The present disclosure is directed to ionization of a sample and, more particularly, ionization of a sample within an ion trap using photoionization and electron ionization.
Mass spectrometers are instruments used to analyze the mass and abundance of various chemical components in a sample. Mass spectrometers work by ionizing the molecules of a chemical sample, separating the resulting ions according to their mass-charge ratios (m/z), and then measuring the number of ions at each m/z value. The resulting spectrum reveals the relative amounts of the various chemical components in the sample.
One type of mass analyzer used for mass spectrometry is called a quadrupole ion trap. Quadrupole ion traps take several forms, including three-dimensional ion traps, linear ion traps, and cylindrical ion traps. The operation in all cases, however, remains essentially the same. Direct current (DC) and time-varying radio frequency (RF) electric signals are applied to the electrodes to create electric fields within the ion trap. These fields trap ions within the central volume of the ion trap. Then, by manipulating the amplitude and/or frequency of the electric fields, ions are selectively ejected from the ion trap in accordance with their m/z. A detector records the number of ejected ions at each rink as they arrive. Regardless of the particular technology of mass spectrometer used, before sample molecules can be analyzed they must be ionized by one of various methods.
Electron ionization (EI) is one common method for generating sample ions. In EI, electrons are typically produced through a process called thermionic emission from a filement. Thermionic emission occurs when the kinetic energy of a charge carrier, in this case electrons, overcomes the work function of the conductor. In a vacuum chamber of a gas analyzer, where there is little gas or air to conduct heat from or react with a filament, a current through the filament quickly heats it until it emits electrons. The electrons are accelerated, usually with a set of electron optics, towards the sample, which may be contained within a mass analyzer (e.g., an ion trap). As the electrons travel through the gaseous sample, the electrons interact with, fragment, and ionize molecules in the sample. The charged particles can then be transported and analyzed using additional electric fields.
EI uses relatively energetic electrons with energies of around 70 electron volts to ionize sample molecules, and as such can sometimes cause weaker molecules to fragment into smaller ions. For this reason energetic electrons are sometimes referred to as a “hard” ionization source. Fragmentation can be beneficial in cases where one wishes to learn more about the parent ion by analyzing the fragment or “daughter” ions. In cases where fragmentation is not desired (e.g., it is desirable to know the mass of the parent ion), a softer ionization technique may be appropriate.
One such soft ionization technique is photoionization (PI). In PI, a light source emits photons, generally in the ultraviolet wavelength range, to provide sufficient energy to eject electrons from molecules in the chemical sample, thereby ionizing them. The photons in PI have lower energy than the electrons in EI, typically 5-10 electron volts as opposed to the 70 electron volts typical of EI. As such, PI generally allows sample compounds to remain intact. Broadly speaking, PI can be accomplished by two different techniques: single-photon ionization, and multi-photon ionization. Single-photon PI occurs when the PI source produces photons that individually have sufficient energy to ionize molecules. This usually corresponds to about 10.6 electron volts, or 110-130 nm wavelength. In multi-photon PI, the photons have less energy, perhaps only 5 electron volts, or 240-260 nm wavelength, and therefore multiple photon-molecule interactions are required to ionize the molecule.
Single-photon PI generally requires a source such as a plasma lamp in the ultraviolet range. Traditional ultraviolet light sources are generally large compared to the dimensions of an ion trap, and may require the source to be located away from the trapping region. As a result, ions must be created outside of the ion trap and transported into the ion trap via the use of electric fields or fluid flow. However, creating ions outside of the ion trap may result in reduced sensitivity of the mass spectrometer, and the electron optics required to transport the ions may add additional complexity to the instrument. Also, some architectures used for mass analyzers that lend themselves to miniaturization, for example ion traps, may not be effective at efficiently trapping ions generated from an external source. In addition, the extra ionization chamber requires more space and larger vacuum pumps to evacuate, making it potentially unsuitable for applications where size and power consumption are an issue.
Laser diodes are small enough to provide an ultraviolet light source directly into an ion trap; however, they are limited to a wavelength of 248 nm, which corresponds to about 5 electron volts. This energy is insufficient for single-photon PI. Multi-photon PI is possible, however, with appropriate pulsing of laser diodes.
Embodiments of the disclosure described herein may overcome at least some of the disadvantages described above.
