EP0217644A2

EP0217644A2 - Quadrupole mass filter

Info

Publication number: EP0217644A2
Application number: EP86307396A
Authority: EP
Inventors: William J. Fies; Michael S. Story
Original assignee: Finnigan Corp
Current assignee: Thermo Finnigan LLC
Priority date: 1985-10-01
Filing date: 1986-09-25
Publication date: 1987-04-08
Anticipated expiration: 2006-09-25
Also published as: EP0217644B1; JPS62188154A; EP0217644A3; JP2529219B2; CA1263152A; DE3678085D1

Abstract

An unbalanced radio frequency voltage is supplied between two pairs of conductive rods (10a, 10c; 10b, 10d) of a quadrupole mass filter of a mass spectrometer system. Means (S2) are provided for d.c. voltage polarity reversal for monitoring positive and negative ions. The d.c. voltage is derived by rectification of the radio frequency voltage.

Description

This invention relates to a quadrupole mass filter as used with mass spectrometers.
One type of mass spectrometer that is extensively used for qualitative and quantitative analysis of chemicals employs one or more quadrupole mass filters. In such spectrometers, quadrupole mass filters incorporating four conductive metal rods are supported on mounts made of an insulating material. The rods are energized by combined direct current (d.c.) and alternating current (a.c.) voltage to achieve selective mass focusing. An example of such a mass filter is described in US-A-4032782 which discloses a method of maintaining filter stability by thermal matching of the rods and the mounts.
To obtain accurate readings and interpretations of analyses performed by mass spectroscopy, it is highly desirable that the mass peak waveforms obtained by the scans are smooth and not characterized by spurious splits or depressions which affect the spectral quality of the data. In prior art systems, it has been observed that such spurious splits and depressions of the mass peaks occur frequently, thus deleteriously affecting the interpretation of the resulting data.
According to this invention there is provided a quadrupole mass filter, for use in a mass spectrometer, comprising first and second pairs of conductive rods for providing a time varying electrostatic field to focus a narrow band of masses; and a source of radio frequency voltage for each pair of rods; characterised by tuned circuit means for adjusting the magnitude of the voltage supplied to one of said pairs of conductive rods relative to that supplied to the other one of said pairs of rods, so that a radio frequency voltage unbalance is produced between said pairs of rods.
We have discovered that by unbalancing the r.f. voltages applied to the pairs of quadrupole rods spurious splits and depressions are substantially reduced, the mass peaks being smooth and devoid of spurious signals and deformations.
Further, the filter of the invention has good ion transmission and hence sensitivity especially for high mass ions.
The invention will now be described by way of example with reference to the drawing which is a schematic circuit and block diagram of a filter according to this invention.
With reference to the drawing, a quadrupole mass filter incorporates two pairs of conductive rods 10a, 10c and 10b, 10d disposed in a configuration that provides a hyperbolic field through which ions of the materials under investigation travel. The rods 10, which may be made of molybdenum, are connected to an electrical circuit that provides d.c. voltage and r.f. or alternating current (a.c.) voltage. The circuit network includes a tuned circuit that controls the magnitudes of the r.f. and d.c. voltages which are applied to the filter rods. The tuned or r.f. resonant circuit is a low loss, high Q circuit, and the phase relation of the r.f. voltage supplied to the two pairs of rods 10a,c and 10b,d is substantially 180°. The rods act to provide a time varying electrostatic field to focus a narrow band of masses.
In operation, a mass control voltage is derived from a control device, such as a computer or sweep generator and applied through an input resistor 12 to a summing point 14. The control voltage is used as a reference that sets the mass to which the mass spectrometer will respond. A feedback voltage V_fb is obtained from a measuring device 38, which is coupled to the rods 10 and to the tuned circuit, as will be described hereinafter. If a non-zero voltage appears at the summing point 14, this voltage is amplified by an error voltage amplifier 16 and the amplified voltage is fed to the control input of an r.f. generator 18. The r.f. generator 18 supplies an r.f. signal, having a frequency in the range of 1.0-2.0 MHz for example, to the tuned circuit, which comprises an inductive network consisting of inductances 20 and 22 and a capacitive network comprising capacitive elements 34 and 36. A center coil 24, which preferably has one or two turns, is coupled to the output of the generator 18 and is disposed at the center between the two inductances 20 and 22 to supply r.f. power to the tuned circuit.
The capacitive network of the tuned circuit includes the capacitive elements 30 and 32 which represent the capacitances of the wiring, mass filter and cables of the system. The capacitances 34 and 36, which are tied to test points TP1 and TP2, are selected so that the circuit is resonant at the desired frequency of operation, and so that the r.f. voltages measured at the test points TP1 and TP2 have a predetermined unbalance. The capacitances 34 and 36 may be fixed capacitors of selected value or variable capacitors. In either case, the values of the capacitances are such that they meet the requirements of resonance and r.f. unbalance.
