Triple Quadrupole Mass Spectrometry - American Chemical Society

Department of Chemistry. University of Florida. Gainesville, Fla, 32611. C. G. Enke. Department of Chemistry. Michigan State University. East Lansing,...
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Instrumentation R. A. Yost Department of Chemistry University of Florida Gainesville, Fla. 32611

C. G. Enke Department of Chemistry Michigan State University East Lansing, Mich. 48824

Triple Quadrupole Mass Spectrometry for Direct Mixture Analysis and Structure Elucidation Quad Mass Filter

Ion Source

Quad Collision Chamber

Quad Mass Filter

Particle Multiplier

IF-X*»

^ ^ Sample Ionization

Ion Selection

Ion Fragmentation +/or Reaction

Product Ion Selection

Ion Detection

Figure 1 . Conceptual diagram of the triple quadrupole mass spectrometer showing each component and its function

A new technique of mass spectro­ metry is rapidly emerging in which tandem mass analyzers are used for separation and identification in a sin­ gle instrument. In this technique (MS/MS), several ionic species are generated from a sample; ions of a particular mass are selected for frag­ mentation; the selected ions are frag­ mented by one of several possible techniques; and the resulting frag­ ment ions are mass-analyzed. We re­ cently introduced the concept of a tri­ ple quadrupole mass spectrometer as a particularly simple and efficient ap­ proach to selected ion fragmentation (1). T h e instrument consists of, in se­ ries, a dual chemical ionization/electron impact (CI/ΕΙ) sample ionization source, a quadrupole mass filter, an RF-only quadrupole t h a t can be pres­ surized with a collision gas, a second quadrupole mass filter and an electron 0003-2700/79/A351-1251$01.00/0 © 1979 American Chemical Society

multiplier, as shown in Figure 1. T h e ion fragmentation process is per­ formed by collision-induced dissocia­ tion (CID) in which the ion acquires internal energy by collision with a neutral molecule. T h e RF-only qua­ drupole collision chamber provides fo­ cusing of scattered ions and is highly efficient (2). In this system, the select­ ed ion fragmentation process can pro­ vide enhanced selectivity and discrim­ ination over normal mass spectrome­ try without significant loss of sensi­ tivity.

A n A d d e d Dimension of Information

The added information contained in the fragmentation spectrum of each source ion species is of great value in several areas of mass spectrometry, especially the elucidation of organic

structures and the analysis of mix­ tures. In structure elucidation applica­ tions, fragment ions of any mass which appear in a compound's normal mass spectrum can be selected with the first mass analyzer. This parent ion is fur­ ther fragmented, and the mass spec­ trum of the resulting daughter ions is determined by scanning the second mass analyzer. A complete fragmenta­ tion map may be obtained by record­ ing the mass spectrum of each frag­ ment ion of a compound. Figure 2 is an example of such a map for cyclohexane. Note t h a t the normal electron impact mass spectrum, displayed along the diagonal (fragment ion m/z = parent ion m/z), is the only informa­ tion available without the added di­ mension of selected ion fragmenta­ tion. For analysis of mixtures, the molec­ ular ions for each component can be

ANALYTICAL CHEMISTRY, VOL. 5 1 , NO. 12, OCTOBER 1979 · 1251 A

Figure 2. Three-dimensional fragmentation map for cyclohexane

produced by soft ionization such as chemical ionization or field desorption and then separated by the first mass analyzer. Thus the molecular ion species can be selected for one compo­ nent at a time, the selected ion frag­ mented, and its fragmentation mass spectrum obtained by scanning the second analyzer. The added dimen­ sion in this case is the selectivity and discrimination achieved through mass separation of the molecular ions of the several components. The elimination of chemical noise that results can often improve the detection limit of the mass spectral technique (3). The use of mass spectral separation of the components of a mixture in MS/MS eliminates the time delays as­ sociated with the chromatographic separation used in GC/MS and LC/ MS. Because all the components are available at any time and in any order, only those components of particular interest need be analyzed. Each com­ ponent may be selected for as much or as little time as is required to deter­ mine its identity and its quantity. Continuous analysis of a sample is possible in such applications as atmo­ spheric analysis, without the time de­ lays associated with batch sampling for chromatographic analysis. Direct insertion probes and field or chemical desorption can be used to introduce involatile or thermally labile samples. Other Selected Ion Fragmentation and Tandem Mass Spectrometers

