RU2683018C1 - Method of mass analysis of ions in quadrupolar high-frequency fields with dipole excitation of oscillations on borders of stability - 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 microanalysis devices for a substance, using the properties of ion motion trajectories in electric fields. Method of mass analysis with resonant excitation of oscillations of ions is characterized in that the frequency of the exciting field is chosen equal to the frequency of one of the harmonics of the oscillations of ions at the boundaries of the Mathieu stability diagram, and the mass sweep is carried out by the time variation of the constant component of the quadrupole field with the constancy of the parameters of its high frequency component. Method allows to increase the resolution and sensitivity, to expand the range of the analyzed mass and to increase the speed of analysis of quadrupole mass spectrometers with resonant output of ions.EFFECT: resolution enhancement, improvement of high-frequency power supply systems, excitation and scanning of quadrupole mass analyzers with resonant ion output.1 cl

Description

The invention relates to the field of mass spectrometry and can be used to improve the analytical, operational and commercial characteristics of substances microanalysis devices using the properties of ion trajectories in high-frequency [HF] quadrupole electric fields when superimposed on them close to uniform exciting fields. The technical task of the invention is to improve the RF power supply system, excitation and sweep of quadrupole mass analyzers with resonant ion output. Known devices of this type are quadrupole linear ion traps with hyperbolic or cylindrical electrodes with mass-selective ion removal by dipole resonance excitation of ion vibrations at secular frequencies [1-3]. Resolution and mass range of devices of this type is limited to 10 ³ . The proposed method can significantly improve the analytical parameters, as well as improve the system of RF power and mass sweep of quadrupole mass spectrometers with resonant ion output.

, где r₀ - минимальное расстояние электродов от оси Z, L - длина анализатора по оси Z, ионы с начальными координатами х₀,у₀<<r₀,

суперпозицией электрических полей: квадрупольного, высокочастотного, сформированного под действием питающих напряжений u₁(t)=-u₂(t)=Vcos(Ωt+ϕ), где V, Ω, ϕ - амплитуда, частота и начальная фаза высокочастотных напряжений, приложенных к парам, расположенным по осям X и Y, гиперболических (или цилиндрических) электродов, и, близкого к однородному, возбуждающего поля, сформированного под действием возбуждающего напряжения u_в(t)=V_вcos(ω_вt+ϕ_в), где

, ω_в, ϕ_в - амплитуда, частота и начальная фаза напряжения, приложенного между парой электродов на оси Y, в процессе которого амплитуды колебаний ионов резонансно нарастают и они через щели в электродах вдоль оси Y выводятся из анализатора на регистрацию, отличающийся тем, что на высокочастотное квадрупольное поле путем добавления к питающим напряжениям u₁(t) и u₂(t) постоянных составляющих U и -U накладывается статическое квадрупольное поле, а частота возбуждающего поля выбирается из ряда ω_в=rΩ+ω_S, где r=0, ±1, ±2 …,

- секулярная частота со значениями параметра стабильности β=0 или β=1, соответствующими границам a ₀(q) или b₁(q) диаграммы стабильности Матье, причем развертка масс анализатора осуществляется изменением во времени постоянных составляющих U и -U питающих напряжений u₁(t) и u₂(t) при постоянстве амплитуды V их ВЧ составляющих.The method of mass analysis of ions in quadrupole high-frequency fields with dipole excitation of oscillations at the stability boundaries, which consists in influencing the quadrupole analyzer formed or introduced into the working area ⎪х⎪ <r ₀ , ⎪у⎪ <r ₀ ,

where r ₀ is the minimum distance of the electrodes from the Z axis, L is the length of the analyzer along the Z axis, ions with initial coordinates x ₀ , y ₀ << r ₀ ,

superposition of electric fields: quadrupole, high-frequency, formed under the action of supply voltages u ₁ (t) = - u ₂ (t) = Vcos (Ωt + ϕ), where V, Ω, ϕ - amplitude, frequency and initial phase of high-frequency voltages applied to pairs located along the X and Y axes, of hyperbolic (or cylindrical) electrodes, and close to a uniform, exciting field formed under the action of the exciting voltage u _in (t) = V _in cos (ω _in t + ϕ _in ), where

, ω _в, ϕ _в - amplitude, frequency and initial phase of the voltage applied between the pair of electrodes on the Y axis, during which the oscillation amplitudes of the ions resonantly increase and they are removed from the analyzer through the slots in the electrodes along the Y axis for registration, characterized in that a static quadrupole field is superimposed on the high-frequency quadrupole field by adding the constant components U and -U to the supply voltages u ₁ (t) and u ₂ (t), and the frequency of the exciting field is selected from the series ω _в = rΩ + ω _S , where r = 0 , ± 1, ± 2 ...,

- secular frequency with values of the stability parameter β = 0 or β = 1 corresponding to the boundaries a ₀ (q) or b ₁ (q) of the Mathieu stability diagram, and the analyzer mass scans are carried out by changing the constant components U and -U of the supply voltage u _{1 with time} (t) and u ₂ (t) with a constant amplitude V of their RF components.

