SU930086A1 - Nuclear magnetic resonance pulse spectrometer - Google Patents

Description

(5 ") PULSE SPECTROMETER OF NUCLEAR MAGNETIC RESONANCE

Claims (2)

The invention relates to devices for observing and recording the effect of magnetic resonance and can be used in various fields of research in physics, chemistry, biology, medicine, etc. Pulsed nuclear magnetic resonance spectrometers are known, for example, to observe and record the effect of magnetic resonance 0. A disadvantage of these devices is the occurrence of transients in the sensor circuit of the spectrometer after powerful excitatory RF pulses, which makes it difficult to study substances with short relaxation times. The closest to the invention in the technical essence is a device containing a series-connected master oscillator, an RF key, a control input which is connected to the first output of a programming device, a power amplifier, a sensor oscillation circuit for the test 1% of a sample, a polarizing magnet, a receiver 2J. However, it is not possible to record a nuclear magnetic resonance signal with a short decay time on such a spectrometer. This is due to the fact that after powerful excitation RF pulses in the oscillatory circuit of the sensor of the radio spectrometer transients arise with the frequency of the radio frequency pulse. Until the end of transients, a weak useful signal cannot be detected by a measuring device. As a result, the sensitivity of the spectrometer decreases due to a decrease in the useful signal during the transient time. The purpose of the invention is to increase sensitivity by reducing the transient time of the oscillatory circuit of the pulse-spectrum magnetic nuclear resonance sensor. The goal is achieved by the fact that in a pulsed spectrometer of nuclear magnetic resonance containing a series-connected master oscillator, an RF key, whose control input is connected to. the first output of the programming device, the power amplifier, the oscillating circuit of the sensor for the sample under study, a polarizing magnet and a signal receiver, are additionally introduced in series with an attenuator, a phase shifter, a second radio frequency key and a pulse shaper, the attenuator input connected to the output of the master oscillator, the output of the second radio frequency key connected to the input of the power amplifier; the input of the pulse generator is connected to the second output of the programming device. ovatel pulses - to the control input of the second key radiofrequency The drawing is a block diagram of the proposed device. The device contains a master oscillator 1, an attenuator 2, a phase shifter, radio frequency keys k and 5, a power amplifier 6, a pulse shaper 7, a programming device 8, a sensor loop 9, a polarizing magnet 10 and a receiver of NMR signals 11. The master oscillator 2 output is connected with the input of the attenuator 2, the output of which is connected to the input of the phase shifter 3. The input of the radio frequency key 4 is connected to the output of the master oscillator 1о The input of the radio frequency key 5 is connected to the output of the phase shifter 3 outputs of the radio frequency switches k and S We are at the input of the amplifier 6 power. The pulse shaper 7 is connected with its output to the control input of the RF key 5 and its input to the second output of the programming device 8, the first output after it is connected to the control input of the RF frequency switch 4. The oscillation circuit of the sensor 9 is connected to the output of the amplifier 6, and the output is connected to the input of the signal receiver 11. The device operates as follows,. The high frequency signal produced by the master oscillator 1 is passed through an RF key controlled by the programmer 8, and in the form of an RF pulse amplified by the power amplifier 6, is fed to the oscillating circuit of the single-coil sensor 9 with the sample under study. After the end of the rf pulse, the programming device 8 starts the pulse shaper 7, which controls the formation of a short rf transient damping pulse in the oscillatory circuit of the sensor 9. The damping pulse is generated as follows. The high frequency signal from the master oscillator T, pass through the attenuator; Ator 2 and phase shifter 3 are attenuated, shifted relative to the carrier phase of the exciting radio frequency pulse by 180 and through the RF switch 5 and the power amplifier 6 is fed to the oscillating circuit of sensor 9. As a result, after the action of the exciting radio frequency pulse, the transient oscillations with the frequency and phase of the radio frequency carrier damped by antiphase oscillations of the rf pulse of the same frequency; i.e. transient processes in the oscillatory circuit of the sensor are achieved by adjusting the amplitude and duration of the radio-frequency pulse damping with the help of an attenuator of the pulse former 7. After termination of transients in the oscillatory circuit of sensor 9, the useful nuclear magnetic resonance signal is amplified and detected by receiver 11. The use of additional elements - an attenuator, a phase shifter, a second radio frequency key distinguishes the proposed device from the known ones, as it reduces the transient time in the sensor circuit, increase the sensitivity of the spectrometer. The ability to measure substances with short relaxation times broadens the scope of application of the device. The invention includes a nuclear magnetic resonance pulse spectrometer, each comprising an associated master oscillator, with an RF key controlling input of which is connected to the first output of a programming device, a power amplifier, an oscillating sensor circuit for the sample under study with a polarizing magnet, and a signal receiver different the fact that, in order to increase the sensitivity by reducing the transient time of the oscillation circuit of the sensor, it is additionally introduced | Attentively connected attenuator, phase shifter, second radio frequency key and pulse shaper, with the attenuator input connected to p :, 0866 by the master oscillator stroke, the output of the second radio-frequency switch is connected to the input of the power amplifier, the input of the pulse generator is connected to the 5th second output of the programming device, and the output of the driver of the pulse generator is connected to the control input of the second radio-frequency switch, Information sources, taken into account during examination 1. Farrar T., Becker E. Pulse and Fourier-spectroscopy NMR. M., Mir, 1973, p. 60, 2. Daniel A, fletrel Pulse Fourier 15 transform nuclear magnetic resonance spectroscopy. Applied Spectroscopy, il972, U. 26, f i, p. 30 (prototype).