Time-of-flight mass spectrometry
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Time-of-flight mass spectrometry (TOFMS) is a method of mass spectrometry in which an ion's mass-to-charge ratio is determined via a time of flight measurement. Ions are accelerated by an electric field of known strength.[1] This acceleration results in an ion having the same kinetic energy as any other ion that has the same charge. The velocity of the ion depends on the mass-to-charge ratio (heavier ions of the same charge reach lower speeds, although ions with higher charge will also increase in velocity). The time that it subsequently takes for the ion to reach a detector at a known distance is measured. This time will depend on the velocity of the ion, and therefore is a measure of its mass-to-charge ratio. From this ratio and known experimental parameters, one can identify the ion.
Contents
1 Theory
2 Delayed extraction
3 Reflectron TOF
4 Ion gating
5 Orthogonal acceleration time-of-flight
6 Hadamard transform time-of-flight mass spectrometry
7 Tandem time-of-flight
8 Detectors
9 Applications
10 History of the field
11 References
12 Bibliography
13 External links
Theory
The potential energy of a charged particle in an electric field is related to the charge of the particle and to the strength of the electric field:
Ep=qUdisplaystyle E_mathrm p =qU,
(1)
where Ep is potential energy, q is the charge of the particle, and U is the electric potential difference (also known as voltage).
When the charged particle is accelerated into time-of-flight tube (TOF tube or flight tube) by the voltage U, its potential energy is converted to kinetic energy. The kinetic energy of any mass is:
Ek=12mv2displaystyle E_mathrm k =frac 12mv^2
(2)
In effect, the potential energy is converted to kinetic energy, meaning that equations (1) and (2) are equal
Ep=Ekdisplaystyle E_mathrm p =E_mathrm k ,
(3)
qU=12mv2displaystyle qU=frac 12mv^2,
(4)
The velocity of the charged particle after acceleration will not change since it moves in a field-free time-of-flight tube. The velocity of the particle can be determined in a time-of-flight tube since the length of the path (d) of the flight of the ion is known and the time of the flight of the ion (t) can be measured using a transient digitizer or time to digital converter.
Thus,
v=dtdisplaystyle v=frac dt,
(5)
and we substitute the value of v in (5) into (4).
qU=12m(dt)2displaystyle qU=frac 12mleft(frac dtright)^2,
(6)
Rearranging (6) so that the flight time is expressed by everything else:
t2=d22Umqdisplaystyle t^2=frac d^22Ufrac mq,
(7)
Taking the square root yields the time,
t=d2Umqdisplaystyle t=frac dsqrt 2Usqrt frac mq,
(8)
These factors for the time of flight have been grouped purposely. d2Udisplaystyle frac dsqrt 2U contains constants that in principle do not change when a set of ions are analyzed in a single pulse of acceleration. (8) can thus be given as:
t=kmqdisplaystyle t=ksqrt frac mq,
(9)
where k is a proportionality constant representing factors related to the instrument settings and characteristics.
(9) reveals more clearly that the time of flight of the ion varies with the square root of its mass-to-charge ratio (m/q).
Consider a real-world example of a MALDI time-of-flight mass spectrometer instrument which is used to produce a mass spectrum of the tryptic peptides of a protein. Suppose the mass of one tryptic peptide is 1000 daltons (Da). The kind of ionization of peptides produced by MALDI is typically +1 ions, so q = e in both cases. Suppose the instrument is set to accelerate the ions in a U = 15,000 volts (15 kilovolt or 15 kV) potential. And suppose the length of the flight tube is 1.5 meters (typical). All the factors necessary to calculate the time of flight of the ions are now known for (8), which is evaluated first of the ion of mass 1000 Da:
t=1.5m2(15000V)(1000Da)(1.660538921×10−27kgDa−1)+1.602×10−19Cdisplaystyle t=frac 1.5;mathrm m sqrt 2(15000;mathrm V )sqrt frac (1000;mathrm Da )(1.660538921times 10^-27;mathrm kg;Da ^-1)+1.602times 10^-19;mathrm C
(10)
Note that the mass had to be converted from daltons (Da) to kilograms (kg) to make it possible to evaluate the equation in the proper units. The final value should be in seconds:
- t=2.792×10−5sdisplaystyle t=2.792times 10^-5;mathrm s
which is about 28 microseconds. If there were a singly charged tryptic peptide ion with 4000 Da mass, and it is four times larger than the 1000 Da mass, it would take twice the time, or about 56 microseconds to traverse the flight tube, since time is proportional to the square root of the mass-to-charge ratio.