There are several other approaches to selected ion fragmentation, the most notable of which for analytical applications is Mass-Analyzed Ion Ki­ netic Energy Spectrometry, or MIKES (also called Collisional Acti­ vation Mass Spectrometry or CAMS, and Direct Analysis of Daughter Ions or DADI). This technique makes use of a double-focusing mass spectrome­ ter in which the magnetic sector pre­ 1252 A • ANALYTICAL CHEMISTRY,

cedes the electrostatic analyzer. Frag­ mentation between the sectors can be unimolecular (metastable ions) or collisionally induced. MIKES has been demonstrated as a technique for se­ lected ion fragmentation in such ap­ plications as structure elucidation (4-8) and mixture analysis (3, 9). The structure elucidation technique has been clearly described by Beynon (8). The technique for analysis of mixtures has been reviewed by Cooks in these pages (3). It is also possible to emulate the MIKES technique with a normal geometry double-focusing mass spec­ trometer (electric sector preceding the magnet) and a linked scan of both the electric sector field strength and ei­ ther the magnetic field or accelerating voltage (10). Ions enter the CID colli­ sion chamber in sector instruments with 3-30 keV of kinetic energy. The mechanism of the CID process at these high energies is fundamentally different from the process at the low kinetic energies (3-50 eV) of ions in the triple quadrupole instrument (11). True tandem mass spectrometers have been constructed to apply select­ ed ion fragmentation techniques to the study of interactions between ions and molecules (12). Two quadrupoles in tandem have been employed to study ion-molecule reactions (13), and triple quadrupole systems have been applied to study the photodissociation of ions (14, 15). However, it is the lowenergy CID process in the center quad that makes the triple quadrupole spectrometer described here particu­ larly well suited for analytical applica­ tions. Hunt and co-workers have re­ cently reported on the analytical ap­ plications of a triple quadrupole in­ strument constructed in their labora­ tory (16). Modes of Operation

There are three fundamental con­ trol parameters in the triple quadru­

VOL. 5 1 , NO. 12, OCTOBER

1979

pole mass spectrometer. These are the mass selected by the first mass analy­ zer, the presence or absence of colli­ sion gas in the quad collision chamber, and the mass selected by the second mass analyzer. These parameters may all be varied independently or in com­ binations to provide a variety of useful modes of operation as enumerated and described below: • In order to obtain a normal mass spectrum (only one stage of mass anal­ ysis), the first mass filter is scanned with the second and third quadrupoles in RF-only (total-ion) mode. The colli­ sion gas may be present or not, since it does not significantly affect the number of ions reaching the detector. • A scan of the third quadrupole while the first mass filter passes a spe­ cific mass produces a spectrum of all the daughter ions from the selected parent ion. If the collision gas is ab­ sent, the unimolecular decomposition products ("mestastable" ion decompo­ sition) will be measured. • The spectrum of all parent ions that fragment to produce a given daughter ion is observed by scanning the first mass filter with the third quadrupole fixed on the daughter ion mass. • The observation of a specific neu­ tral mass loss is achieved by scanning both mass filters with a fixed differ­ ence in mass. The use of a double-fo­ cusing mass spectrometer for neutral loss spectra has been suggested re­ cently as a useful but complicated technique for structure elucidation (17).

• A specific parent/daughter ion transition is selected in single reaction monitoring (18), a technique analo­ gous to single ion monitoring in gas chromatography/mass spectrometry. • The quadrupole's linear mass scale and fast response permit rapid multiple reaction monitoring in which multiple parent/daughter ion pairs are observed. Mixture Analysis

As an example of the performance of the triple quadrupole mass spec­ trometer, the following sample which contains five components at equal concentration was chosen: 3-heptanone and n-heptanal (isomers of mo­ lecular weight 114), «-octane (isobaric with the other two at 114), cyclohex­ ane (84), and 2-pentanone (86). The mixture was ionized by 70 eV EI, al­ though CI would have simplified the mass spectrum. The CID spectra of the 114+ ion from the individual com­ ponents show unique fragmentation: 99+ (M-15) for 3-heptanone, 96+ (M18) for n-heptanal, and 70+ (C 5 Hi 0 + ·) for η-octane. In the CID spectrum of the 114+ ion in the mixture, it is possi­ ble to detect the individual compo-

Reference Spectra

Spectra of Selected Ions

Ion Fragmentation

43 n-Octane 43 114·. υ c 3

£ 1010"

Bruce R. Kowalski, Editor University of Washington A symposium sponsored by the Division of Computers in Chemistry of the American Chemical Society. This new collection constitutes an invaluable aid for every analytical chemist, instrument designer, and builder interested in the search for better measurement system control as well as up-to-date optimization and measurement analysis methods. Increased use of chemical measurements, combined with the >roliferation of computers in chemical aboratories, has prompted a drive for new and improved methods to design and control experiments and to analyze the wealth of data that can be generated.

