System and method for reducing heat loss from FRC bulk plasma

What is claimed is: 1. A field reversed configuration (FRC) fusion reactor, comprising: a main chamber containing an FRC core and an energy and ash removal shell (EARS), the FRC core comprising fuel and ash; and at least one divertor chamber connected to the main chamber via a divertor throat, the divertor chamber comprising a solid plasma extruder object suspended inside the divertor chamber, the solid plasma extruder object being positioned on a major axis of the FRC fusion reactor and a distance along the major axis from the divertor throat such that the ash but not the fuel is exhausted, the solid plasma extruder object configured to block plasma flow towards the FRC core to create a gap region between the FRC core and the EARS. 2. The FRC fusion reactor of claim 1 , wherein the solid plasma extruder object is made of heat- and sputter-resistant material. 3. The FRC fusion reactor of claim 1 , wherein the solid plasma extruder object is at least one of a conical, spherical, and cylindrical shape. 4. The FRC fusion reactor of claim 1 , further comprising a plurality of axial field magnets. 5. The FRC fusion reactor of claim 1 , wherein the divertor chamber is a gas box containing neutral gas and plasma. 6. The FRC fusion reactor of claim 5 , wherein the solid plasma extruder object is further configured to reduce neutral gas flow from the divertor chamber into the main chamber. 7. A method of operating a field reversed configuration (FRC) fusion reactor, the FRC fusion reactor having a main chamber containing an FRC core and an energy and ash removal shell (EARS), the FRC core containing fuel and ash, and at least one divertor chamber connected to the main chamber via a divertor throat, the divertor chamber having a solid plasma extruder object suspended inside the divertor chamber, the method comprising: positioning the solid plasma extruder object on a major axis of the FRC fusion reactor and a distance along the major axis from the divertor throat such that the ash but not the fuel is exhausted; and blocking plasma flow towards the FRC core via the solid plasma extruder object to create a gap region between the FRC core and the EARS. 8. The method of claim 7 , wherein the solid plasma extruder object is made of heat- and sputter-resistant material. 9. The method of claim 7 , wherein the solid plasma extruder object is at least one of a conical, spherical, and cylindrical shape. 10. A field reversed configuration (FRC) fusion reactor, comprising: a main chamber containing an FRC core and an energy and ash removal shell (EARS), the FRC core comprising fuel and ash; a first divertor chamber connected to the main chamber via a first divertor throat, the first divertor chamber comprising a first solid plasma extruder object suspended inside the first divertor chamber, the first solid plasma extruder object being positioned on a major axis of the FRC fusion reactor and a distance along the major axis from the divertor throat such that the ash but not the fuel is exhausted, the first solid plasma extruder object configured to block plasma flow towards the FRC core to create a gap region between the FRC core and the EARS; and a second divertor chamber connected to the main chamber via a second divertor throat, the second divertor chamber comprising a second solid plasma extruder object suspended inside the second divertor chamber, the second solid plasma extruder object being positioned on the major axis and a distance along the major axis from the divertor throat, the second solid plasma extruder object configured to block backflow plasma being near the FRC core. 11. The FRC fusion reactor of claim 10 , wherein the first solid plasma extruder object and the second solid plasma extruder object are made of heat- and sputter-resistant material. 12. The FRC fusion reactor of claim 10 , wherein the first solid plasma extruder object and second solid plasma extruder object are each at least one of a conical, spherical, and cylindrical shape. 13. The FRC fusion reactor of claim 10 , wherein the first divertor chamber is a gas box containing neutral gas and plasma. 14. The FRC fusion reactor of claim 13 , wherein the first solid plasma extruder object is further configured to reduce neutral gas flow from the first divertor chamber into the main chamber. 15. The FRC fusion reactor of claim 1 , further comprising at least one of axial and radial structures to support and position the solid plasma extruder object. 16. The FRC fusion reactor of claim 15 , wherein the axial and radial structures further comprise at least one linear actuator to control the distance of the solid plasma extruder object. 17. The FRC fusion reactor of claim 1 , wherein a material of the solid plasma extruder object comprises at least one of tungsten, tantalum, molybdenum, and ceramic. 18. The FRC fusion reactor of claim 10 , further comprising at least one of axial and radial structures to support and position the first solid plasma extruder object and the second solid plasma extruder object. 19. The FRC fusion reactor of claim 18 , wherein the axial and radial structures further comprise at least one linear actuator to control the distance of the first solid plasma extruder object and second solid plasma extruder object. 20. The FRC fusion reactor of claim 1 , wherein a material of the first solid plasma extruder object and a material of the second solid plasma extruder object each comprise at least one of tungsten, tantalum, molybdenum, and ceramic.