Delayed extraction
Mass resolution can be improved in axial MALDI-TOF mass spectrometer where ion production takes place in vacuum by allowing the initial burst of ions and neutrals produced by the laser pulse to equilibrate and to let the ions travel some distance perpendicularly to the sample plate before the ions can be accelerated into the flight tube. The ion equilibration in plasma plume produced during the desorption/ionization takes place approximately 100 ns or less, after that most of ions irrespectively of their mass start moving from the surface with some average velocity. To compensate for the spread of this average velocity and to improve mass resolution, it was proposed to delay the extraction of ions from the ion source toward the flight tube by a few hundred nanoseconds to a few microseconds with respect to the start of short (typically, a few nanosecond) laser pulse. This technique is referred to as "time-lag focusing" [3] for ionization of atoms or molecules by resonance enhanced multiphoton ionization or by electron impact ionization in a rarefied gas and "delayed extraction"[4][5] for ions produced generally by laser desorption/ionization of molecules adsorbed on flat surfaces or microcrystals placed on conductive flat surface.
Delayed extraction generally refers to the operation mode of vacuum ion sources when the onset of the electric field responsible for acceleration (extraction) of the ions into the flight tube is delayed by some short time (200–500 ns) with respect to the ionization (or desorption/ionization) event. This differs from a case of constant extraction field where the ions are accelerated instantaneously upon being formed. Delayed extraction is used with MALDI or laser desorption/ionization (LDI) ion sources where the ions to be analyzed are produced in an expanding plume moving from the sample plate with a high speed (400–1000 m/s). Since the thickness of the ion packets arriving at the detector is important to mass resolution, on first inspection it can appear counter-intuitive to allow the ion plume to further expand before extraction. Delayed extraction is more of a compensation for the initial momentum of the ions: it provides the same arrival times at the detector for ions with the same mass-to-charge ratios but with different initial velocities.
In delayed extraction of ions produced in vacuum, the ions that have lower momentum in the direction of extraction start to be accelerated at higher potential due to being further from the extraction plate when the extraction field is turned on. Conversely, those ions with greater forward momentum start to be accelerated at lower potential since they are closer to the extraction plate. At the exit from the acceleration region, the slower ions at the back of the plume will be accelerated to greater velocity than the initially faster ions at the front of the plume. So after delayed extraction, a group of ions that leaves the ion source earlier has lower velocity in the direction of the acceleration compared to some other group of ions that leaves the ion source later but with greater velocity. When ion source parameters are properly adjusted, the faster group of ions catches up to the slower one at some distance from the ion source, so the detector plate placed at this distance detects simultaneous arrival of these groups of ions. In its way, the delayed application of the acceleration field acts as a one-dimensional time-of-flight focusing element.
Reflectron TOF
The kinetic energy distribution in the direction of ion flight can be corrected by using a reflectron.[6][7] The reflectron uses a constant electrostatic field to reflect the ion beam toward the detector. The more energetic ions penetrate deeper into the reflectron, and take a slightly longer path to the detector. Less energetic ions of the same mass-to-charge ratio penetrate a shorter distance into the reflectron and, correspondingly, take a shorter path to the detector. The flat surface of the ion detector (typically a microchannel plate, MCP) is placed at the plane where ions of same m/z but with different energies arrive at the same time counted with respect to the onset of the extraction pulse in the ion source. A point of simultaneous arrival of ions of the same mass-to-charge ratio but with different energies is often referred as time-of-flight focus.
An additional advantage to the re-TOF arrangement is that twice the flight path is achieved in a given length of the TOF instrument.