The present disclosure is directed to a mass spectrometer including an ion trap, which includes a first aperture, a center electrode or electrodes, and a second aperture. The on trap may be configured to trap and analyze an ionized sample. The first aperture may have a first diameter, and may be configured to receive electrons for the purpose of ionizing sample ions within the ion trap. The second aperture may have a second diameter, and may be configured to receive photons for the purpose of ionizing sample ions within the ion trap. The spacing between the electrodes may also be configured to receive either electrons or photons to ionize samples within the trap.
The present disclosure is directed to a method of ionizing a sample within an ion trap. The method may include directing electrons into an ion trap and fragmenting the sample with the electrons within the ion trap. Additionally, the method may include directing photons into the ion trap at a different time from the electrons. The photons may be provided as a series of pulses with a total energy sufficient to ionize the sample.
The drawings are not necessarily to scale or exhaustive. Instead, emphasis is generally placed upon illustrating the principles of the inventions described herein. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate several embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure. In the drawings:
Reference will now be made in detail to the embodiments of the present disclosure described below and illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to same or like parts.
Embodiments consistent with the present disclosure relate to a mass spectrometer configured to ionize a sample within an ion trap. The ionization may be accomplished through electron ionization (EI) or photoionization (PI). A coating may be provided on the ion trap to prevent unwanted electron emission during PI. Additionally, the ion trap may reduce electron burn or for other reasons known to those skilled in the art by providing end caps with different sized apertures. Several methods for ionizing the sample with EI and PI are disclosed in greater detail below. As shown in
Chamber 111 may be any suitable, substantially airtight container, and may be coupled to a vacuum path via one or more ports (not shown) so as to create a low pressure (e.g., vacuum) environment for chemical analysis. In operation, chamber 111 may be configured to receive a sample and convey the sample to ion trap 120 through one or more inlets (not shown). Electron source 110 may be configured to produce electrons and contain optics (not shown) to direct them into an ion trap 120. Additionally or alternatively, photon source 130 may produce pulses of photons and direct the pulses into ion trap 120. The sample may be ionized within ion trap 120 with either the electrons through EI, or photons through PI, and ion trap 120 may produce an alternating electric field to trap the ionized molecules. Ion detector 140 may receive the molecules ejected from ion trap, and may measure the number of ions at each mass-charge ratio (m/z).
Electron source 110 may include a filament configured to produce and direct electrons into ion trap 120. In one embodiment, electron source 110 may be heated with a current sufficient to emit electrons from a surface of electron source 110. The electrons may flow within an electric field from electron source 110, through an electron lens 115 and to ion trap 120. The electric field may focus the electrons into an electron beam as they travel from electron source 110 and through an aperture 117 of lens 115. The electron beam may enter ion trap 120 and ionize the sample molecules. A differential voltage may be established between the filament and lens 115 to accelerate the electrons into ion trap 120. In certain embodiments, changes in voltage applied to lens 115 may influence the amount of electrons directed into ion trap 120, and therefore the amount of molecules ionized within ion trap 120. A voltage difference may accelerate electrons sufficiently to ionize the sample. An increase in voltage may increase the number of electrons directed into ion trap 120, and a decrease in voltage may decrease the number of electrons directed into ion trap 120. It is recognized that other embodiments of the electron optics may be contemplated here that provide a sufficient number of electrons at a sufficient energy to ionize the sample in trap 120.
PI source 130 may include a light source configured to direct high intensity ultraviolet photons to the sample molecules within ion trap 120. In one embodiment, the photons may contact the sample molecules as the sample molecules enter ion trap 120. The photons may have sufficient energy to raise the energy level of one or more of the electrons contained within the sample molecules sufficiently to remove one or more of the electrons from a valence shell and thus ionize the molecules without fragmenting the molecules. For example, the photons may raise the energy level of the sample molecules to at least the ionization energy of the molecules. Photo source 130 may provide pulsed energy, as described in greater detail below, to raise the energy level of the molecules.
