SU968718A1 - Radio spectrometer of electronic paramagnetic resonance - Google Patents

Description

(3) PAflMOCnEtCTPOMETP ELECTRON PARAMAGNETIC RESONANCE

one

The invention relates to radio spectroscopy and can be used in the design of equipment and the study of substances by the method of electronic magnetic resonance (EPR, FMR),

An electron paramagnetic resonance radio spectrometer is known in which the microwave generator is stabilized in frequency of the working resonator of the spectrometer with the help of an automatic frequency control modulated by the frequency of the microwave generator (MFR) 1.

Eff () the efficiency of the work of the IAHD in the main- The nom is determined by the Q of the resonator Qg as an amplitude-frequency discriminator with a slope of $ d. The range of automatic tuning is limited by the passband of the working resonator at the operating frequency f

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Q,

and, for example, for GHz and (is 2 MHz. Considering the influence of microwave power in the resonator, the degree of matching of the resonator with the generator, and some other factors on the shape of the discriminatory curve, this range is actually even smaller. When working with samples, different effects the working Q th resonator and introducing a frequency shift exceeding this range (in the example 2 MHz), when changing samples requires multiple manual tuning of the radio spectrometer. 5 The disadvantage of this device, therefore, is the narrow range n automatic frequency control.

The closest technical resolution to the inference is the electron paramagnetic resonance radio spectrometer, which contains an electromagnet with a control unit, generating 396

UHF torus, the output of which is connected through a circulator with a microwave detector and a working resonator, an automatic frequency control channel of the microwave generator, including a modulation generator connected to the modulating input of the microwave generator and to the reference input of the synchronous detector, the signal input of which is connected to the output of the microwave detector and the output is from the control input of the microwave generator, and the registration block, as well as the threshold device, the input of which is connected to the output of the microwave detector, and the output to the control logic circuit connected to the control Valid) m microwave generator 2.

The tuning system of the radio spectrometer is a scheme of a wide-range automatic tuning of the frequency of the microwave generator relative to the resonant frequency of the working resonator, including, in addition to the MAPC circuit, a threshold device and a logic device whose task is to drive the generator frequency to a fairly narrow bandwidth of the working resonator. When the frequency of the microwave generator and the resonator is not matched and the HSMC is cut off, a scanning device is activated that performs electromechanical tuning of the frequency of the microwave generator in a wide range. The criterion of the mismatch and the signal to turn on the scanning device is the excess of the microwave detector current threshold value (above 100 / 4A). With a smaller value of the detector current, the electronic circuit of the IOL circuit works, which ensures accurate matching of the frequencies of the microwave generator and the working resonator.

A disadvantage of the known device is a large adjustment time of the spectrometer. When the IOLA mismatch and stall, the circuit loses information on the relative position of the frequencies of the microwave generator and the working resonator, and the generator is tuned by scanning the entire tuning range until the current of the microwave detector is below the threshold value (). In each case of switching on the scanning scheme, the oscillator frequency frequency is equal both in the direction of the resonator frequency and from the edge of the range, and then the turn and retraction until the frequency coincides.

The aim of the invention is to reduce the tuning time of a radio spectrometer.

The goal is achieved by the fact that. In the electron paramagnetic resonance radio spectrometer, containing an electromagnet with a control unit, a microwave generator, the output of which is connected through a circulator with a microwave detector and a working resonator, an automatic frequency tuning channel of the microwave generator, including a modulation generator, connected to the modulating input of the microwave generator and with a synchronous reference input a detector, whose signal input is connected to the output of the microwave detector, and the output is connected to the control input of the microwave generator, and a recording unit, an additional channel has been introduced frequency tuning of the working resonator, made in the form of parallel-connected first and second two-threshold circuits, connected by outputs to series-connected control circuit and frequency tuning element of the operating resonator, with the input of the additional frequency control channel of the working resonator connected to the output of the synchronous detector, and the input of the registration unit is connected to the output of the microwave detector.

Fig. 1 shows the block diagram of the proposed radio spectrometer; Fig. 2 shows the dependence of the output voltage on the frequency.

Claims (2)

