FET switch as detune circuit for MRI RF coils

Having thus described the preferred embodiments, the invention is now claimed to be: 1. A radio frequency (RF) receive coil assembly for use in magnetic resonance, including: a radio frequency receive coil; and an electronic switch which switches between open and closed states to detune and tune the coil to a preselected resonance frequency, each electronic switch including: at least one field effect transistor (FET) and a bias network, wherein each of the at least one FET has a gate, wherein the bias network is configured to provide a bias voltage to the gate of each of the at least one FET to switch the at least one FET from the closed state to the open state, wherein the bias network is configured to provide the bias voltage in response to a self bias signal, the bias network further being configured to provide the bias voltage in response to a control signal, wherein the RF coil is a loop coil and the at least one FET is connected in the loop to tune the loop coil to the MR frequency when the at least one FET is closed and to detune the loop coil when the at least one FET is open, and wherein the electronic switch further includes a self bias network configured to generate the self bias signal by rectifying part of an incident RF signal. 2. The RF coil assembly according to claim 1 , wherein the bias network includes: a biasing circuit which generates the control signal to switch the at least one FET from the closed state to the open state. 3. The RF coil assembly according to claim 2 , wherein control signal is generated from at least one of an active bias signal or the self bias signal. 4. The RF coil assembly according to claim 1 , wherein the electronic switch further includes: a compensation circuit which removes parasitic capacitance from the electronic switch during the tuned state. 5. The RF coil assembly according to claim 1 , wherein the electronic switch has a resistance of less than 0.3 ohms during the tuned state and a resistance greater than 3000 ohms during the detuned state. 6. The RF coil assembly according to claim 5 , wherein the electronic switch withstands voltages of greater than 100 volts in the detuned state. 7. The RF coil assembly according to claim 6 , wherein the electronic switch includes an array of FETs placed in series to improve a voltage rating of the electronic switch. 8. A magnetic resonance method including: transmitting RF excitation signals at a magnetic resonance (MR) frequency to induce resonance signals in an examination region; with the electronic switch according to claim 1 , tuning an RF receive coil to the preselected resonance frequency to receive resonance signals from the examination region and detuning the RF receive coil to inhibit the RF receive coil from receiving the transmitted RF excitation signal; generating a bias voltage to switch the electronic switch to a non-conductive state to detune the RF receive coil. 9. The method according to claim 8 , wherein a switching time between the detuned and tuned state is less than 50 microseconds. 10. The method according to claim 9 , wherein the at least one FET and the bias network withstand voltages of greater than 100 volts in the detuned state. 11. A radio frequency (RF) coil assembly for use in magnetic resonance, including: a radio frequency receive coil; and an electronic switch which switches between open and closed states to detune and tune the coil to a preselected resonance frequency, the electronic switch including: an array of field effect transistors (FETs) connected in series to improve a voltage rating and reduce capacitance of the electronic switch, a bias network configured to bias the array of FETs to an open state to detune the coil, wherein the electronic switch has a switching time between the closed and open states of less than 50 microseconds, wherein the electronic switch has a resistance of less than 0.3 ohms during the open state and a resistance greater than 3000 ohms during the closed state, wherein the electronic switch withstands voltages of greater than 100 volts in the open state. 12. The RF coil assembly according to claim 11 , wherein the RF coil is a loop coil and the array of FETs is connected in the loop to tune the loop coil to an MR frequency when the array of FETs is closed and to detune the loop coil when the array of FETs is open. 13. The RF coil assembly according to claim 11 , wherein the bias network further includes: a self bias network which generates a self bias signal by rectifying part of an incident RF signal. 14. The RF coil assembly according to claim 13 , wherein the bias network further includes: a bias limiter which limits a voltage of the self bias signal. 15. The RF coil assembly according to claim 11 , wherein each FET of the FET array is fabricated from at least one of silicon-carbide FETs or gallium-nitride FETs. 16. The RF coil assembly according to claim 11 , wherein a plurality of the series connected arrays of FETs are placed in parallel to reduce resistance of the electronic switch. 17. A magnetic resonance system, including: a magnet which generates a static magnetic field in an examination region; a RF transmitter and a RF transmit coil which generates RF pulses at a magnetic frequency to excite and manipulate resonance in the examination region; at least one RF receive coil assembly according to claim 11 configured to acquire magnetic resonance data from the examination region; at least one RF receiver connected to the at least one RF coil assembly; a control circuit to generate a control signal to switch a state of the electronic switch; and a scan controller configured to control the RF transmitter and RF receiver and the control circuit. 18. The magnetic resonance system according to claim 17 , further including: a data processor which processes resonance data from the RF receiver to produce one of a magnetic resonance imaging data or magnetic resonance spectroscopy data; and a display which displays results of the resonance signal processing. 19. A magnetic resonance method, including: transmitting RF excitation signals at a magnetic resonance (MR) frequency to induce resonance signals in an examination region; with-the electronic switch according to claim 11 , tuning the RF receive coil to an MR frequency to receive resonance signals from the examination region and detuning the RF receive coil to inhibit the RF receive coil from receiving the transmitted RF excitation signal. 20. The method according to claim 19 , wherein the FETs of the array are fabricated from at least one of silicon-carbide FETs or gallium-nitride FETs.