Mass spectrometry differs from the types of spectroscopy previously discussed because the molecular information that the technique provides does not depend on absorption of electromagnetic radiation. In a mass spectrometer, molecules are converted to charged fragments called ions, which are then separated according to their masses. The chart that records the masses of the fragments together with a measure of their relative abundance is known as a mass spectrum. From the masses and abundance of the peaks in a mass spectrum, it is often possible to determine the exact mass of the molecule being analyzed and to obtain clues about molecular structure. Today chemists can use one of several different types of mass spectrometer. A brief description of electron-ionization mass spectrometry, widely used for the analysis of relatively small molecules, illustrates the general principles.
In simple terms, a mass spectrometer (all components of which operate in a high vacuum) consists of an inlet chamber into which the compound to be analyzed is introduced and vaporized. The gaseous molecules then pass into an ionization chamber, where they are bombarded by a beam of high-energy electrons. The electron beam generates, among other things, a positively charged molecule known as a molecular ion, which results from the removal of one electron from the molecule. The molecular ion can subsequently break apart into smaller fragments. The positively charged fragments (which for simplicity are considered here to bear only a single positive charge) are then accelerated by an electric field and directed into a mass analyzer. The mass analyzer contains a strong magnetic field, through which the molecular ions must pass. As the ions pass through the magnetic field, they are deflected into a curved path that is dependent on both their charge and mass. Ions of different mass travel along a different trajectory before reaching a detector, which records the intensities and masses of the ions that strike it. The mass spectrum that is recorded shows the mass-to-charge ratio (m/z) along the horizontal axis and ion abundance along the vertical axis. For ions bearing a single positive charge, z equals 1, and the horizontal axis shows the masses of the fragments directly.
The mass spectrum of the ketone 2-butanone serves as an example. The strongest peak in the spectrum is known as the base peak, and its intensity is arbitrarily set at a value of 100. The peak at m/z= 72 is the molecular ion and as such gives the molecular mass of the molecule. In high-resolution mass spectrometry, the mass of the molecular ion can be measured to an accuracy of 4 ppm. In such an instrument, the molecular ion of 2-butanone would appear at m/z= 72.0575, which would unambiguously establish its molecular formula as C4H8O. High-resolution mass spectrometry is an excellent method for determining the molecular formulas of organic compounds.
Valuable information about molecular structure also can be obtained from the mass of the fragments present in the mass spectrum. Various functional groups cause molecules to break apart in characteristic ways. Ketones, for example, usually break apart at the bond in which the alkane chain is joined to the carbonyl group. Loss of the CH3 group (m/z= 15) from 2-butanone generates the fragment at m/z= 57. Loss of the heavier CH3CH2group (m/z= 29) from 2-butanone generates the base peak at m/z= 43.
The spectroscopic techniques discussed above are central to the modern study of chemistry; they allow chemists to determine the specific molecular architecture of many organic substances. For very complicated molecules, such as many natural products that occur in living organisms, even a complete set of spectra is insufficient to allow an unambiguous structural assignment. Molecular structure can then be determined only by a step-by-step synthesis of the molecule, followed by confirmation that the synthetic molecule is identical to the natural one.
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