RU2749549C1 - Device for mass analysis of ions with quadrupole fields with excitation of oscillations at stability boundary - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to the field of mass spectrometry and can be used to improve the analytical, operational and commercial characteristics of devices for microanalysis of matter, using the movement of ions in quadrupole high-frequency electric fields. The device contains an ion-optical system of planar electrodes with discrete-linear distributions on them of superpositions of RF quadrupole and quasi-static and homogeneous static potentials. In the process of sweeping the masses, by a change in the constant component of the quadrupole field under the action of a uniform static field, excitation occurs at the stability boundary of unipolar oscillations of ions. In this case, the ions are taken from the analyzer for registration one by one, in decreasing order of their mass.EFFECT: increasing the resolution and sensitivity of quadrupole mass analyzers.1 cl, 1 dwg

Description

The invention relates to the field of mass spectrometry and can be used to improve the analytical, operational and commercial characteristics of devices for microanalysis of matter, using the movement of ions in quadrupole high-frequency high-frequency electric fields. The technical problem of the invention is to improve the design of the ion-optical system (IOS) of quadrupole mass analyzers with the excitation of ion oscillations and to increase their resolution and sensitivity. Known devices of this type are linear ion traps with either quadrupole analyzers [1], or with planar discrete electrodes [2, 3] with dipole excitation of ion oscillations. Their analytical capabilities are limited by the complex structure of the excitation function and the low rate of its increase in the process of excitation of oscillations [4].

The proposed device, implemented using IOS with planar discrete electrodes in the half-space у≥0, allows you to improve the analytical, design and operational parameters of mass spectrometers of this class.

In well-known quadrupole mass analyzers with resonant excitation of oscillations of ions, IOS consist of 4 hyperbolic [1] or 2 planar discrete [2] electrodes. They form a quadrupole RF superposition of harmonic and homogeneous electric fields in the bipolar working area _and y _and in plane ≤u≤u X0Y, _and where - the amount of IER in the excitation axis Y. To excite oscillations in these cases, a homogeneous harmonic field and ions in the process of mass analysis, bipolar oscillations are performed in the working area of the analyzer [1, 2].

In the proposed device, resonant excitation of ion oscillations in quadrupole high-frequency fields occurs under the action of a superposition of quasi-static quadrupole and static homogeneous fields, while oscillations along the excitation axis Y are unipolar y (t)> 0 [5]. Therefore, the working area of the analyzer along the Y-axis can also be monopolar.

The proposed device for mass analysis of ions, containing an ion-optical system for the formation in the X0Y plane of a superposition of quadrupole and uniform electric fields and excitation of resonant oscillations in them differs in that its IOS with dimensions 2x _a , y _a and 2z _a along the X, Y axes , Z is monopolar, located in the half-space у≥0 and consists of 2 in the planes х = ± х _а , with dimensions у _а >> х _а , 2z _a >> х _а along the axes Y, Z, discrete with a step Δу _а << у _а along the Y-axis of electrodes (I) and (II) with discrete-linear along the Y-axis distributions of HF, quasi-static and static potentials u _{(I) i} = ΔU _y (t) i + ΔV _y icosωt + ΔU _in i, u _{(II) i} = -ΔU _y (t) i-ΔV _y icosωt + ΔU _in i, where i = 1, 2, 3, ..., n is the number of discrete electrode elements, n = y _a / Δy, ΔU _y ( t) = U (t) / n, U (t) = Ut / T is the quasi-static (slowly changing during the sweep of the masses) potential, T is the duration of the sweep of the masses, ΔU _in = U _in / n, U _in is the potential of the uniform exciting field , one in the plane y = 0, with dimensions 2x _a , 2z _a along the X, Y axes, grounded e electrode (IV), and one in the plane y = y _a with dimensions 2x _a , 2z _a along the X and Z axes, discrete with a step Δx << x _a along the X axis of the electrode (III) with a superposition of discrete linear distributions of high-frequency and quasi-static potentials and static exciting potential u _{(III) j} = ΔU _x (t) j + ΔV _x jcosωt + ΔU _в , where j = -m, ..., - 2, - 1, 0, 1, 2, ..., m is the number discrete electrode element, m = x _a / Δx, ΔU _x (t) = U (t) / m, ΔV _x = V / m. To remove ions from the analyzer for registration, the electrode (III) is made semitransparent.

