Mass Spectrometry

1. Mass Spectrometry • The substance being analyzed (solid or liquid) is injected into the mass • spectrometer and vaporized at elevated temperature and reduced pressure. • The gaseous molecules are bombarded with high-energy electrons, which • convert some of the molecules into positively charged ions. • Magnetic and electric fields in the spectrometer separate the ions according • to their mass/charge ratios (m/z). • The vast majority of the ions generated carry only a single positive charge, • i.e.z = 1, so m/Z represents the molecular mass of the ions detected. • The spectrometer displays a spectrum of peak intensity (y-axis) versus • m/z (x-axis). • The peak intensity is shown as a % (relative to the abundance of the • most abundant peak (the base peak, which is set as 100%).

2. Diagram of a Simple Mass Spectrometer, Showing the Separation of Neon Isotopes

3. Interpretation of Mass Spectra. • The most important information obtained is the integral molecular weight • of the compound. i.e. the mass in the largest fragment. • The integral molecular weight is obtained from the molecular ion peak • of the compound, designated as m+. This will appear at the high end • (to the right hand side) of the m/z scale. • Two molecular ion peaks may be found when the parent compound • contains an element having two abundant isotopes (e.g. Cl and Br). • In some instances a molecule will not show a molecular ion peak • (because it has decomposed into smaller fragments) or its intensity will be too • low to be recorded.

4. Determination of Molecular Structure from Fragmentation Pattern. • The molecular structure can often be deduced from the masses of the fragments • obtained from the breakdown of the compound into smaller fragments, • i.e. from the fragmentation pattern. • Higher mass fragments are usually more important than smaller ones for structure • determination. • Each major peak identifies a particular mass fragment. • Intense peaks correspond to high probability fragments. • Rearrangements of ionized fragments, to structures not obviously related to the • parent compound, can sometimes complicate the analysis. • The fragmentation pattern obtained depends on the activation energy for bond • cleavage ( bond energy) and on the stability of the resulting positive ion. • The stability of the positive ion is generally of greatest importance. It will depend • on the effectiveness with which the positive ion fragment can delocalize its charge.

5. Base Peak 100 90 80 70 60 50 40 30 20 10 0 M - (H2O and CH2=CH2) CH2OH+ M - (H2O and CH3) Intensity (% of Base Peak) M - H2O Molecular Ion Peak M+ - 1 20 30 40 50 60 70 80 90 m / z

6. Isotope Peak Rules • When the parent compound contains an element that has more than one • stable abundant isotope, more than one peak will be found for each fragment • containing this element. • Although nearly all elements occur naturally as a mixture of isotopes, for the • lighter elements of interest in organic chemistry (H, C, N, O), one isotope, • the lighter one, predominates. • Since the abundances of 79Br and 81Br are 50.5% and 49.5%, two peaks of • nearly equal intensity, separated by two mass units, will occur for all • bromine-containing fragments. e.g. in the spectrum of CH3Br, two peaks of • nearly equal intensity will occur at m/e values of 94 and 96, corresponding • to (CH379Br)+ and (CH381Br)+. • Since the abundances of 37Cl and 35Cl are 24.6% and 75.4%, two peaks • with an intensity ratio of 1:3, separated by two mass units will occur in a • mass spectrum of a compound containing a single Cl atom.

7. The Nitrogen Rule • The integral molecular weight of the majority of organic compounds • (containing the lighter elements H, C, N, O, P, S, Cl, Br, I) will be an • even number, except for those containing an odd number of N atoms. • The appearance of an odd number for the integral molecular weight of the • molecular ion indicates that the compound contains an odd number of N atoms.