DE1448192A1 - mass spectrometry - Google Patents

Description

Dr.-lng. Remove SomnerMcf Dr. Dieter r. Bmzoki

Munich 23, DunmOsk. 6 2493-ei / Dr. ν. B. / Fr. 1 4 4 8 1 S 2

Dr. Expl.

Max-Planck-Qesellechaft for the Promotion of Science eV

represented by Max Planck Institute for Physics and Astrophysics, Munich 23, Föhringer Hing β

and Institute for Plasmaphysics GmbH, Garehing

MASS SPECTROMETRY

The invention relates to a dynamically operating mass spectrometer and in particular a mass spectrometer in which the ions perform at least approximately periodic movements.

What all dynamically working mass spectrometers have in common is that the types of ions are separated due to differences in transit time. In mass spectrometer !! » in which the ions move out in a recurring motion, a field is present that corresponds to that of the maasenabhangiger The speed of the ions (which should be charged with multiple charges here apart) on stable orbits on which the ions * then the perform repetitive movement. The field can, depending on the principle, on which the mass spectrometer works, electrical or magnetic Be nature.

BATH ORIGINAL

809802/0783

The selection of a certain type of ion, ie the separation of ions of a certain mass, takes place through a periodic change of a suitable spectrometer parameter. Ions of a certain mass move with a phase that is synchronous with the parameter change and are thereby preferred over the other ions, dij & not, move synchronously with the parameter change, so that they can provide an output signal. You synchronously sick, moving selected ions are referred to hereinafter kun as "resonance ion ¹ *, although the rejection does not necessarily indicate Eesonanaeffekten in the true sense to berußen braucM; it can s B, also an accumulation held a lonenscrte" If bekaaaten mass spectrometer. are beispieiisweise nmr loaan a bestimisien mass by an applied WmnkmlajManxuag beecfeleunigi, WTKR * nd the l & smn. of other mass n no "* anen * wwrfrt Ea ^ rgifc aijfsBskmsn b * i eümm. other. MasscnspeMroxsstertyp be Naite with the Ss & wingung ^ freqisens a beMimmten lonenasortts dat «da» Akimiaidierussf ψ & η 1 © ü »e of this sort» »iatsltt.

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80IS02 / 0783

Spectrometer can be improved considerably.

The object of the invention is to improve the operating properties of dynamic mass spectrometers in which the ions have repetitive movements perform, to be improved by the fact that the space charges formed from the ions that are not in resonance are continuously removed, without any significant influence on the resonant ions to be detected (resonance ions). According to a further training According to the invention, the resonance ions are additionally subjected to phase focusing.

A method for operating a dynamically operating mass spectrometer, in which the ions execute a reciprocating movement on stable paths determined by a field, with ions of a certain Mass through a periodic change of a parameter of the synchronized with the repetitive movement of these ions Mass spectrometer are sorted out and brought for evidence, is characterized according to the invention in that in the spectrometer an additional field periodically distorting the field which determines the trajectories is generated in a subspace of the spectrometer at a point in which the resonance ions are outside this range, so that the ions that are not in resonance escape from the stable orbits and can discharge.

The invention will now be explained in more detail with reference to the drawing in conjunction with exemplary embodiments, where:

-4 «

BATH ORIGINAL 809802/0783

1 shows a schematic representation of the electrode system an electrostatic field mass spectrometer;

Fig. 2 is a diagram of the potential distribution of the spectrometer tube according to Fig. 1;

Figures 3 and 4 are graphs and operating voltages for the tube of Figure 1;

FIG. 5 shows a part of an electrode system compared to FIG. 1 slightly modified mass spectrometer tube;

Fig. 6 shows an improved collector arrangement for the mass spectrometer according to Fig. 1 or 5 and

7 shows a circuit arrangement which allows a mass spectrometer to operate the type described in the manner according to the invention.

Fig. 1 shows schematically an electrode system of a substantially known mass spectrometer tube (e.g. Zs. ang. Phys. 11, 1959, 395-399). The electrode system consists of a cathode 1, a Wehnelt cylinder 2, an anode 3, field electrodes 4 and a catch 5. The electrodes are biased in such a way that the potential curve drawn below in the same length scale in FIG. 2 is within the drill results. The electrons emerging from the cathode 1 are accelerated to the normally lattice-shaped anode 3, pass through it and are biased negatively with respect to the anode Field electrodes 4 reflected, so that they perform many pendulum movements in the area of the anode 3, during which they perform the in this area

■ -5-

809802/0783

can ionize existing gas molecules. Here and in the following, the terms "positive" and "negative ^{11" should} only be understood relatively; normally, when such a tube is in operation, the anode 3 and the collector S are approximately at ground potential, while the potential mini mum β of the potential well generated by the field electrodes 4 is at a high negative potential with respect to ground.

