Organic Structural Spectroscopy by Lambert, Shurvell, Lightner Calculation of approximate intensity distribution due to natural isotope abundance

Organic Structural Spectroscopy by Lambert, Shurvell, Lightner

Molecular formula determination by exact mass measurements Examples The calculated isotope ratios for CO, N 2, and C 2 H 4, all of molar mass 28, are as follow: CO100 (M) 1.14 (M+1) 0.2 (M+2) N (M) 0.76 (M+1) C 2 H (M) 2.26 (M+1) 0.01 (M+2) The calculated isotope ratios for C 3 H 6 and CH 2 N 2, both of molar mass 42, are as follow: C 3 H (M) 3.39 (M+1) 0.05 (M+2) CH 2 N (M) 1.87 (M+1) 0.01 (M+2)

Calculated isotopic distribution for protonated bovine insulin. The chemical molecular weight based on elemental atomic weights is Da. The molecular weight based on the most abundant isotope of each element is Da, and the molecular weight based on the most abundant isotopic form of the molecule is Da. Different isotope distributions that match the molecule mass Da

Schematic Representation of a Sector Mass Spectrometer Spectroscopic Methods in OC by Hesse, Meier, Zeeh

Mass Analysis for Magnetic Sector MSs Magnetic sectors deflect accelerated beams of ions, with the degree of deflection depending on the mass, the charge, and the velocity of the ion beam. The speed of ions is described by: v = (2zU / m) 1/2 z = ionic charge, m = ion mass, U = acceleration potential (V) The mass separation is given by:r m = mv / zB (cm) B = magnetic field strength (T) Both equations can be combined to give the fundamental equation of MS: m/z = B 2 r m 2 / 2U U and B are kept constant: m/z = constant r m 2 U and r m are kept constant: m/z = constant B 2 For typical values of B max = 1.5 Tesla, r m = 30 cm, and U = 5 kV, the maximum value for m/z is 1953 Da/charge; Metastable ions are generated by fragmentation after acceleration but before entering the magnetic sector. The position of their diffuse peaks in the mass spectrum is given by:m * = m 2 2 /m 1 z 1 /z 2 2 Example: 1,2,3,4-tetrahydrocarbazole (M = 171) looses ethylene and a metastable peak at /171 = is observed;

The fragmentation in EI-MS involves exclusively gas phase unimolecular reactions and is governed by product ion stability. The relative stabilities of different ions are based on the same chemical models that are also applicable in solution: Maintenance of an octet of electrons Localization of charge on the most favourable group/atom Resonance delocalization Absence of unpaired electrons charge delocalization Fragmentation Patterns in EI-MS

Odd- and even-electron molecular and fragment ions Odd + can fragment into [even + + neutral ] or [odd + + neutral] while even + fragments into [even + + neutral] but unlikely into [odd + + neutral ] Exceptions are found for even-electron ions containing particularly week bonds, such as multiple C-Br bonds that undergo successive Br losses, or when particular stable odd-electron ions are formed.

Stevenson’s Rule for retro Diels-Alder and elimination reactions product ion enthalpy governs the dissociation pathway the fragment with the lowest ionization energy will preferentially take the charge the difference in activation energy equals the difference in IE (ionization energy) IE = 9 eV IE = 10 eV more less

Rearrangement versus simple cleavage rearrangements are intrinsically slower processes than simple bond cleavages since they involve conformational changes rearrangements can only compete with bond cleavages if their activation energies and the overall internal ion energies are low more than one new bond can be formed under low-energy conditions (example to the right)

Charge localization The two molecular radical ions shown above differ in internal energy by about 1.2 eV due to their different IEs. The more electropositive N-atom has the lower IE, therefore the higher internal energy, and is more likely to fragment α-cleavage of an oxygen ether and hetero-bond cleavage of the more polarizable and electropositive thio ether

No strict rules apply for mass spectral fragmentation, just as they are not for describing product yields in solution phase reactions. Remote fragmentations are possible and usually occur via a six-centred transition state (see rearrangements). Background noise (minor signals at almost every mass) is caused by ions of high internal energy that undergo random bond cleavage. Ions in which the charged site is formally separated from the radical site are called distonic ions. Other terms Always Remember