Ion trap 120 may include one or more electrodes. In one embodiment, ion trap 120 may have three electrodes including a ring electrode 123, a first end cap 122, and a second end cap 124. First end cap 122 may form a first aperture 121, and second end cap 124 may form a second aperture 125. Ring electrode 123 may be disposed between first and second end caps 122, 124. It is contemplated that ring electrode 123 may have any suitable shape, size, and/or configuration. In one embodiment, ring electrode 123 comprises a cylindrical shape forming a trap volume 126. In the embodiment of
First and second apertures 121, 125 may each be formed in a substantially center portion of first or second end cap 122, 124 and axially aligned with trap volume 126. In some embodiments, first and second apertures 121, 125 may each comprise substantially circular cross-sections. As shown in
Trap volume 126 of ring electrode 123 may include a coating configured to reduce and/or prevent electrons that may emit from ion trap 120 during a PI period or phase. The coating may surround a surface of trap volume 126. The coating may include a higher work function than the photons emitted from photon source 130, and may prevent the photons from liberating electrons from the surface of trap volume 126. In one embodiment, the coating may have a work function of about 11 eV, and the photons from photon source 130 may have a work function of about 10 eV. The coating may include a conductive or semiconductive material. For example, the coating may include a crystalline thin film with enhanced surface chemistry to prevent electron emission. In other embodiments the coating may include an insulated mask over the conductive material to prevent exposure to the ultraviolet light.
Ion trap 120 may be sufficient to trap and ionize molecules within trap volume 126. During an ionization period (i.e., a period when sample molecules are ionized via EI or PI in ion trap 120), ion trap 120 may generate time-varying electric fields to trap the ions within trap volume 126. For example, DC and RF fields may be applied to ring electrode 123 and produce an electric field sufficient to trap the molecules within trap volume 126. In some embodiments, DC and RF fields may also be applied to end caps 122, 124.
Mass spectrometer 100 may alter the DC and RF fields to eject the ionized molecules from ion trap 120. The ions may be ejected based on their m/z and into ion detector 140, which may be configured with a deflector or dynode 142. For example, a progressive increase in the strength of the electric fields may allow lighter ions to be ejected from ion trap 120 followed by heavier ions. As shown in
Ion detector 140 may be configured to capture the ions ejected from ion trap 120 and separate them for detection. Ion detector 140 may include a high negative voltage sufficient to attract the ejected ions, for example a voltage of approximately −2,000 V. In the embodiment of
As shown in
In operation, energy may be supplied to electron source 110 to release electrons into ion trap 120 via a focused electron beam. The electrons may be directed through first aperture 121 and into trap volume 126, where the electrons may ionize sample molecules by EI. The diameter of second aperture 125 may be enlarged relative to the diameter of first aperture 121 to prevent electrons from accumulating along a surface of second end cap 124. For example, second aperture 125 may allow electrons ejected into opening 120 to avoid contacting a surface of second end cap 124.
In a traditional mass spectrometer, electrons emitted from an electron source may not impact a sample, and instead the electrons may move across the ion trap and contact a second end cap in an area directly surrounding an aperture. Therefore, the electrons may hit the surface of the aperture before impacting neutral species within the trap to form ions. These electron collisions may induce a degradation of the surface around the aperture in such traditional systems. This may result in inaccurate detection of the ions within a sample, for example by creating field distortions. However, the enlarged diameter of second aperture 125 in the present disclosure may allow the electrons to avoid contact with second aperture 125 when emitted into trap volume 126. The electrons may then properly ionize a sample within ion trap 120.
The ionized sample may then be ejected from ion trap 120 and into detector 140 for detection. As described above, conversion dynode 142 is configured to provide a means of providing ions of a polarity that will be directed to detector 140. The diameter of second aperture 125 may also reduce and/or prevent ions from accumulating along a surface of second end cap 124. For example, second aperture 125 may allow ions to be ejected from ion trap 120 without contacting a surface of second end cap 124.
Ions emitted from a traditional ion trap and towards an ion detector may hit a surface of the second end cap in the area directly surrounding the aperture. Over a period of time the material may accumulate along the surface of the second end cap. This accumulation may form a resistive film that can hold an electric charge, eventually resulting in inaccurate analysis of the sample due to electric field distortions. However, the enlarged diameter of second aperture 125 may allow the ions to avoid contact with second aperture 125 when ejected from trap volume 126 and into ion detector 140.
Alternatively, ion trap 120 may ionize the sample through PI. Photons may be ejected from photon source 130 and into ion trap 120. In one embodiment, source 130 is configured to provide photons emitted with an energy sufficient to ionize species within the ion trap 120 with a single photon impact. The photons may pass through lens 131 before entering ion trap 120. The coating on ion trap 120 may be sufficient to prevent unwanted electron emission from a surface of the ion trap during PI. Such electron emission may cause unwanted fragmentation of sample ions.