The ions formed in the area of the anode 3 are converted into the Potential troughs formed by biasing the field electrodes 4, which in the ideal case should have an approximately parabolic course, are sucked in and perform vibrations there, the frequency of which depends on their mass. Ions of a certain mass can thereby be preferred (selected) because with the oscillation frequency of these ions there are always new ions are supplied in the correct phase. This can be done by having one the Wehnelt cylinder 2 with a corresponding periodic flparonmg modulated. By summation, a large charge cloud can be formed from this type of ion, which at the influence collector S "in Signal But the background of all other ions that have a · different phase resulted in. It can be seen that there are tubes of this kind in this a considerable tree load that interferes with the function.

This stiff never Baumladmng is made according to the invention There is a need for an electrode to move with the desired electrode

Ions synchronized defocusing delay counters the orbits

■ ■ '"*" ■ ί

- ■ k

- BAD OR! GJN _AL

809802/0783

of the ions that are not in resonance are defocused, so d & A they do not ions in resonance on electrodes or those not shown Strike the Kolhenwand of the tube and be discharged. Hardly any different Way to be done:

According to a first operating method according to the invention, the ions are generated continuously in a manner known per se; the selection of the resonance ions is now carried out by. Apply a suitable frequency to the anode so that ds # potential d <* s in the prevailing electrostatic field in the bareick of the anode fluctuates approximately between the limits shown in broken lines in FIG. This measure has the effect that all ions that are generated in the positive of the modulation voltage of the anode are not

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-T-

809802/0783

This measure increases the amplitude of the resonance lines and the half width is reduced.

The measure specified above can be combined with the known measure of periodic generation of ions. At a Such a double control is the generation of the ions in a known manner periodically limited by sine modulation of the electron beam at the Wehnelt cylinder and the anode is according to the invention with the same Phase how the Wehnelt cylinder modulates. This gives you a time constricted ion supply and at the same time an elimination of undesired space charges due to the changes in potential at the anode. The simultaneous Modulation of the anode and Wehnelt cylinder can be achieved by isolating the anode from ground in terms of high frequency. The anode then receives its alternating voltage through capacitive coupling from the Wehnelt cylinder. Because of the time constant of the coupling in the antiphase, disruptive coupling via the electron beam is the However, the phase of the alternating voltage developing at the anode is undesirable slightly shifted compared to the exciting alternating voltage on the Wehnelt cylinder. Despite the not ideal conditions occurs but here, too, a noticeable improvement.

The resolving power of the spectrometer can thereby Improve even further that the ion generation can be continued over time constricts. For this purpose, the voltage on the Wehnelt cylinder is pulsed modulated, the most useful is simply modulation used sinusoidal voltage before feeding to the Wehnelt cylinder

BAD ORIGINAL _ ₈ .

809802/0783

tears, so that the curve shown in Fig. 3 results. Electrons are injected when the voltage in Fig. 3 is above the abscissa. The additional time limit of the Ion generation affects practically only the ions that are not in resonance, so that the sensitivity of the spectrometer through this measure is not noticeably impaired.

While the known mass spectrometer tubes of the described Type only work satisfactorily in a pressure range between 10 and 10 Torr, it has become possible through the specified measures,

-4 -11

to measure in the range between about 5 χ 10 and 5 χ 10 Torr.

In addition to removing unwanted ions, the high frequency voltage at the anode also causes phase focusing the kesonansionen, if one considers the potential distribution in the tube suitable chooses. In order to achieve phase focusing, however, it must be ensured that the restoring force acting on the ions is weaker grows linearly with the deflection, d. h »the oscillation frequency of the Ions must be amplitude dependent. Vibrations with greater amplitude should therefore last longer than oscillations with a smaller amplitude, i. H. the ions should represent a sub-linear oscillator in the electric field. A phase focusing then occurs in that the Resonance ions arriving too early at the anode modulated with the AC voltage from the still increasing potential with energy absorption

-9-

809802/0783

are lifted, so that they continue with the next half-wave begin to swing and arrive a little later in the next period. Ions, those arriving too late are slowed down by the already falling potential and give off energy, so that it is now faster with a smaller amplitude swing and arrive earlier in the next period. The demand since the restoring forces grow weaker than linearly with the deflection, must only be fulfilled in part of the tube area; preferably the restoring force becomes symmetrical in the area of the oscillation reversal points designed to be sub-linear to the potential flow. Need these conditions also only be fulfilled in the areas in which the resonance ions are are currently located.

