first and second repositionable electrodes are parallel to each other; and a radio frequency signal source that supplies radio frequency energy to either or both of the first repositionable electrode or the second repositionable electrode. 11. The system of claim 10 , further comprising: a second bus bar disposed in the cavity, the second bus bar including a second plurality of ports, one of the second plurality of ports receiving a second connector portion of the second repositionable electrode to electrically connect the second repositionable electrode to a second port of the second plurality of ports of the second bus bar. 12. The system of claim 11 , wherein the second repositionable electrode is electrically connectable to ground through the second bus bar. 13. The system of claim 11 , further comprising: a plurality of support structures disposed at different heights at interior walls of the cavity; a first repositionable shelf supportable by a first subset of the plurality of support structures; a second repositionable shelf supportable by a second subset of the plurality of support structures; a first plurality of dielectric standoff isolators that attaches the first repositionable shelf to the first repositionable electrode and that provides separation between the first repositionable shelf and the first repositionable electrode; and a second plurality of dielectric standoff isolators that attaches the second repositionable shelf to the second repositionable electrode and that provides separation between the second repositionable shelf and the second repositionable electrode. 14. The system of claim 13 , wherein a dielectric standoff isolator of the first plurality of dielectric standoff isolators comprises: a cylindrical portion at a first end of the dielectric standoff isolator; a threaded portion at a second end of the dielectric standoff isolator opposite the first end, the threaded portion being inserted through a hole in the first repositionable electrode; and a threaded cap screwed onto the threaded portion to affix the dielectric standoff isolator to the first repositionable electrode. 15. The system of claim 11 , wherein the radio frequency signal source is electrically connected to the second bus bar and supplies radio frequency energy to the second repositionable electrode through the second bus bar. 16. The system of claim 10 , further comprising: a variable impedance matching network coupled between the radio frequency signal source and either or