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We present cryogenic infrared spectra of sodiated β-cyclodextrin [β-CD + Na] + , a common cyclic oligosaccharide, and its main dissociation products upon collision-induced dissociation (CID). We characterize the parent ions using high-resolution ion mobility spectrometry and cryogenic infrared action spectroscopy, while the fragments are characterized by their mass and cryogenic infrared spectra. We observe sodium-cationized fragments that differ in mass by 162 u, corresponding to B n /Z m ions. For the m / z 347 product ion, electronic structure calculations are consistent with formation of the lowest energy 2-ketone B 2 ion structure. For the m / z 509 product ion, both the calculated 2-ketone B 3 and the Z 3 structures show similarities with the experimental spectrum. The theoretical structure most consistent with the spectrum of the m / z 671 ions is a slightly higher energy 2-ketone B 4 structure. Overall, the data suggest a consistent formation mechanism for all the observed fragments. 

We investigate the gas-phase structures and fragmentation chemistry of deprotonated carbohydrate anions using combined tandem mass spectrometry, infrared spectroscopy, regioselective labelling, and theory. Our model system is deprotonated, [lactose-H] − . We computationally characterize the rate-determining barriers to glycosidic bond (C 1 –Z 1 reactions) and cross-ring cleavages, and compare these predictions to our tandem mass spectrometric and infrared spectroscopy data. The glycosidic bond cleavage product data support complex mixtures of anion structures in both the C 1 and Z 1 anion populations. The specific nature of these distributions is predicted to be directly affected by the nature of the anomeric configuration of the precursor anion and the distribution of energies imparted. i.e. , Z 1 anions produced from the β-glucose anomeric form have a differing distribution of product ion structures than do those from the α-glucose anomeric form. The most readily formed Z 1 anions ([1,4-anhydroglucose-H] − structures) are produced from the β-glucose anomers, and do not ring-open and isomerize as the hemiacetal group is no longer present. In contrast the [3,4-anhydroglucose-H] − , Z 1 anion structures, which are most readily produced from α-glucose forms, can ring-open through very low barriers (<25 kJ mol −1 ) to form energetically and entropically favorable aldehyde isomers assigned with a carbonyl stretch at ∼1640 cm −1 . Barriers to interconversion of the pyranose [β-galactose-H] − , C 1 anions to ring-open forms were larger, but still modest (≥51 kJ mol −1 ) consistent with evidence of the presence of both forms in the infrared spectrum. For the cross-ring cleavage 0,2 A 2 anions, ring-opening at the glucose hemiacetal of [lactose-H] − is rate-limiting (>180 (α-), >197 kJ mol −1 (β-anomers)). This finding offers an explanation for the low abundance of these product anions in our tandem mass spectra.