In quadrupole mass analyzers with a potential distribution of the form:

where U is the constant component of the supply voltage, the movement of ions along the axes X and Y is described by the Mathieu equations [4]:

,

- параметр Матье, m, e - масса и заряд ионов.Where

,

- Mathieu parameter, m, e - mass and charge of ions.

The solutions of equations (2) are the sums of harmonic functions with frequencies:

секулярной составляющей колебаний ионов в зависимости от значения параметра стабильности 0≤β≤1, определяемого параметрами Матье a и q, лежит в пределах 0 - Ω/2. Значения β=0 и β=1 соответствуют границам a ₀(q) и b₁(q) диаграммы стабильности Матье [4]. В известных прототипах квадрупольных масс-анализаторов с резонансным выводом ионов используется режим питания без постоянной составляющей (U=0, параметр Матье а=0), а развертка масс осуществляется изменением во времени амплитуды V питающего ВЧ напряжения.Frequency

the secular component of ion vibrations, depending on the value of the stability parameter 0≤β≤1, determined by the Mathieu parameters a and q, lies in the range 0 - Ω / 2. The values β = 0 and β = 1 correspond to the boundaries a ₀ (q) and b ₁ (q) of the Mathieu stability diagram [4]. In well-known prototypes of quadrupole mass analyzers with resonant ion output, a power mode without a constant component is used (U = 0, Mathieu parameter a = 0), and the mass scan is carried out by changing the amplitude V of the supply RF voltage with time.

For the resonant extraction of ions on a quadrupole field, an exciting field is superimposed with a potential distribution along the Y axis that is close to linear:

The process of excitation of oscillations occurs when the frequencies of the exciting field are equal to one of the harmonics of ion vibrations ω _in = ω _r . In this case, the ratio of the spectral components in the excited oscillation does not depend on the number r of the excited harmonic.

, поэтому в прототипах для резонансного вывода используют возбуждение секулярных колебаний ионов и частоту возбуждающего поля выбирают равной частоте секулярных колебаний анализируемых ионов ω_в=ω_S. В этом случае разрешающая способность квадрупольных масс-анализаторов с резонансным выводом ионов возрастает пропорционально

, поэтому частоту возбуждающего поля желательно увеличивать [1]. Но росту разрешения препятствует наложение на секулярную составляющую высших гармоник колебаний ионов, в первую очередь соседней гармоники с частотой Ω - ω_S и амплитудой, пропорциональной ~ω_S. Поэтому частоту возбуждающего поля ограничивают величиной

.In solving equation (2) for the coordinate y, the component with the secular frequency has the largest amplitude

therefore, in the prototypes for the resonant conclusion use the excitation of secular oscillations of ions and the frequency of the exciting field is chosen equal to the secular frequency of the analyzed ions ω _in = ω _S. In this case, the resolution of quadrupole mass analyzers with resonant ion output increases proportionally

therefore, it is desirable to increase the frequency of the exciting field [1]. But the increase in resolution is hindered by the superposition of the higher harmonics of ion vibrations on the secular component, primarily the neighboring harmonics with a frequency Ω - ω _S and an amplitude proportional to ~ ω _S. Therefore, the frequency of the exciting field is limited to

.

:In the proposed method, voltages U (t) and -U (t), slowly changing during mass sweep, are added to the RF supply voltages, under the influence of which the parameter β changes, and at the moment of resonant excitation takes the value 0 or 1, corresponding to one of the boundaries a ₀ (q) or b ₁ (q) Mathieu stability diagrams. In this case, the frequency of the exciting field is a multiple of the frequency of the quadrupole rf field Ω or its half

:

- on the stability boundary a ₀ (q), where the stability parameter and secular frequency are respectively β = 0, ω _S = 0, the frequency of the exciting field is selected from the series 0, Ω, 2Ω., ...

, частота возбуждающего поля выбирается из ряда

,

,

, …- at the stability boundary b ₁ (q), where β = 1,

, the frequency of the exciting field is selected from

,

,

, ...