The phase focusing of the resonance anions to increase the sensitivity and resolving power of the spectrometer system can be further enhanced by wobbling the shape and / or phase position (based on the voltage at the Wehnelt cylinder) of the high-frequency voltage supplied to the anode. When the shape is wobbled, the rising v ⁿ <l · *] - n-ma, i the falling edge of the positive half-wave of the anode alternating voltage is controlled once. Distortion, phase deviation and phase relationship are selected in connection with the wobble frequency in such a way that the focusing outweighs the defocusing that occurs in a different phase position of the wobble

Fig. 4 shows the case where the sick siiixjfftrmig * Modmlatie ** - Voltage at the anode in the cycle of the wobble frequency both phases · » is modulated as well as distorted. If the phase deviation is zero, the gpai is undistorted, that is to say symmetrical «in the case of the iron Gremz value I of the stroke is the rising edge, with the other »limit value the falling edge

-10 ·

BATH ORIGINAL 809802/0783

Flank of the Sinsu half-wave taxed. The amplitude and the near Surrounding the maximum voltage should not be used in the case of distortion be changed.

To achieve a coupling between the Wehnelt cylinder and anode, if possible To keep it small, a high-frequency protective grille is usually connected between these electrodes.

For effective Fhasenfokussierung the Bedingoiig muli one under linear vibrator in riamlichen and iHliehen field of ion formation symmetrically JTW jfchwingangsraum hj ~ ητψΑ <? * T be met Ht ^m. In order to learn this as well as possible, it is expedient to supply the hitch frequency to a separate electrode within the sensor , as FIG. 5 shows, for example. The anode of this S * »Ipektrometersystems consists ans of the electrode 3a to id" the electrode Sb is AAF eiaem about "Bisdrigeren jp" aitiren potential than the Stektzwiea Ul iodo Ie. "4 * high frequency modulation output is 9lmr inside the roughly tubular shape of the electrode Sb, preferably about electrified" 3d. The electrodes 3a are completely grounded. The UmterLbttaritlt mnM xsr while "M £ dea Ei ** chuss" s be guaranteed, because Sieb, aar daa & in the anedtal area M

beiiaden. A corresponding bath of the Feldrerlauf is avch in the bath Auffingers generated, so that at the local university pact Ittiae Defok "ni" r "ag Loading comb.

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■ - BATHROOM

809802/0783

To operate the mass spectrometer tube shown in FIG. 1 or 6, an alternating voltage is required, the frequency of which changes monotonically from about 0.17 to 1.70 MHz, the mass range between about 2 and 200 being swept over. The output signals of the mass spectrometer tube must be amplified in a highly sensitive measuring amplifier. To improve the signal-to-noise ratio, it is advisable to use a heterodyne receiver, since in this case the ions that oscillate at the wrong frequency are not measured. The mirror frequencies could be switched off by a selective, synchronously running high-frequency pre-stage, but this effort will generally not be worthwhile. For phase focusing by means of phase modulation, noc ' - * xie voltage of the same frequency is also required, the phase position of which can be shifted by -45 with respect to the reference voltage.

The circuit arrangement shown in FIG. 7 fulfills these conditions. It contains a variable oscillator 1, the frequency of which is variable between 8, 3 and 9.83 MHz and is preferably swept to the rhythm of the mains frequency. The output voltage of the oscillator 1 is amplified in an amplifier 2 and mixed in a mixer * stage 3 with a fixed frequency of 10 MHz from an oscillator 4. The output signal of the mixer stage is fed to a low-pass filter 6, whose output gklemne a sinusoidal voltage of frequency from 0.17 to 1, 70 MHz is available, through an amplifier

BATH ORIGINAL ~ ¹² ~

809802/0783

6 and, if necessary, an adjustable distortion level 7, which corresponds to the in Fig. 3 generated curve shape, the Wehnelt cylinder 2 (Fig. 5) is fed.