Each inductance 20 and 22 is coupled at one end respectively to capacitive elements 26 and 28, which are tied to a reference potential such as ground. The other end of each inductance 20 and 22 is coupled to test points TP1 and TP2 respectively, which are connected to capacitors 34 and 36 respectively. The junction of the inductance 20 and capacitive element 34 is connected to opposing rods 10a and 10c, whereas the junction of the inductance 22 and capacitive element 36 is connected to opposing rods 10b and 10d. The inductances and capacitive elements form an LC resonant circuit which provides high r.f. voltage operation, up to3,000 peak volts for example.
Since the precise values of some of the capacitive elements of the tuned circuit are not known, the need for adjustments of the capacitive values of the tuned circuit to effectuate the r.f. unbalance is determined by an r.f. voltage measuring device such as an oscilloscope. The measuring device is coupled to the test points TP1 and TP2, and to the pairs of rods 10. The capacitors 34 and 36 are adjusted to obtain the desired unbalance. The adjustments may be made manually, or automatically in response to the measurement seen at the measuring device. Alternatively the inductors 20 and 22 may be formed with an unequal or different number of turns on opposite sides of the center tap to produce the desired r.f. voltage unbalance, or may be variable inductances that may be adjusted.
The output feedback V_fb of negative polarity from the measuring device 38 represents the difference in r.f. voltage between the rod pair 10a, 10c and the rod pair 10b, 10d. This feedback voltage is fed through a feedback resistor 40 to the summing point 14 to be combined with the mass control voltage of positive polarity. As described heretofore, the non-zero sum of the two voltages provides an error signal that is processed by the feedback loop including the tuned circuit and measuring device 38 to compensate for the error and drive the summed voltage at junction 14 towards zero.
The feedback voltage V_fb provided by the detector or measuring device 38 is also used to produce the positive and negative d.c. voltages which are applied to the rods 10 in order to produce the mass filtering action of the quadrupole. The feedback voltage is fed through a resolution controls circuit 40 which controls the slope and intercept of the d.c. signal, and thus allows for proper adjustment of mass resolution. The d.c. voltage is applied through parallel channels, one of which incorporates a phase inverting amplifier 44, to a d.c. rod polarity reversible switch S1. The switch S1, which is operated manually, or under computer control if so desired, reverses the d.c. voltage polarity to enable detection of positive or negative ions by the quadrupole filter. In actual operation, it is desirable to switch rapidly between positive ion analysis and negative ion analysis, and in such cases computer control is employed.
The positive and negative d.c. signals are passed respectively through voltage amplifiers 46 and 48, and applied to the junctions between the inductances 22 and 20 and the bypass capacitors 28 and 26, for application through the tuned circuit to the rod pairs 10.
Although the use of the switch S1 at the input of the voltage amplifiers 46 and 48 is a preferable implementation because it does not require switching of high voltage, bipolar d.c. rod voltage amplifiers are required to enable supplying either positive or negative output signals from each amplifier. In an alternative approach, a switch S2 is used at the output of the voltage amplifiers 46 and 48, and each amplifier needs only to supply a single polarity d.c. signal, one positive and the other negative.
With the implementation disclosed herein, the d.c. rod voltages are delivered to the quadrupole rods through the inductive coil structure. In such case, the center tap of coil 24 is isolated from the system ground and the r.f. circuit is completed by use of grounded bypass capacitors 26 and 28 which serve to complete the r.f. circuit while preventing excessive r.f. voltage from reaching the d.c. rod voltage amplifiers 46 and 48.
We have observed that with an unbalance of the r.f. voltages that are applied to the rods, the shapes of the mass peaks become smooth and afford a significant improvement in mass spectroscopy operation, particularly in quantitative analysis of high mass chemicals. There is a clear seperation between adjacent mass peaks without the spurious signals that are experienced in prior art systems and affect the accuracy of the spectroscopic readout. To obtain the desired unbalance, one or both of the capacitive elements are adjusted so that they are different in value. Similarly, the inductive elements may be adjusted to a different value, or adjustments both of inductance and capacitance may be made to achieve the required imbalance of r.f. voltages. In a preferred implementation, the r.f. voltage at one pair of rods, say 10a, 10c is approximately 1.4 times that at other pair of the rods 10b, 10d.