The radio spectrometer contains an electromagnet 1 with block 2 packs (events, unit 3 of registration is a microwave generator, the output of which is connected via a circulator 5 to the microwave detector 6 and the working resonator 7, the automatic frequency control of the microwave generator 4, including a generator 8, connected with a modulating input of the microwave generator and with a reference input of the synchronous detector 9 whose signal input is connected to the output of the microwave detector 6, and the output to the control input of the microwave generator, a working resonator frequency control channel connected to the output A synchronous detector 9 and made in the form of the first 10 and second 11 double-threshold circuits, the outputs of which are connected to the frequency control element 13 of the resonator 7 via the control circuit 12, and the input of the recording unit 3 is connected to the output of the microwave detector 6. The EPR radio spectrometer operates as follows The sample under study is placed in an electromagnetic microwave field, excited by 9 working resonators 7 using an oscillator and microwave and polarizing the magnetic field generated by electromagnet 1 connected to control unit 2. When the resonance conditions are fulfilled, the EPR signal in the form of an electromagnetic wave reflected from the resonator 7 is detected by the microwave detector 6 and recorded by the detection unit 3. The frequency of the microwave generator is tied to the resonant frequency of the working resonator 7 using the automatic frequency control channel of the microwave generator 4 as follows. The output power of the microwave generator is frequency modulated by applying to the modulating input of the microwave generator of the modulating voltage from the modulation generator 8. From this generator, the reference voltage for the synchronous detector 9 is obtained. In this case, the working resonator 7 performs the role of an amplitude-frequency discriminator, at the output of which the frequency modulation of the microwave generator k is converted into amplitude modulation. Conversion efficiency It is proportional to the slope of the resonant curve of the working resonator 7. In the middle of the resonant curve, the slope is zero, which corresponds to an exact coincidence of the frequencies of the microwave generator k and the resonant frequency of the working resonator 7, and no conversion occurs. The relative shift (drift) of the oscillator frequency k of the microwave and the working resonator 7 causes amplitude modulation with frequency f, the amplitude of which is proportional to the drift value, and the phase is determined by the drift sign. The signal at the frequency fdd is taken from the output of the microwave detector 6 and is fed to the signal input of the synchronous detector 9. The constant current output of the synchronous detector 9 is proportional to the frequency drift and is used to control and stabilize the frequency of the microwave generator at the control input (Fig. 2). When the frequency of the oscillator k of the microwave and the working resonator 7 is detuned (as a result of a sample change or for other reasons) by an amount exceeding the holding range of the NAPH circuit, failure of the NAPH occurs. However, due to the presence of the frequency control channel of the working resonator 7, the circuit does not lose information about the relative position of the frequencies of the microwave generator k and the working resonator 7 remembers the frequency detuning sign, generates a control signal, turns on element 13; adjusting the frequency of the working resonator 7 and returning (the frequency of the working resonator 7 to the frequency of the microwave generator, to the MAPC capture zone. The first 10 and second 11 two-threshold circuits connected to the output of the synchronous detector 9 allow the detuning sign to be remembered. As two-threshold circuits for example, comparators with hysteresis are used. The upper threshold voltage and the “dpi” two-way circuit 10 are set, as can be seen from Fig. 2, based on the maximum value of the MFH detuning signal, The output of the synchronous detector 9 determines the switching-on threshold of the channel for automatic tuning of the operating resonator frequency 7 at failure of the NAP. The channel is turned off by a lower threshold voltage, which has a small opposite sign to prevent false alarms.When the FVRE fails, the voltage at the output of the synchronous detector exceeds that time, the threshold Ul ,, which triggers the two-threshold circuit 10 and activates through Qxema 12 the control of the frequency resonator element 13 of the working resonator 7. The two-threshold EMA 10 remains in this position to reduce the voltage output from the synchronous detector 9 to a value UHK, i.e. c / zero crossing. The sign of the voltage at the output of the two-threshold circuit 10 is reversed, and using the control circuit 12 turns off the frequency control element 13 of the working resonator 7. The double-threshold circuit 11 operates similarly to the circuit 10 and differs in opposite polarity of the threshold voltages frequency tuning. The width of the hysteresis loop U of the two-threshold circuits is set from the value. Thus, when the frequency of the resonator 7 leaves the pick-up area of the IOL for any value, the radio spectrometer circuit produces a unique matching signal, provides constant tracking and automatic alignment of the frequencies of the microwave generator 4 and the working resonator 7 s frequency range, which allows, with an operating frequency of 100 MHz and an LAP capture bandwidth of about 2 MHz, a reduction in the spectrometer tuning time by a factor of 3-5. / Additional advantages of the proposed technical solution are realized when working with solid-state microwave generators (Gunn diodes, LPDs, etc.), in which, for the purpose of maintaining stability and high spectral purity of the microwave signal, the range of electronic tuning is often reasonable. be small (on the order of 10 MHz). The introduction of an additional channel for adjusting the frequency of the working resonator makes it possible to use the narrowband microwave path and thereby optimize the characteristics of individual resonant waste elements. The invention includes an electronic paramagnetic resonance radio spectrometer, comprising an electromagnet with a control unit, a microwave generator, the output of which is connected via a circulator to a microwave detector and a working resonator, an automatic frequency control channel for the microwave generator, including a modulation generator connected to the modulating input of the microwave generator and the reference input of the synchronous detector, the signal input of which is connected to the output of the microwave detector, and the output to the control input of the microwave generator, and a recording unit that differs In order to reduce the tuning time of the radio spectrometer, an additional channel of frequency tuning of the working resonator is introduced, made in the form of parallel first and second two-threshold circuits connected by outputs to serially connected control circuit and frequency tuning element of the working resonator, and the input of the additional channel of tuning the frequency of the working resonator is connected to the output of the synchronous detector, and the input of the registration unit is connected to the output of the microwave detector. Sources of information taken into account in the examination 1. Technical description and operating instructions for the EPR E-12 spectrometer by Varian, USA, 1976. 2. Technical description of the ESR ER-200tt radios. From Bruker, Germany 1978 (prototype).