RU192005U1 - DEVICE FOR RESEARCH BY METHODS OF GAS ELECTRONOGRAPHY AND SPECTROSCOPY OF NUCLEAR MAGNETIC RESONANCE COMPONENTS OF SUBSTANCE, SEPARATED BY A GAS CHROMATOGRAPH - Google Patents

Abstract

The utility model relates to the field of research and analysis of materials. A device is proposed for electron diffraction studies of molecules in the gas phase, in which the blocks of a gas chromatograph, molecular separator, gas electron diffractometer, ion source and nuclear magnetic resonance spectrometer are connected in series, each of these blocks being connected to a computer that controls the operation using a common computer program each block. The technical result achieved is to increase the accuracy and reliability of all parameters of free molecules of a substance determined by gas electron diffraction (that is, data on the spatial configuration of free molecules, internuclear distances in each molecule, the value of valence angles and amplitude of atomic vibrations in the analyte molecule).

Description

The proposed utility model relates to the field of research and analysis of materials, namely, to a device for determining the structure of a free molecule by gas electron diffraction methods (its spatial configuration, internuclear distances, valence angles, vibration amplitudes) and nuclear magnetic resonance spectroscopy (elemental analysis, the presence of certain groups of atoms , their number, composition and type of bond) for pure substances obtained by separation of the analyzed material by gas chromatography.

The prior art device is known combining gas chromatography (GC) and gas electron diffraction (GE) [Ewbank J.D. et al. Real-time data acquisition for gas electron diffraction / Review Scientific Instruments, 1984, V. 55, N. 10, pp. 1598-1603; Ewbank J.D. et. al. Improvements in real-time data acquisition for gas electron diffraction / Review Scientific Instruments, 1986, V. 57, N. 5, pp. 967-972].

The disadvantages of such a device include the impossibility of obtaining nuclear magnetic resonance (NMR) spectra of the samples under study, which are especially important for studying the structures of polyatomic organic molecules, since the distance between the hydrogen nuclei in a molecule is practically impossible to determine by the GE method [L. Vilkov, Mastryukov BC, Sadova N.I. Determination of the geometric structure of free molecules. - L .: Chemistry, 1978.- 224 p., P. 32], and NMR just gives information related to this. The nuclei of hydrogen atoms (protons) give characteristic resonance NMR peaks, the area of which is directly proportional to their number, and the chemical shift of this signal helps to determine the elemental and structural composition of the groups included in the molecule. [Vilkov L.V., Pentin Yu.A. Physical research methods in chemistry. Resonance and electro-optical methods. - M .: Higher school, 1989. - 288 p., Bookends].

On the other hand, the data obtained by the HE method in combination with the preliminary separation of the analyzed gas by the GC method provide important information for the NMR method on the spatial structure of the free molecule, the presence and number of certain groups of atoms in it, and the bond lengths allow one to determine the type of bond triple). This helps the interpretation of the NMR spectrum, which uses the pulse technique with the Fourier transform. Taking into account the results of the HE method makes the results of the NMR method more reliable and reasonable, that is, these methods are mutually complementary.

The results of NMR analysis are especially important for GE in determining the spatial configuration of a polyatomic molecule, when the close internuclear distances fall at one peak on the radial distribution curve, and the internuclear distances (between hydrogen atoms) are generally absent on the radial distribution curve. In this case, the information obtained from the NMR method significantly helps to decrypt the electron diffraction pattern, the results of which are basic for the device proposed in this utility model.

The NMR version of a pulsed Fourier spectrometer with the introduction of ions instead of neutral molecules is equivalent to using a mass spectrometer with the highest resolution in modern mass spectrometry. In the literature [Lebedev A.T. Mass spectrometer in organic chemistry. - M .: BINOM. Laboratory of Knowledge, 2003. - 493 p., P. 129] such an instrument is called a Fourier transform ion cyclotron resonance mass spectrometer (MS-ICRFP), although it is more correctly called an Fourier transform NMR spectrometer, but analyzing ions.

The technical result of the proposed utility model is to increase the accuracy and reliability of all parameters of free molecules of a substance determined by the GE method (that is, data on the spatial configuration of free molecules, internuclear distances in each molecule, the value of valence angles and atomic vibration amplitudes in the analyte molecule).

The specified technical result is achieved by a device for electron diffraction analysis of molecules in the gas phase, which includes serially connected blocks of a gas chromatograph, molecular separator, gas electron diffractometer, ion source and nuclear magnetic resonance spectrometer, while each of these blocks is connected to a computer, which using a common computer program controls the operation of each unit.

A block diagram of the proposed device is shown in FIG. one.

The test sample 1, together with the carrier gas 2, enters the gas chromatograph (GC) 3, where the test sample is separated into the components of which it can consist (impurities, isomers, conformers, rotamers, unstable molecules). Helium should be used as a carrier gas, which does not contribute to the electron diffraction pattern and does not react with the components of the sample. From the gas chromatograph 3, the gas enters the molecular separator 4, which separates most of the helium from the sample. The separated components of the sample gas enter the gas electron diffraction system 5 injection system and then into the gas electron diffraction chamber 51, where they interact with the electron beam and the result is recorded by the gas electron diffraction detector 52. The analyzed gas exits the nozzle of the gas electron diffraction system 5 with a diameter of about 0.2 mm at a pressure of the order of 1 ÷ 0.1 mm Hg, which is controlled by the valve of the inlet system of the gas electronograph 5. Next, the gas enters the ion source 6, where it is ionized by one of the ionization methods, into applicability of the sample, goals and effectiveness of subsequent NMR analysis. “Soft” methods of ionization (electrospray, chemical, field, etc.) allow you to avoid fragmentation of molecules and obtain molecular ions, and “hard” methods (electron ionization) give fragmentation of molecules, which can help determine the structure of the molecule. The pressure in the ion source (of the order of 10 ^-5 mm Hg) can be controlled by a valve in the inlet system of the gas electronograph 5 and a valve at the entrance to the block of the ion source 6. Ions from block 6 are sent by an electrostatic lens system to the NMR analyzer 7, which is installed in a strong uniform magnetic field and is equipped with exciting and detecting electrodes. All blocks are connected to a computer 8, which controls the operation of each block, and then processes the results according to a common computer program. To ensure a working vacuum in all blocks, they are tightly interconnected (excluding a computer) through vacuum gaskets, have a common pumping system with forevacuum and high vacuum pumps, a piping system with valves, which allows to obtain the necessary pressure in each block and measure it with the required accuracy.

Claims (1)

A device for electron-electron research of molecules in the gas phase, including serially connected units of a gas chromatograph, molecular separator, gas electron diffractometer, ion source and nuclear magnetic resonance spectrometer, each of these units being connected to a computer that controls the operation of each unit using a common computer program .

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