SU958935A1 - Method of nuclear quadruple resonance spectrum search and registering - Google Patents

Description

(54) METHOD OF SEARCH AND REGISTRATION OF NUCLEAR QUADRUPOLE RESONANCE SPECTRA The invention relates to radio spectroscopy and can be used when searching and recording nuclear quadrupole resonance (NQR) spectra. It is known to use a pulsed technique for searching and recording NQR spectra, which consists of applying a radio-frequency field pulses to a test substance with a repetition period longer than the spin-lattice relaxation time Ti. To record the NQR frequency spectrum, the radio frequency field varies smoothly within certain limits for each core investigated. When this frequency coincides with the quadrupole resonance frequency, transient NQR signals (induction signals or spin echo signals) 1 arise. In this case, we collect moth accumulation, which increases the signal-to-noise ratio in proportion to the square root of the accumulations, which a sharp increase in the time of the experiment, since the repetition frequency of the spin echo signal is limited by the spin-lattice relaxation time. The closest technical solution to the present invention is a method for searching and recording NQR spectra, which consists in exciting and recording spin echo signals using a multipulse sequence consisting of a preparatory pulse and following it after time T of the main pulse sequence with a time of 2m between them each pulse of the main sequence is shifted in phase by 90 ° with respect to the preparatory pulse. The interval between the pulses 2 T in this case must be less than the spin-spin relaxation time T, the duration of the entire multipulse sequence is less than the spin-lattice relaxation time Tj. This sequence results in multiple unipolar spin echo signals in one repetition period and, therefore, significantly increases the number of signal accumulations per unit time 2. However, this method has the following disadvantages: the difficulty of obtaining the phase shift retaining the frequency at 90 °; the difficulty of avoiding zero-level drift with the accumulation of unipolar signals. The aim of the invention is to improve measurement accuracy by eliminating zero level drift during accumulation. The goal is achieved by the method of searching and recording NQR spectra consisting in exciting and recording spin echo signals using a multipulse sequence consisting of a preparatory pulse and following it through the time t of the main pulse sequence with a time 2E between them, set the phase impulses in this way, each impulse of a multipulse sequence has a phase shift of 180 ° in relation to the preceding impulse. Since the proposed sequence yields alternating phase spin echo signals, the difficulties associated with zero-level drift in signal accumulation disappear. FIG. 1 shows the multipulse sequence of the prototype method; in fig. 2 shows the multipulse sequence of the proposed technical solution. The proposed method is carried out as follows. The test sample is placed in an oscillating circuit coil, in which pulsed radio-frequency fields are excited with the help of a generator in the sequence shown in FIG. 2. This sequence is defined by a special block of programs built, for example, on the basis of digital techniques. Filling Frequency: Pulses are swept from

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Claims (2)

ft using a master oscillator in the entire frequency range under study. When the frequency of the exciting pulses coincides with the frequency of the quadrupole resonance, NQR signals appear, which are recorded after amplification and accumulation. The proposed method eliminates zero-level drift when accumulating an NQR signal, and also simplifies the search process for registering spectra due to using only 180 ° phase shifts. using a multipulse sequence consisting of a preparatory pulse and following it after the time T of the main sequence of pulses with a time 21 between not and characterized in that, in order to improve the measurement accuracy by eliminating zero-level drift during accumulation, each pulse of a multipulse sequence has a phase shift of 180 ° relative to the previous pulse. Sources of information taken into account during the examination 1. Grechishkin B. C. Nuclear quadrupole interactions in solids. M., “Science, 1973, p. sixteen. 2. R. A. Marino and S.M. Klainer. Metods and apparatus J. Chem Phys. V. 67, 1977, p. 3388 (prototype). . ig 42