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The results of this research effort are discussed in 12 chapters covering the development and application of new mathematical and statistical analysis methods to extract useful chemical information from chemical measurements. CONTENTS Optimization Methodology in Chemistry · ARTHUR and Experimental Data Analysis · Abstract Factor Analysis « TargetTransformation Factor Analysis · Application of Factor Analysis to the Study of Rain Chemistry · Electron Spin Resonance of Spin Labels · Stirred-Pool ControlledPotential Chronocoulometry · Application of Nonlinear Regression Analysis to Chemical Data · Structure-Activity Studies · Enthalpy-Entropy Compensation · How to Avoid Lying with Statistics · SIMCA: A Method for Analyzing Chemical Data in Terms of Similarity and Analogy 288 pages (1977) $21.00 clothbound LC 77-9088 ISBN 0-8412-0379-2 SIS/American Chemical Society 1155 16th St., N.W./Wash., D.C. 20036 Please send copies of SS 52 Chemometrics at $21.00 per copy. D Check enclosed for $ . D Bill me. Postpaid in U.S. and Canada, plus 40 cents elsewhere. Name Address City

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10- s 10" 4 Collision Gas Pressure (N2)

(torr) 10-

Figure 6. Effect of collision gas (N 2 ) pressure on CID efficiency for methane C H 4 + · at ion axial energy of 10eV

chemical and electrical noise levels, and the lowest measurable signal level. The electrical noise in the system is typically 3 X 10~ 1 3 A. The two stages of mass separation often make it pos­ sible to reduce chemical noise (ions detected from other than the desired reaction) to well below the 1 0 - 1 3 A level. In such a case, at the extreme sensitivity limit, the peak height is quantized by the integer number of ions which reach the detector during the scanning time of the peak. The de­ tection of 4 ions would give an S/N of 2 and, for methane, would require 6 fg of sample. T h e detection limit for methane has been determined experi­ mentally to be 16 femtograms by mea­ suring a sample of 10 ppm CH 4 in N2 at a sample flux of 20 femtograms per sec of CH4. The large excess of N2 is required to increase the ion source pressure so that it can be accurately measured and the sample flux calcu­ lated. The selectivity of monitoring the CH4 + - -* CH3 + reaction has ef­ fected a two order of magnitude im­ provement in detection limit com­ pared to that obtained by simply mon­ itoring the CH 4 +·, CH 3 +, or CH 2 +· ions from electron impact. This im­ provement is due to the elimination of the chemical noise introduced by background 1 4 N + -, 15 N+· and 1 6 0+· peaks. The selected ion fragmentation ca­ pability of the instrument produces only a small loss in transmission and sensitivity, and produces a significant gain in selectivity. Indeed, in the nor­ mal case where the system is limited by chemical rather than electrical noise (3), a substantial improvement

1262 A · ANALYTICAL CHEMISTRY, VOL. 51, NO. 12, OCTOBER 1979

in detection limit can be achieved as was observed for methane. T h e detec­ tion limit of approximately 1 0 - 1 5 mole is made possible by the high efficiency of every component of the system. The detection limit for a higher mass organic compound, nitroben­ zene, has also been determined experi­ mentally. The transition N 0 2 C 6 H 5 + · —»· CeH5 + was monitored at unit mass resolution in both mass filters, with the parent ion produced by electron impact on a sample of 10 ppm nitro­ benzene in N2. A detection limit of 120 femtograms (S/N = 2) was obtained with a sample flux of 200 femtograms/ sec. In comparison, for the M I K E S technique, Cooks has estimated a de­ tection limit of 10 pg for the 140 + -*• 123 + transition of protonated nitrophenol ions produced by CI (22). Al­ though consumption of only femto­ grams is required for recording the single reaction, actual sample size is significantly larger than this and is de­ pendent on the sample inlet used. Total consumption of a sample intro­ duced by direct probe should make it possible to detect quantities of indi­ vidual components at close to these detection limits. Conclusions

T h e CID process performed in the strong focusing field of an RF-only quadrupole is efficient and effective in producing characteristic spectra of selected ions. T h e kinetic energy inde­ pendence of the mass resolution is ideal for collision product analysis. The lack of interdependence in the control of the two mass filters makes

Topics in . . .

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it easy to implement the various analytical modes. T h e system can be used to detect species present in a mixture including isomers without prior separation at the 1 0 - 1 5 mole level. T h e capability to select a desired initial mass and specific collision product mass reduces chemical noise dramatically. For structure elucidation applications, the spectra of selected functional moieties in the molecule may be obtained. Among the many other promising applications of the selected ion fragmentation technique is the analysis of isotopically labeled samples, in which the first mass filter can eliminate interferences from molecules t h a t are not completely labeled.