при β=1. Более перспективным для расширения аналитических возможностей и усовершенствования систем питания и развертки квадрупольных масс-анализаторов с резонансным выводом ионов является режим возбуждения колебаний ионов на границе стабильности а ₀(q) под действием постоянного однородного поля.The amplitudes of the harmonic components of the oscillation of the ions with increasing numbers r decreases rapidly, so effective for the excitation can be used only _{in the} frequency ω = 0, Ω at β = 0 and

for β = 1. More promising for expanding the analytical capabilities and improving the power supply and scanning systems for quadrupole mass analyzers with resonant ion extraction is the mode of excitation of ion vibrations at the stability boundary a ₀ (q) under the influence of a constant uniform field.

The mass scans of analyzers with resonant excitation of ion vibrations at the boundaries of the Mathieu diagram are performed by scanning the stability parameter from the initial value β ₀ to the final value β = 0 under the action of the time-varying DC components U (t) and -U (t) of the supply voltage. When the stability parameter of the ions of the analyzed mass reaches β = 0, the frequencies are equal ω _in = ω _S and a resonance occurs, during which the coordinate of oscillations increases unlimitedly and ions are removed from the analyzer through the slots in the electrodes for registration.

имеет ряд преимуществ:Excitation of ion vibrations at stability boundaries compared with the case

has several advantages:

- increases the rate of increase in the amplitude of the forced oscillations of ions, changing at the boundaries of stability in proportion to t ² ;

- the influence on the side vibrations of the excited harmonics is reduced, since their frequencies are multiples of the frequency of the exciting field ω _r = rω _in ;

- the influence of the scatter of the initial coordinates at ₀ and ion velocities υ _0y on the resolving power of the mass analyzer is reduced, since at the stability boundaries, the oscillation amplitudes due to the parameters at ₀ and υ _0y increase proportionally to t, and the amplitudes of the excited oscillations are proportional to t ² ;

- at the stability boundary a ₀ (q), the excited oscillations of the ions are unipolar in nature;

- the mass scan of the analyzer occurs by a slow change in the constant components at constant amplitudes and frequencies of the RF components of the supply voltage.

The listed properties of the mode of excitation of ion vibrations at the boundaries of the Mathieu stability diagram can increase the resolution, expand the mass range and improve the RF power system and the mass sweep of quadrupole mass spectrometers with resonant ion extraction and can be used to create more advanced microanalysis devices for substances of various applications

Literature

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

2. Collings B.A., Stott W.R., Londry F.A. Resonant excitation in low-pressure linear ion trap // J. Am. Soc. Mass Spectrom. 2003. Vol. 14. P. 522-534

3. S.M. Willams, K.W.M. Sin, F.A. Londry, V.I. Baranov Resonant excitation by linear ion trap simulations. J. Am. Soc. Mass spectrum. 2007 Vol. 18. P. 578

4. McLahlan H.B. Theory and applications of Mathieu functions. M .: Foreign literature. 1953.474.

Claims (1)

The method of mass analysis of ions in quadrupole high-frequency fields with dipole excitation of oscillations at the stability boundaries, which consists in influencing the created or introduced into the working area of the quadrupole analyzer | x | <r ₀ , | y | <r ₀ ,

where r ₀ is the minimum distance of the electrodes from the Z axis, L is the length of the analyzer along the Z axis, ions with initial coordinates x ₀ , y ₀ << r ₀ ,

superposition of electric fields: quadrupole, high-frequency, formed under the action of supply voltages u ₁ (t) = - u ₂ (t) = Vcos (Ωt + ϕ), where V, Ω, ϕ - amplitude, frequency and initial phase of high-frequency voltages applied to pairs located along the X and Y axes, hyperbolic (or cylindrical) electrodes and close to a uniform exciting field formed under the action of the exciting voltage u _in (t) = V _in cos (ω _in t + ϕ _in ), where

, ω _в , ϕ _в - amplitude, frequency and initial phase of the voltage applied between the pair of electrodes on the Y axis, during which the oscillation amplitudes of the ions resonantly increase and they are removed from the analyzer through the slots in the electrodes along the Y axis for registration, characterized in that a static quadrupole field is superimposed on the high-frequency quadrupole field by adding the constant components U and -U to the supply voltages u ₁ (t) and u ₂ (t), and the frequency of the exciting field is selected from the series ω _в = rΩ + ω _S , where r = 0 , ± 1, ± 2 ...,

- secular frequency with values of the stability parameter β = 0 or β = 1 corresponding to the boundaries a ₀ (q) or b ₁ (q) of the Mathieu stability diagram, moreover, the mass analyzer is scanned by changing the constant components U and -U of the supply voltage u ₁ (t) and u ₂ (t) with a constant amplitude V of their RF components.