A voltage is required for the anode 3 or 3 ', its phase shift is frequency-independent compared to the Wehnelt voltage. This tension is generated in a separate mixing pin 11, the is fed on the one hand by the variable oscillator 1 and on the other hand from the fixed oscillator 4 via a phase rotator 8, so the Fixed frequency shifts in phase. The phase rotator 8 can be adjusted by a manually adjustable device 10 and, on the other hand, by a stage 9 can be swept »behind one at the output of the mixer stage 11 connected filter, a wave coherent to the Wehnelt voltage is available, the phase position of which is static and independent of frequency can be changed dynamically. This voltage is via an amplifier 13 and an adjustable distortion stage 14 of the anode 3 or 3d fed.

At the output electrode (collector or multiplier) of the spectrometer system occurs, among other things, a small voltage of the frequency of the modulation voltages. To create a constant intermediate frequency one could mix the output voltage again with the frequency of the oscillator 1 to get an intermediate frequency of 10 MHz. the In this case selection would be relatively bad, so a second

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80S802 / 078 3

—Ίο—

Mixing to a second intermediate frequency would be required.

This can be avoided by mixing the output voltage of the spectrometer tube with a frequency that is a relatively small, constant distance from her. For this purpose, the in an amplifier ^ Increased output voltage of the oscillator 1 in a mixer 16 mixed with the output voltage of an oscillator 17 «its frequency is slightly above or below the frequency of the oscillator 4, in the present case this frequency is 10.1 MHz. The output voltage the mixer 16 is a filter 18 and an amplifier 19 one Mixer 20 is supplied, which is also supplied with the output signal of the mass spectrometer tube. Since the two of the mixer stage 20 supplied signals have a constant distance of 100 kHz here, the constant intermediate frequency of 100 kHz is obtained at its output, which is amplified in an amplifier 21, rectified in a demodulator 22 and then applied to the measuring plates of an oscilloscope 23, whose timing voltage also controls the variable oscillator 1 · Thereby the synchronization is given from the start.

The frequency modulation in the oscillator 1 is preferably carried out with Capacitance diodes. If you put the frequency of the oscillator 1 below that of the Fixed oscillator 4, it results in connection with the properties of the varactor diodes that the area of high frequencies is in d * m the mass distance is relatively large, is compressed and the area of lower frequencies is stretched. Dadurhh becomes the screen of

• 14-

809802/0783

Oscillographs better used.

A frequency mark generator is useful for marking frequencies. The voltage of an adjustable,! ^ EicMan oscillator 24 is with the fed to the Wehnelt cylinder or at the frequency fed to the anode to a stage 25 which, if the frequency is the same, delivers a pulse, which is used for beam modulation of the oscilloscope.

The equations required for the operation of the electrometer tube * Voltage potentials are supplied by a power supply unit 26.

Except as described above. Modulation of Anedengpannung to the unwanted Bsuimladunjgen also follows Weis be "removed: At the time when the Besonanzieaen at the turning point of its orbit * preferably located within the Aufflüsgers, a rom Interceptor remote electrode is a preferably ESgativer, more intense, short Most of the flank impulse trains move because the trajectories of the ions are so strongly distorted that the FeM holding the ions are so strongly distorted that those in the area of this are so strongly distorted. Impals learned to escape their stable trajectories and attach themselves to electrodes, or the “ijH“ nzios ”n“ lad dian. EinfltiS ύ% χ through inn

Field through the shielding effect of the Asffiaf * ra wad. any diaphragm elements. "Maintain, if another Iemem under dmm Sinflul d <s & Feldes ia iksrmr Mchtuag defoke * s

L. -IB «

809802/0783

With the known mass spectrometer !! of the described The ions can be detected either by means of an influence collector or by means of a secondary electron multiplier. It has been shown that both detection methods are in need of improvement, especially if the removal of the space charges in the manner described increases the Strong resonance occurs.

