Low-loss persistent current switch with heat transfer arrangement

What is claimed is: 1. An apparatus, comprising: a cryostat having an enclosure and a thermal shield disposed within the enclosure, the thermal shield defining an inner region, and further defining a thermal insulation region disposed between the thermal shield and the enclosure; a cold head having a first stage element disposed in the thermal insulation region, and a second stage element disposed in the inner region and being configured to operate at a lower temperature than a temperature of the first stage element; a first heat exchange element thermally coupled to the first stage element of the cold head; a second heat exchange element thermally coupled to the second stage element of the cold head; an electrically conductive coil disposed within the enclosure and configured to produce a magnetic field when an electrical current is passed therethrough; a persistent current switch disposed within the enclosure and connected across the electrically conductive coil, wherein the persistent current switch comprises a superconducting material which is electrically superconducting at a superconducting temperature and electrically resistive at a resistive mode temperature which is greater than the superconducting temperature; a persistent current switch heater configured to be selectively activated and deactivated so as to heat the persistent current switch to the resistive mode temperature; a convective heat dissipation loop; and a thermally conductive link thermally coupling the persistent current switch to the second heat exchange element, wherein the persistent current switch is thermally coupled via the convective heat dissipation loop directly to the first heat exchange element, and wherein the thermally conductive link comprises a material which has a first thermal conductivity at the superconducting temperature and has a second thermal conductivity at a second temperature which is greater than the superconducting temperature, wherein the first thermal conductivity is greater than the second thermal conductivity. 2. The apparatus of claim 1 , further comprising a superconducting convection cooling loop disposed within the enclosure and connected to the second heat exchange element, the superconducting convection cooling loop having a cryogenic fluid disposed therein and being configured to cool the electrically conductive coil to the superconducting temperature. 3. The apparatus of claim 2 , further comprising a controller configured to activate the persistent current switch heater during a magnet energization period wherein the electrically conductive coil is brought to the superconducting temperature and charged to produce the magnetic field with a particular strength, the controller further being configured to deactivate the persistent current switch heater during an operating period following the magnet energization period once the electrically conductive coil is charged to produce the magnetic field with the particular strength. 4. The apparatus of claim 3 , wherein during the magnet energization period more heat is transferred from the persistent current switch to the first heat exchange element via the convective heat dissipation loop than is transferred from the persistent current switch to the second heat exchange element via the thermally conductive link. 5. The apparatus of claim 1 , wherein the superconducting temperature is about 4° K and the first heat exchange element is at a temperature of about 40° K. 6. A method of operating a device comprising an electrically conductive coil, a persistent current switch connected across the electrically conductive coil, a persistent current switch heater, and a first heat exchange element thermally coupled to a first stage element of a two-stage cold head, and also thermally coupled via a convective heat dissipation loop to the persistent current switch without a second heat exchange element being included in the convective heat dissipation loop, wherein the persistent current switch comprises a superconducting material which is superconducting at a superconducting temperature and electrically resistive at a resistive mode temperature which is greater than the superconducting temperature, and a thermally conductive link thermally coupling the persistent current switch to the second heat exchange element, wherein the thermally conductive link comprises a material which has a first thermal conductivity at the superconducting temperature and has a second thermal conductivity at a second temperature which is greater than the superconducting temperature, wherein the first thermal conductivity is greater than the second thermal conductivity, the method comprising, during a magnet energization period: cooling the electrically conductive coil to the superconducting temperature; heating the current switch heater so as to raise a temperature of the persistent current switch to the resistive mode temperature; applying energy to the electrically conductive coil so as to charge the electrically conductive coil to produce a magnetic field with a desired strength; and while applying the energy to the electrically conductive coil, dissipating heat from the persistent current switch to the first heat exchange element via the convective heat dissipation loop which does not include the second heat exchange element. 7. The method of claim 6 , further comprising disposing the first heat exchange element above the persistent current switch, and wherein during the magnet energization period the first heat exchange element is at a first temperature which is greater than the superconducting temperature. 8. The method of claim 7 , wherein the first temperature is about 40° K and the superconducting temperature is about 4° K. 9. The method of claim 6 , further comprising, during an operating period subsequent to the magnet energization period, dissipating heat from the persistent current switch to a second heat exchange element via a thermally conductive link, wherein the second heat exchange element is at the superconducting temperature during the operating period. 10. The method of claim 9 , wherein during the magnet energization period and during the operating period, the first heat exchange element is at a first temperature which is substantially greater than the superconducting temperature. 11. The method of claim 10 , wherein the superconducting temperature is about 4° K and the first temperature is about 40° K. 12. An apparatus, comprising: a persistent current switch comprising a superconducting material which is electrically superconducting at a superconducting temperature and electrically resistive at a resistive mode temperature which is greater than the superconducting temperature; a first heat exchange element thermally coupled to a first stage element of a cold head; a convective heat dissipation loop thermally coupling the persistent current switch to the first heat exchange element; a second heat exchange element spaced apart from the first heat exchange element and thermally coupled to a second stage element of the cold head wherein the second heat exchange element is not included in the convective heat dissipation loop thermally coupling the persistent current switch to the first heat exchange element; and a thermally conductive link thermally coupling the persistent current switch to the second heat exchange element; wherein the thermally conductive link comprises a material which has a first thermal conductivity at the superconducting temperature and has a second thermal conductivity at a second temperature which is greater than the superconducting temperature, wherein the first thermal conductivity is greater than the se