The ITS diagram of the proposed device is shown in Fig. 1. The ion-optical system in the X0Y plane is closed, therefore, the accuracy of the distribution of the superposition of electric fields in it depends only on the discreteness step of the electrodes I, II, III. When optimizing the modes of resonant excitation of ions, the dimensions of the working area of the analyzer x _a and y _a , and their ratios, can be selected within wide limits.

The analyzer is powered by an RF voltage with constant parameters V and ω, which ensures their high installation accuracy and stability. The monopolar IOS scheme excites ion oscillations in one direction of the Y axis, which doubles the analyzer sensitivity.

Thus, the proposed solution makes it possible to improve the design of the IOS of mass analyzers with resonant excitation of ions, to optimize its parameters, to increase the analytical and operational characteristics of mass spectrometers of this type, and also to increase the efficiency of their RF power supply and sweep systems.

Literature

1. D.J. Douglas, N.V. Konenkov. Mass selectivity of dipolar resonant excitation in a linear quadrupole ion trap // Rapid Communications in Mass Spectrometry. 2014, V. 28, p. 430-438.

2. E.V. Mamontov. Method for mass analysis with resonant excitation of ions and a device for its implementation. Invention patent RU 2634614, 02/11/2017. Application No. 2016149722 dated 16.12.2016.

3. E.V. Mamontov. A method for generating a two-dimensional linear high-frequency electric field and a device for its implementation. RF patent No. 2497226, 2012

4. Mamontov E.V., Sudakov M.Yu., Dyatlov R.N. Free and forced oscillations of charged particles in inertial-nonstationary rapidly oscillating quadrupole electric fields. Radio engineering and electronics. 2020, volume 65, no. 2, p. 197-202.

5. E.V. Mamontov. Method for mass analysis of ions in quadrupole fields with excitation of oscillations to the stability boundaries. Patent Pending, 2020

Claims (1)

A device for ion mass analysis, containing an ion-optical system for the formation in the X0Y plane of superpositions of quadrupole and uniform electric fields and excitation of resonant oscillations in them, differs in that its monopolar ion-optical system with dimensions 2x _a , y _a and z _a along the axes X, Y and Z is located in the half-space у≥0 and consists of two in the planes х = ± х _а , with dimensions у _а >> х _а , 2z _a >> х _а along the axes Y, Z, discrete with a step Δу _а << у _а along the Y-axis, electrodes (I) and (II) with discrete-linear along the Y-axis distributions of high-frequency, quasi-static and static potentials u _{(I) i} = ΔU _y (t) i + ΔV _y icosωt + ΔU _in i , u _{(II) i} = -ΔU _y (t) i-ΔV _y icosωt + ΔU _in i, where i = 1, 2, 3, ..., n is the number of the discrete electrode element, n = у _а / Δу, ΔU _y (t) = U (t) / n, U (t) = Ut / T is the quasi-static (slowly changing during the sweep of the masses) potential, T is the duration of the sweep of the masses, ΔU _in = U _in / n, U _in is the potential of the exciting homogeneous field, one in the plane y = 0, with dimensions 2x _a , 2z _a along the axis pits X, Z, a grounded electrode (IV), and one in the plane y = y _a , with dimensions 2x _a , 2z _a along the X, Z axes, discrete with a step Δx << x _a along the X axis, electrode (III) with superposition of discrete-linear distributions of high-frequency and quasi-static potentials and static exciting potential u _{(III) j} = ΔU _x (t) j + ΔV _x jcosωt + ΔU _в , where j = -m, ..., - 2, - 1, 0, 1 , 2, ..., m is the number of the discrete element of the electrode, m = х _а / Δх, ΔU _x (t) = U (t) / m, ΔV _x = V / m, and for the withdrawal of ions from the analyzer for registration the electrode (III ) is translucent.

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