Ion gating
A Bradbury–Nielsen shutter is a type of ion gate used in TOF mass spectrometers and in ion mobility spectrometers, as well as Hadamard transform TOF mass spectrometers.[8] The Bradbury–Nielsen shutter is ideal for fast timed ion selector (TIS)—a device used for isolating ions over narrow mass range in tandem (TOF/TOF) MALDI mass spectrometers.[9]
Orthogonal acceleration time-of-flight
Continuous ion sources (most commonly electrospray ionization, ESI) are generally interfaced to the TOF mass analyzer by "orthogonal extraction" in which ions introduced into the TOF mass analyzer are accelerated along the axis perpendicular to their initial direction of motion. Orthogonal acceleration combined with collisional ion cooling allows separating the ion production in the ion source and mass analysis. In this technique, very high resolution can be achieved for ions produced in MALDI or ESI sources.
Before entering the orthogonal acceleration region or the pulser, the ions produced in continuous (ESI) or pulsed (MALDI) sources are focused (cooled) into a beam of 1–2 mm diameter by collisions with a residual gas in RF multipole guides. A system of electrostatic lenses mounted in high-vacuum region before the pulser makes the beam parallel to minimize its divergence in the direction of acceleration. The combination of ion collisional cooling and orthogonal acceleration TOF [11][12] has provided significant increase in resolution of modern TOF MS from few hundred to several tens of thousand without compromising the sensitivity.
Hadamard transform time-of-flight mass spectrometry
Hadamard transform time-of flight mass spectrometry (HT-TOFMS) is a mode of mass analysis used to significantly increase the signal-to-noise ratio of a conventional TOFMS.[13] Whereas traditional TOFMS analyzes one packet of ions at a time, waiting for the ions to reach the detector before introducing another ion packet, HT-TOFMS can simultaneously analyze several ion packets traveling in the flight tube.[14] The ions packets are encoded by rapidly modulating the transmission of the ion beam, so that lighter (and thus faster) ions from all initially-released packets of mass from a beam get ahead of heavier (and thus slower) ions.[15] This process creates an overlap of many time-of-flight distributions convoluted in form of signals. The Hadamard transform algorithm is then used to carry out the deconvolution process which helps to produce a faster mass spectral storage rate than traditional TOFMS and other comparable mass separation instruments.[13]
Tandem time-of-flight
Tandem time-of-flight (TOF/TOF) is a tandem mass spectrometry method where two time-of-flight mass spectrometers are used consecutively.[16][17][18][19] To record full spectrum of precursor (parent) ions TOF/TOF operates in MS mode. In this mode, the energy of the pulse laser is chosen slightly above the onset of MALDI for specific matrix in use to ensure the compromise between an ion yield for all the parent ions and reduced fragmentation of the same ions. When operating in a tandem (MS/MS) mode, the laser energy is increased considerably above MALDI threshold. The first TOF mass spectrometer (basically, a flight tube which ends up with the timed ion selector) isolates precursor ions of choice using a velocity filter, typically, of a Bradbury–Nielsen type, and the second TOF-MS (that includes the post accelerator, flight tube, ion mirror, and the ion detector) analyzes the fragment ions. Fragment ions in MALDI TOF/TOF result from decay of precursor ions vibrationally excited above their dissociation level in MALDI source (post source decay [20]). Additional ion fragmentation implemented in a high-energy collision cell may be added to the system to increase dissociation rate of vibrationally excited precursor ions. Some designs include precursor signal quenchers as a part of second TOF-MS to reduce the instant current load on the ion detector.
Detectors
A time-of-flight mass spectrometer (TOFMS) consists of a mass analyzer and a detector. An ion source (either pulsed or continuous) is used for lab-related TOF experiments, but not needed for TOF analyzers used in space, where the sun or planetary ionospheres provide the ions. The TOF mass analyzer can be a linear flight tube or a reflectron. The ion detector typically consists of microchannel plate detector or a fast secondary emission multiplier (SEM) where first converter plate (dynode) is flat.[21] The electrical signal from the detector is recorded by means of a time to digital converter (TDC) or a fast analog-to-digital converter (ADC). TDC is mostly used in combination with orthogonal-acceleration (oa)TOF instruments.
Time-to-digital converters register the arrival of a single ion at discrete time "bins"; a combination of threshold triggering and constant fraction discriminator (CFD) discriminates between noise and ion arrival events. CFD converts a few nanosecond long Gaussian-shaped electrical pulses of different amplitudes generated on the MCP's anode into common-shape pulses (e.g., pulses compatible with TTL logic circuitry) sent to TDC. Using CFD provides a time point correspondent to a position of peak maximum independent of variation in the peak amplitude caused by variation of the MCP or SEM gain. Fast CFDs typically have dead time of several nanoseconds thus preventing repetitive triggering from the same pulse.