In the influenza catcher, charges are influenced by the oscillating charges in the area of one turning point of their orbit, which form the signal for the ions in resonance. The influenza catcher 5 in Fig. 1 is the known one. Tube on one fixed potential, so that only ions of a very narrow energy range give a maximum of influence. Ions richer in energy hit the interceptor and are discharged, lower energy ions cannot approach the interceptor far enough and surrender a low influenza effect. These disadvantages are avoided by the new influenza catcher shown schematically in FIG. which consists of a system of diaphragms, preferably concentric funnels, which open towards the ion beam and which are equal to different, preferably adjustable, potentials. In terms of alternating current, the individual electrodes are connected to one another connected and connected to the input of an amplifier. The electrode 7d furthest away from the entry side of the ions is located

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809802/0783

on the highest electrode, the one closest to the entry side 7a at the lowest positive potential * The equipotential surfaces generated by the preferred funnel system are shown in dashed lines. Depending on their energy, the ions penetrate deeply into the collector system and can reach a maximum To exert an influence without being discharged. Because of the funnel shape The electrodes are also directionally focused reflected ions. The catcher can be combined with a multiplier at the same time. Namely, it is desirable between to be able to change both detection systems or both at the same time available, as in areas of higher pressures in general a catcher is more appropriate and flashovers or non-linearities can easily occur in the multiplier, while lower in the range Pressing a multiplier is preferable. For this purpose, the opening of the rearmost electrode 7d is spanned with a mesh 8 and Behind the collecting system there is a multiplier entry electrode which is at a relatively high negative potential during operation ö, which is constructed like a blind, arranged. This electrode can any known multiplier arrangement with dynodes 10 and an anode 11 are then connected. Ions of sufficient energy can through the Pass through grid 8, are accelerated to the shutter electrode 9, there trigger electrons in a known manner, which are multiplied at the dynodes and can be detected at the anode.

-17-809802 / 0783

With the known mass spectrometer systems of the observer Type, a multiplier operation is very difficult, as easy the potential curve shown in Fig. 2 can be seen. The ions are generated approximately in the area 12 between the dashed lines, the entry electrode of the multiplier may be approximately at the potential 13. Either the ions are now generated at potentials that are lower than the multiplier potential, so that they cannot reach the multiplier without the application of energy, or they become at potentials generated, dl are comparable to or higher than the multiplier potential, then they get into the multiplier after only half a cycle. However, there are many oscillations for a sufficient selection of the ions necessary. An energy supply to the ions is in itself through a subsequent acceleration through a high-frequency field is possible. this but again has the disadvantage that the ions »al · avf earn highest potential, compared to the lowest * PoteatLal generated ions vi ·! less vibrations · * köaae *. Since the entry potential of the multiplier is also about equal to the highest · »potential on the since · the source of Ieman ·» «ia must ,, becomes about A * Half of the potential maximum on the salt of the Iaaeaquelle I) Mrechreiten mad ia the electron source removed. They don't go only lose », but» also atomize the »filament ia aserwt * sakt« r Catfish·.

-If-

BAO ORIGINAL

809302/0783

These disadvantages can be avoided by doing so a. symmetrical, approximately parabolic potential generated that on the side opposite to the multiplier via the eletrittpotential of the multiplier reaches out. The ions then become acquaintances in and of themselves Way through electron injection, ao transverse to the tube axis and field direction generated, but according to the invention at a potential da * lower is than the entry potential of the multiplier. The ions formed in this way are supplied with energy in a manner known per se by a high-frequency voltage applied to symmetrical electrodes approximately in the vicinity des Poto & tlaimiirimuTnB β is applied.

Influencing the oscillating ions at the reversal can be avoided if you send the signals to one in the potential Minimum f arranged in £ Luenselectrc4e decreases "

Also toi der to ** hri »too · * B # tritbs * rt * at * wr ale Xqä · * t & rcm • in the Htekfre ^ fttmsfeld amfgescaaasmU and in« im »Mmliimlier Mkg · - iriesem wird», kenne «, dl« calibrated Ieasm located in the Beseaams on ü · next «be» b «chritbeme Weis · amif» eoeÄ »rtn. ^{The electrode S l, which is covered with a} breathable Modmlatiraaspamxug b «ftxfsehlt

• The Sd is damm in the middle a little more pesitirer * 5 * ot * aäial kaltta as * «r Mmltiplier and with a weckselejanmang the same benefit as the cases» 1g »ngsspa ^ i intimately with gssigneter Pmaiten-] mg · medulated di · M »iaam.wümam». «Im p * ras« lf * r »ig» »Fetemüal T» rii ** em, wlkmdl die mcht im S «i

809802/0783 I.

Overflowing potential mountain and being able to discharge. The modulated, Positively biased electrodes are generally not connected to the anode of the beam generating system forming the ionizing device coincide. A beam modulation, e.g. B. according to FIG. 3, possible.