In another embodiment, photon source 130 may provide the photons as a series of pulses, such that the pulses may collectively raise the ionization energy to an amount sufficient to ionize a sample molecule (
Photon source 130 may include a light source, wherein the light source may provide a series of photon pulses to a sample within ion trap 120. The light source may include, for example, a laser diode or a plasma lamp. Each consecutive pulse may further raise the energy level of the sample molecules higher than the preceding pulse, until each molecule has reached its ionization energy level (i.e., the level required to ionize the molecule). In one embodiment, each pulse may range from 2-50 ns in duration. The time between each pulse may range from 10-1,000 ns. Photon source 130 may also be pulsed such that ions are created only during the time interval in which the trap is configured to trap ions but switched off during the period when the trap is configured to eject ions.
As shown in
End plates 530 and 531 may have apertures 532 and 533, respectively. Aperture 532 in end plate 530 may be configured to receive electrons via electron source 110. Aperture 533 in end plate 531 may be configured to receive photons via photon source 130. In other respects, the operations of EI and PI proceed as described previously, including the configuration of source region and ion detection region from embodiments described in
The operation of the circuit is as follows. First, the third power supply 604 provides a current to the cathode filament 605, heating it sufficiently to cause thermionic emission of electrons. Second, the trigger power supply 602 is engaged to provide a high voltage of approximately 500-600 volts to the lamp anode 606. This voltage determines the energy of the electrons emitted from the cathode filament. When the energy of those electrons is sufficiently high, they will ionize the gas inside lamp 601 energize it into the plasma phase.
Once the lamp achieves the plasma state, the resistance between the lamp anode 606 and cathode 605 decreases and the current increases. At this point the high voltage of the trigger power supply 602 is no longer needed and it is disconnected via the trigger switch 607. The constant current power supply 603 takes over and maintains a current in the lamp 601 sufficient to maintain the plasma phase. In some embodiments, it may no longer be necessary to maintain a filament current through the lamp cathode 605 as the plasma arc will be sufficient to maintain the filament temperature. To turn the lamp off and end further photoionization once sufficient ionization has been achieved, a solid-state relay in series with lamp anode 606 (not shown) is opened to halt current through the lamp.
This circuit has the additional advantages of being able to provide lamp state information to the user, and also to compensate for any variations in the lamp due to manufacturing, or degradation of the lamp over time. For example, the microprocessor can increase or decrease the trigger voltage and/or the constant current. It can also adjust switching synchronization with ionization time. The microprocessor may also render the solid-state relay 703 unnecessary because it can simply turn off the power supply to end the photoionization pulse. Finally, depending on the duration of the off time between photoionization pulses, the microprocessor may be able to dispense with the trigger voltage altogether as the lamp may still be in plasma phase.
The present disclosure provides a mass spectrometer providing both EI and PI. Therefore, the mass spectrometer may accurately detect the parent ion(s) of the compound(s) in a sample and the fragment ions that are formed from the parent molecule(s). This may allow a user to more easily detect and identify similar compounds having similar structures, but different molecular weights. It may also allow detection of compounds that are preferentially ionized using one or the other techniques. The ion trap may prevent electron emission during PI, which may also allow for more accurate detection by preventing unwanted fragmentation of sample compounds.
Additionally, the mass spectrometer of the present invention provides for both EI and PI within an ion trap. This may result in more accurate detection of the ions, and may reduce the size and complexity of the mass spectrometer. The ion trap may comprise end caps having different diameter sizes to prevent electron burn and ion accumulation. A pulsed light source may provide sufficient energy for photoionization within the ion trap. Additionally, the pulsed light source of the present disclosure may provide a signal that does not decay after a period of time, and therefore may continue to provide sufficient energy to ionize the sample.
It will be apparent to those skilled in the art that various modifications and variations can be made to the system of the present disclosure. Other embodiments of the system will be apparent to those skilled in the art from consideration of the specification and practice of the method and system disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.
This application claims the benefit of U.S. Provisional Application No. 61/801,471, filed Mar. 15, 2013, which is herein incorporated by reference in its entirety.
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