The TDC is an ion counting detector – it can be extremely fast (down to a few picosecond resolution), but its dynamic range is limited due to its inability to properly count the events when more than one ions simultaneously hit the detector. The outcome of limited dynamic range is that the number of ions detected in one spectrum is somewhat small. This problem of limited dynamic range can be alleviated using multichannel detector design: an array of mini-anodes attached to a common MCP stack and multiple CFD/TDC, where each CFD/TDC records signals from individual mini-anode. To obtain peaks with statistically acceptable intensities, ion counting is accompanied by summing of hundreds of individual mass spectra (so-called hystograming). To reach a very high counting rate (limited only by duration of individual TOF spectrum which can be as high as few milliseconds in multipath TOF setups), a very high repetition rate of ion extractions to the TOF tube is used. Commercial orthogonal acceleration TOF mass analyzers typically operate at 5–20 kHz repetition rates. In combined mass spectra obtained by summing a large number of individual ion detection events, each peak is a histogram obtained by adding up counts in each individual bin. Because the recording of the individual ion arrival with TDC produces only a single time point (e.g., a time "bin" correspondent to the maximum of the electrical pulse produced in a single-ion detection event), the TDC eliminates the fraction of peak width in combined spectra determined by a limited response time of the MCP detector. This propagates into better mass resolution.
Modern ultra-fast 8 GSample/sec analog-to-digital converters digitize the pulsed ion current from the MCP detector at discrete time intervals (125 picoseconds). Typical 8-bit or 10-bit 8 GHz ADC has much higher dynamic range than the TDC, which allows its usage in MALDI-TOF instruments with its high peak currents. To record fast analog signals from MCP detectors one is required to carefully match the impedance of the detector anode with the input circuitry of the ADC (preamplifier) to minimize the "ringing" effect. Mass resolution in mass spectra recorded with ultra-fast ADC can be improved by using small-pore (2-5 micron) MCP detectors with shorter response times.
Applications
Matrix-assisted laser desorption ionization (MALDI) is a pulsed ionization technique that is readily compatible with TOF MS.
Atom probe tomography also takes advantage of TOF mass spectrometry.
Photoelectron photoion coincidence spectroscopy uses soft photoionization for ion internal energy selection and TOF mass spectrometry for mass analysis.
History of the field
An early time-of-flight mass spectrometer, named the Velocitron, was reported by A. E. Cameron and D. F. Eggers Jr, working at the Y-12 National Security Complex, in 1948. The idea had been proposed two years earlier, in 1946, by W. E. Stephens of the University of Pennsylvania in a Friday afternoon session of a meeting, at the Massachusetts Institute of Technology, of the American Physical Society.[22][23]
References
^ Stephens W. E. (1946). "A Pulsed Mass Spectrometer with Time Dispersion". Phys. Rev. 69 (11–12): 691. Bibcode:1946PhRv...69R.674.. doi:10.1103/PhysRev.69.674.2..mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em
^ US 2847576
^ Wiley, W. C.; McLaren, I. H. (1955). "Time-of-Flight Mass Spectrometer with Improved Resolution". Review of Scientific Instruments. 26 (12): 1150. Bibcode:1955RScI...26.1150W. doi:10.1063/1.1715212.
^ V. S. Antonov; V. S. Letokhov & A. N. Shibanov (1980). "Formation of molecular ions as a result of irradiation of the surface of molecular crystals". Pis'ma Zh. Eksp. Teor. Fiz. 31: 471.
JETP Lett. 31: 441. Missing or empty|title=
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^ Brown, R. S.; Lennon, J. J. (1995). "Mass resolution improvement by incorporation of pulsed ion extraction in a matrix-assisted laser desorption/ionization linear time-of-flight mass spectrometer". Anal. Chem. 67 (13): 1998–2003. doi:10.1021/ac00109a015. PMID 8694246.
^ Mamyrin, B. A.; Karataev, V. I.; Shmikk, D. V.; Zagulin, V. A. (1973). "The mass-reflectron, a new nonmagnetic time-of-flight mass spectrometer with high resolution". Sov. Phys. JETP. 37: 45. Bibcode:1973JETP...37...45M.