Claims

1. A quadrupole mass filter, for use in a mass spectrometer, comprising first and second pairs of conductive rods (10a, 10c; 10b, 10d) for providing a time varying electrostatic field to focus a narrow band of masses; and a source of radio frequency voltage (18) for each pair of rods; characterised by tuned circuit means (20, 22; 26, 28; 34, 36) for adjusting the magnitude of the voltage supplied to one of said pairs of conductive rods (10a, 10c or 10b, 10d) relative to that supplied to the other one of said pairs of rods (10b, 10d or 10a, 10c) so that a radio frequency voltage unbalance is produced between said pairs of rods.

2. A filter as claimed in Claim 1, characterised in that said tuned circuit means comprises at least first and second capacitances (34, 36) coupled respectively to said first and second pairs of rods (10a, 10c; 10b, 10d), said capacitances providing a controlled amount of unbalance in the r.f. voltage applied to the rods.

3. A filter as claimed in Claim 1 or Claim 2, characterised in that said tuned circuit means comprises at least first and second inductances (20, 22) coupled respectively to said first and second pairs of rods (10a, 10c; 10b, 10d), said inductances providing a controlled amount of unbalance in the r.f. voltage applied to the rods.

4. A filter as claimed in Claim 3, characterised by a center coil (24) coupled to the output of said source of voltage (18), and electrically coupled between said inductances (20, 22).

5. A filter as claimed in Claim 3 or Claim 4, characterised by bypass capacitors (26, 28) connected to said inductances (20, 22).

6. A filter as claimed in any preceding claim, characterised by a radio frequency voltage measuring device (38) for sensing the difference in voltages between said first and second pairs of rods (10a, 10c; 10b, 10d).

7. A filter as claimed in Claim 6, characterised by means for providing a mass control voltage for setting a reference to which said filter responds.

8. A filter as claimed in Claim 7, characterised by means (40) coupled to said voltage measuring device (38) for providing a feedback voltage to a summing point (14) at which said mass control voltage and said feedback voltage are summed to form a combined voltage.

9. A filter as claimed in Claim 8, characterised by an error voltage amplifier (16) coupled between said summing point (14) and said voltage source (18) for amplifying said combined voltage.

10. A filter as claimed in any one of Claims 6 to 9, characterised by switching means (S1) coupled to said measuring device (38) for providing a d.c. voltage to said pairs of rods (10a, 10c; 10b, 10d).

11. A filter as claimed in Claim 10, characterised by voltage amplifiers (46, 48) coupled between said switching means (S1) and said tuned circuit means (20, 22; 26, 28; 34, 36).

12. A filter as claimed in Claim 10 or Claim 11, characterised by means (S2) for reversing the polarity of the d.c. voltage applied to the rods.