Acknowledgment We wish to acknowledge the work of the MSU Chemistry D e p a r t m e n t Machine Shop headed by Russ Geyer, and master machinist Len Eisele who constructed much of the instrument. We would also like to express our gratitude to Kaz Latven, John Chakel and Fritz Allen who helped to get the ins t r u m e n t functioning and t o demonstrate its application. Finally, we would like to acknowledge the invaluable time spent in the laboratory of J i m Morrison a t La Trobe University and helpful discussions with Graham Cooks and Chuck Sweeley.

References (1) R. A. Yost and C. G. Enke, J. Am. Chem.Soc, 100,2274-75(1978). (2) R. A. Yost, C. G. Enke, D. C. McGilvery, D. Smith, and J. D. Morrison, Int. J. Mass Spectrom. Ion Phys., 30,127136 (1979).

S I S / A m e r i c a n C h e m i c a l Society 1155 16th St., N.W./Wash., D C . 2 0 0 3 6 Please send copies of Chemical Instrumentation—II at $12.00 per copy. CI Check enclosed for $ . D Bill me. Postpaid in U.S. and Canada, plus 40 cents elsewhere. Name Address

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ANALYTICAL CHEMISTRY, VOL. 5 1 , NO. 12, OCTOBER

This work was supported in part by the Office of Naval Research.

Chris Enke (left) and Rick Yost developed the triple quadrupole mass spectrometer at Michigan State University where Chris is professor of chemistry and Rick was a graduate fellow with support from the National Science Foundation and Analytical Division of ACS (sponsored by the Upjohn Company). Rick is currently assistant professor of chemistry at the University of Fla., Gainesville and is pursuing a research program in computer applications and modern instrumentation with special emphasis in mass spectrometry. The research program in Chris' lab at Michigan State University includes the development and application of computer-based instrumentation in optical spectroscopy, electroanalytical chemistry, and mass spectroscopy.

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(3) R. W. Kondrat and R. G. Cooks, Anal. Chem., 50, 81A-92A (1978). (4) R. G. Cooks and J. H. Beynon, MTP Int. Rev. Sei., Ser. II, 5,159 (1975). (5) F. W. McLafferty, P. F. Bente, R. Kornfeld, S. C. Tsai, and T. Howe, J. Am. Chem. Soc, 95, 3886 (1973). (6) U. P. Schlunegger, Angew. Chem. Int. Edn., 14,679-88(1975). (7) K. Levsen and H. Schwarz, Angew. Chem. Int. Edn., 15, 509-19 (1976). (8) M. H. Bozorgzadeh, R. P. Morgan, and J. H. Beynon, Analyst, 103, 613-22 (1978). (9) F. W. McLafferty and F. M. Bockhoff, Anal. Chem., 50, 69-76 (1978). (10) R. J. Stradling, K. R. Jennings, and S. Evans, Org. Mass Spectrom., 13 429-30 (1978). (11) Manuscript in preparation. (12) J. H. Futrell and T. O. Tièrnan in "Ion-Molecule Reactions," J. L. Franklin, Ed., Chap. 11, Plenum, New York, 1972. (13) T.-Y. Yu, M. H. Cheng, V. Kempter, and F. W. Lampe, J. Phys. Chem., 76, 3321-30 (1972). (14) M. L. Vestal and J. H. Futrell, Chem. Phys. Lett., 28, 559-61 (1974). (15) D. C. McGilvery and J. D. Morrison, Int. J. Mass Spectrom. Ion Phys., 28, 81-92 (1978). (16) D. F. Hunt and J. Shabanowitz, 27th Annual Conference on Mass Spectrometry and Allied Topics, Seattle, Wash., June 1979; paper FAMOC2. (17) M. J. Lacey, C. G. MacDonald, Anal. Chem., 51,691-95(1979). (18) R. W. Kondrat, G. A. McClusky, and R. G. Cooks, Anal. Chem., 50, 2017-21 (1978). (19) F. W. McLafferty, "Interpretation of Mass Spectra," 2nd Ed., pp 95-6, W. A. Benjamin, Reading, Mass. 1973. (20) Manuscript in preparation. (21) G. Eadon, C. Djerassi, J. H. Beynon, and R. M. Caprioli, Org. Mass Spectrom., 5,917-33(1971). (22) T. L. Kruger, J. F. Litton, R. W. Kondrat, and R. 6. Cooks, Anal. Chem., 48, 2113-19(1976).

1979