A parabolic potential distribution can be done better than with the approximate the field electrodes 4 shown in Fig. 1 by the following arrangement: On a cylinder with linearly sloping from the center to the sides Conductivity (e.g. on a vapor layer) are applied via ring-shaped connection electrodes in the middle and at the ends, potentials, the potential in the middle is more negative than at the ends. Instead of a cylinder with inhomogeneous conductivity, a Cylinders with homogeneous conductivity occur, their wall thickness according to decreases linearly towards the outside.

In the mode of operation in which the ions are driven by a high-frequency field be rocked, phase focusing can also be used will. The resonance ions must indeed oscillate in a potential that is as strictly parabolic as possible, so that a phase focusing by wobbling, as described in connection with FIG. 4, is not appropriate. However, you can do a phase focusing by doing this The high-frequency voltage supplied symmetrically to the potential well can be achieved shifts in phase with respect to the ion oscillation.

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^BATH

809802/0783

While normally between the ion oscillation and the accelerating voltage there is a phase shift of about ar / 2, the phase shift is used to achieve phase focusing preferably greater than jr / 2 to a maximum of 3 jr / 4.

Since the space charges are effectively eliminated by the proposed measures, it makes sense, in a manner known per se, also to apply a longitudinal magnetic field that prevents a loss of ions perpendicular to the direction of oscillation, ie. decreased perpendicular to the longitudinal axis of the spectrometer tube.

The one that works with a purely electrostatic guide field The principles described in the dynamic mass spectrometer can of course also be applied to other dynamic mass spectrometers, in which the ions perform repetitive movements. At a with a magnetic guide field working mass spectrometer, which is known under the name Chronotron (G. R. Rieck "Einfühining in the mass spectroscopy "VEB Deutscher Verlag der Wissenschaften Berlin, 1956, page 161 ff), the grids can, for example, be negative Defocusing pulse can be applied while the ions are moving desired mass are in the area of the ion source and the collector. To the resonance ions the influence of the defocusing field appropriate shielding can be provided.

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809802/0783

Claims (26)

