Superconducting switches

The invention claimed is: 1 . An electrical switch comprising: a length of superconducting material configured to carry a transport current, wherein the length of superconducting material has a critical current and a critical temperature; a magnetic field generator configured to apply a magnetic field to the length of superconducting material; and a heating assembly for heating the length of superconducting material, wherein the magnetic field generator and the heating assembly are configured to be selectively controlled independently or in combination to switch the length of superconducting material between a low-resistance state and a higher resistance state, wherein, in the low-resistance state, a magnitude of the magnetic field is relatively low and a temperature of the length of superconducting material is substantially less than the critical temperature such that the transport current is substantially less than the critical current, wherein, in a first configuration of the electrical switch in the higher-resistance state, the magnitude of the magnetic field is relatively high to reduce the critical current; wherein, in a second configuration of the electrical switch in the higher-resistance state, the heating assembly heats the length of superconducting material to reduce the critical current, wherein, in a third configuration of the electrical switch in the higher-resistance state, the magnitude of the magnetic field is relatively high and the heating assembly heats the length of superconducting material to reduce the critical current, and wherein, in each of the configurations of the electrical switch in the higher-resistance state, the critical current is reduced such that the transport current approaches the critical current, is substantially equal to the critical current or is greater than the critical current of the length of superconducting material. 2 . An electrical switch as claimed in claim 1 , wherein the magnetic field generator and the heating assembly are configured to be selectively activated and de-activated independently or in combination to switch the electrical switch between the low-resistance state and the higher resistance state. 3 . An electrical switch as claimed in claim 2 , wherein the heating assembly is configured to remain activated and the length of superconducting material is switched between the low-resistance state and the higher-resistance state by selective de-activation and activation of the magnetic field generator. 4 . An electrical switch as claimed in claim 1 , wherein the magnetic field applied by the magnetic field generator is a constant magnetic field. 5 . An electrical switch as claimed in claim 1 , wherein the heating assembly comprises a resistive heating element positioned in thermal contact with the length of superconducting material. 6 . An electrical switch as claimed in claim 1 , wherein the superconducting material is a high-temperature superconducting material. 7 . An electrical switch as claimed in claim 1 , wherein the magnetic field generator is a first magnetic field generator and the magnetic field is a first magnetic field, and wherein the electrical switch comprises a second magnetic field generator configured to apply a second, time-varying, magnetic field to the length of superconducting material, wherein the second magnetic field generator is configured to be selectively controlled to switch the length of superconducting material between the low-resistance state and the higher resistance state. 8 . An electrical switch as claimed in claim 7 , wherein the superconducting material is a tape having two opposed faces, and wherein the second magnetic field generator is configured to apply the second magnetic field in a direction substantially perpendicular to the two opposed faces. 9 . An electrical switch as claimed in claim 7 , wherein the first magnetic field generator and the second magnetic field generator are the same magnetic field generator, wherein the magnitude of the magnetic field applied by the same magnetic field generator varies in time with a DC bias. 10 . An electrical switch as claimed in claim 1 , wherein: the length of superconducting material comprises a loop of superconducting material configured to carry the transport current between a first terminal and a second terminal, wherein the loop comprises a first branch and a second branch, the first and second branches being electrically connected in parallel between the first terminal and the second terminal, and wherein the loop has an axis which is substantially normal to the plane of the loop, and the electrical switch further comprises: a third, time-varying, magnetic field generator configured to apply a third, time-varying, magnetic field through the loop with the direction of the third magnetic field through the loop being generally parallel to, or having a component which is generally parallel to, the axis of the loop, wherein, in the low-resistance state, the third magnetic field generator does not apply the third magnetic field through the loop and the transport current flows through the loop between the two terminals, and wherein, in the higher-resistance state, the third magnetic field generator applies the third magnetic field through the loop, inducing a screening current in the loop such that a total current in one or more of the first branch and the second branch approaches the critical current, is substantially equal to the critical current or is greater than the critical current of the superconducting material. 11 . An electrical switch as claimed in claim 1 , wherein, in the higher-resistance state, the length of superconducting material is in a superconducting state. 12 . An electrical switch comprising: a length of superconducting material configured to carry a transport current, wherein the length of superconducting material has a critical current and a critical temperature; a first magnetic field generator configured to apply a first, constant, magnetic field to the length of superconducting material; and a second magnetic field generator configured to apply a second, time-varying, magnetic field to the length of superconducting material, wherein the first magnetic field generator and the second magnetic field generator are configured to be selectively controlled independently or in combination to switch the length of superconducting material between a low-resistance state and a higher resistance state, wherein, in the low-resistance state, magnitudes of the first magnetic field and the second magnetic field are relatively low and the transport current is substantially less than the critical current, wherein, in a first configuration of the electrical switch in the higher-resistance state, the magnitude of the first magnetic field is relatively high to reduce the critical current such that the transport current approaches the critical current, is substantially equal to the critical current or is greater than the critical current of the length of superconducting material, wherein, in a second configuration of the electrical switch in the higher-resistance state, the second magnetic field creates dynamic resistance in the length of superconducting material, and wherein, in a third configuration of the electrical switch in the higher-resistance state, the magnitude of the first magnetic field is relatively high to reduce the critical current such that the transport current approaches the critical current, is substantially equal to the critical current or is greater than the critical current of the length of superconducting material, and the second magnetic field creates dynamic resistanc