^ Time-of-flight mass spectrometer Boris A. Mamyrin et al., US 4072862
^ U.S. Patent 6,664,545
^ U.S. Patent 6,489,610
^ U.S. Patent 7,230,234
^ Dodonov, A. F., Chernushevich, I. V., Dodonova, T. F., Raznikov, V. V., Tal’rose, V. L. Inventor’s Certificate No. 1681340A1, USSR, February 25, 1987.
^ A.F. Dodonov, I.V. Chernushevich and V.V. Laiko, Time-of-Flight Mass Spectrometry (1994) ACS Symposium Series 549, Chap. VII.
^ ab Richard N., Zare (2003). "Hadamard Transform Time-of-Flight Mass Spectrometry: More Signal, More of the Time" (PDF). Angewandte Chemie International Edition. 42: 30–35. doi:10.1002/anie.200390047 – via Wiley-VCH.
^ Ansgar, Brock (1999). "Characterization of a Hadamard transform time-of-flight mass spectrometer" (PDF). Review of Scientific Instruments. 71 (3): 1306–1318. Bibcode:2000RScI...71.1306B. doi:10.1063/1.1150456 – via American Institute of Physics.
^ Ansgar, Brock; Rodriguez, Nestor; Zare, Richard N. (1998). "Hadamard Transform Time-of-Flight Mass Spectrometry". Analytical Chemistry. 70 (18): 3735–3741. doi:10.1021/ac9804036.
^ U.S. Patent 5,206,508
^ U.S. Patent 7,196,324
^ Medzihradszky KF, Campbell JM, Baldwin MA, et al. (2000). "The characteristics of peptide collision-induced dissociation using a high-performance MALDI-TOF/TOF tandem mass spectrometer". Anal. Chem. 72 (3): 552–8. doi:10.1021/ac990809y. PMID 10695141.
^ Vestal ML, Campbell JM (2005). Tandem time-of-flight mass spectrometry. Meth. Enzymol. Methods in Enzymology. 402. pp. 79–108. doi:10.1016/S0076-6879(05)02003-3. ISBN 9780121828073. PMID 16401507.
^ Spengler B.; Kirsch D.; Kaufmann R. (1991). "Metastable decay of peptides and proteins in matrix-assisted laser-desorption mass spectrometry". Rapid Communications in Mass Spectrometry. 5 (4): 198–202. doi:10.1002/rcm.1290050412.
^ U.S. Patent 7,446,327
^ Campana, Joseph E. (1987). "Time-of-Flight Mass Spectrometry: a Historical Overview". Instrumentation Science & Technology. 16 (1): 1–14. Bibcode:1987IS&T...16....1C. doi:10.1080/10739148708543625. ISSN 1073-9149.
^ Mirsaleh-Kohan, Nasrin; Robertson, Wesley D.; Compton, Robert N. (2008). "Electron ionization time-of-flight mass spectrometry: Historical review and current applications". Mass Spectrometry Reviews. 27 (3): 237–285. Bibcode:2008MSRv...27..237M. doi:10.1002/mas.20162. ISSN 0277-7037. PMID 18320595.
Bibliography
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Cotter, Robert J. (1994). Time-of-flight mass spectrometry. Columbus, OH: American Chemical Society. ISBN 978-0-8412-3474-1.
Ferrer, Imma; Thurman, E. M. (2009). Liquid chromatography-Time of Flight Mass Spectrometry: Principles, Tools and Applications for Accurate Mass Analysis. New York, NJ: Wiley. ISBN 978-0-470-13797-0.
Ferrer, Imma; Thurman, E. M. (2005). "Measuring the Mass of an Electron by LC/TOF-MS: A Study of "Twin Ions"". Anal Chem. 77 (10): 3394–3400. doi:10.1021/ac0485942. PMID 15889935.
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W. E. Stephens (1946). "A pulsed mass spectrometer with time dispersion". Bull Am Phys Soc. 21 (2): 22.
External links
- IFR/JIC TOF MS Tutorial
- Jordan TOF Products TOF Mass Spectrometer Tutorial
- University of Bristol TOF-MS Tutorial
- Kore Technology – Introduction to Time-of-Flight Mass Spectrometry