PATENT CLAIMS 1. Procedure for operating a dynamically operating mass spectrometer, in which the ions carry out a return of movement on stable orbits determined by a field, with ions of a certain Mass by a periodic change in a parameter of the mass spectrometer system separated and brought to evidence, characterized in that in a part of the Spectrometer periodically distorting the field that determines the orbits Additional field is generated at times in which the resonance ions are outside this range, so that the not ions in resonance can escape from the stable orbits and discharge. 2. The method according to claim 1 for an electrostatic mass spectrometer with ion source, field electrons, interceptor and / or secondary electron multiplier, in which the ions perform oscillations with a frequency dependent on the force and ions of a certain mass are accumulated , characterized in that one is preferably located on the side of the ion source Electrode is fed periodically, preferably negative voltage pulses of short duration * ORIGINAL BATHROOM “22- 809802/0783 while the ions in resonance are in the area of the collector are located and are shielded by this or an adjacent electrode against the additional field generated by the pulses. 3. "The method according to claim 1 or 2, characterized in that an alternating voltage is applied to an electrode (3, 3d) which is arranged on the opposite side of the collector or multiplier and which is positively biased with respect to the minimum potential of the field, di © with the AC voltage causing the accumulation of the ions is synchronized. 4. The method according to claim 2 and / or 3, characterized in * that the ions are generated by an electron beam, which in itself known manner at an angle, preferably perpendicular to the path of the oscillating ions, but at a location where the potential is more negative than the potential at which the entry electrode is located of the multiplier is located; that furthermore the potential of an electrode, those on the parabolic Potential ™ opposite the multiplier trough, at least when the package of resonance ions is there is more positive than the potential of the input electrode of the Multipliers and that in the drilling a high frequency in a known manner is generated, its frequency with the oscillation frequency of the tone matches. 809802/0783 5. The method according to claim 3 or 4, characterized in that that the ion generation takes place intermittently with the frequency of the resonance ions in a manner known per se and that the alternating voltage on the positive electrode is synchronized with the rhythm of the ion generation. β. The method of claim 5, wherein the Wehnelt voltage with the Frequency of the resonance ions is modulated, characterized in that the positive electrode is one with the Wehnelt voltage in-phase modulation voltage is supplied. 7. The method of claim 6, wherein the electron beam is parallel to the direction of oscillation of the ions is injected, thereby characterized in that the .positive electrode is the anode of the beam generating system. 8. The method according to claim 6 or 7, characterized in that that the voltage on the Wehnelt cylinder consists of relatively short pulses, the voltage with the maxima of the positive half-waves of the modulation coincide at the positive electrode. 9. The method according to any one of claims 3 to 8, characterized in that that the phase of the alternating voltage supplied to the positive electrode with respect to the phase of the oscillating resonance ion packet is wobbled. -24- 809802/0783 10. The method according to claim 9, characterized in that the anode is supplied with a modulation voltage, the phase with respect to. the tension applied to the Wehnelt cylinder is wobbled. 11. The method according to claim 9 or 10, characterized in that the voltage at the positive electrode as a function of the wobble stroke is distorted asymmetrically (Fig. 4). 12. Device for performing the method according to one of the claims 6 to 11, characterized by a high-frequency grounded, preferably grid-shaped electrode between the Wehnelt cylinder and the positively biased one to which the modulation voltage is applied Electrode. 13. Device for performing the method according to one of the claims 2 to 11, identified by a catcher consisting of a Number of electrodes * arranged one behind the other in the direction of oscillation of the ions (7a to 7d, FIG. 6), which on in the direction of entry of the Ions with rising positive potentials are connected to a detection device in parallel with an alternating current. 14. Device according to claim 13, characterized in that the electrodes expand the shape of themselves in the direction of the inlet opening Have frustoconical surfaces. 15. Einrichteng according to claim 13 or 14, characterized by a source of adjustable potential for the individual electrodes. -25- BATH ORIGINAL 809802/0783 16. Device for performing the method according to one of the claims 3 to 11, characterized by an alternating current earthed, at least approximately cylindrical electrode (3b) on a positive DC voltage is held and in which a second, a positively biased electrode (3d) is located, the «« demodulation voltage can be supplied. 17. Device for performing the method according to one of the claims 3 to 11, characterized in that the field in the tube corresponds in a manner known per se to an approximately parabolic potential, that the potential is in the vicinity of the turning point of the resonance ions, at least at the times when the resonance ions are there, so below the potential corresponding to a parabola that a sub-linear oscillator results. 18. Device for performing the method according to one of the claims 2 to 11, characterized in that the voltage source for the voltage generating the additional field is of low resistance. 19. Device according to claim 17 or 18, marked by a tube with a weakly conductive inner layer, the conductance of which decreases linearly from the center to the ends. 20. Device according to claim 17 or 18, characterized by a tube made of a material of homogeneous conductance, the wall thickness of which decreases from the center outwards. -26- BADORIQINAL 809802/0783 21. Device according to one of claims 19 or 20, characterized through ring electrodes for supplying the operating voltages. 22. Device for performing the method according to one of the claims 2 to 11, characterized by a one in the middle between the Reversal points of the resonance ions located, in terms of high frequencies Ground-insulated electrode from which the signal voltages can be taken. 23. Device for performing the method according to claim 7, characterized by a frequency fluctuating oscillator (1), the can be controlled by the time deflection voltage of an oscilloscope (23), through a first mixer (3), in which the output voltage of the variable Oscillator is mixed with a fixed frequency, which is dimensioned in such a way that that the resonance necessary for the desired mass range * ' frequencies that can be fed to the Wehnelt cylinder. 24. Device according to claim 23, characterized by a second mixing stage (11), which the output & panmng of the variable Oscillator (1) and a voltage of a fixed frequency via a manually and / or electrically controllable phase shifter (§) can be supplied and by connecting the output of the mixer (11) to the positive one Electrode (3) of the spectrometer system. 25. Device according to claim. 24, jjeksas & eiclmet through a between the second “Mischafcafe (11) nad di © Äaade g © s ^ altei © 809 802/078 3 stmfe (14). 26. Device according to one of claims 23 to 25, characterized in that the signal output of the spectrometer tube with a third mixing stage. (20) is connected, which is also supplied with the output signal of a fourth mixer (16) and that the fourth Mixer on the one hand to the variable oscillator (1) and on the other hand is connected to a second fixed oscillator (17) which has a fixed Frequency delivers which is the distance between the desired intermediate frequency and the frequency of the first fixed oscillator (4). BATH ORIGINAL
809802/0783