TY - JOUR KW - electronic structure KW - spectroscopy AU - Allan Oliveira AU - Julia Lehman AU - Carl Lineberger AB - We report the photoelectron spectrum of the aminomethoxide anion (H2C(NH2)O–). The electron affinity (EA) of the aminomethoxy radical is determined to be 1.944(1) eV. Transitions to the ground (X̃ 2A″) and first excited (Ã 2A′) electronic states of aminomethoxy are observed, with the term energy measured to be T0(Ã ← X̃) = 0.085(1) eV. A long vibrational progression is observed for the transition to the ground X̃ 2A″ electronic state of aminomethoxy, primarily consisting of OCN bending and HNH wagging vibrations, leading to the assignment of these two fundamental vibrational frequencies of H2C(NH2)O· X̃ 2A″. The gas-phase acidity of aminomethanol is calculated at the G4 level of theory to be ΔacidH0Ko = 374.0 kcal mol–1, which, when combined with the experimental EA of aminomethoxy in a thermochemical cycle, provides a determination of the O–H bond dissociation energy, D0(H2C(NH2)O–H) as 106(2) kcal mol–1. Comparisons of the EAs and T0(Ã ← X̃) for the aminomethoxy, methoxy, ethoxy, and hydroxymethoxy radicals provides insight into how the substituent group affects the electronic structure of singly substituted alkoxy radicals. BT - The Journal of Physical Chemistry A DA - 2018-05 DO - 10.1021/acs.jpca.8b02921 N2 - We report the photoelectron spectrum of the aminomethoxide anion (H2C(NH2)O–). The electron affinity (EA) of the aminomethoxy radical is determined to be 1.944(1) eV. Transitions to the ground (X̃ 2A″) and first excited (Ã 2A′) electronic states of aminomethoxy are observed, with the term energy measured to be T0(Ã ← X̃) = 0.085(1) eV. A long vibrational progression is observed for the transition to the ground X̃ 2A″ electronic state of aminomethoxy, primarily consisting of OCN bending and HNH wagging vibrations, leading to the assignment of these two fundamental vibrational frequencies of H2C(NH2)O· X̃ 2A″. The gas-phase acidity of aminomethanol is calculated at the G4 level of theory to be ΔacidH0Ko = 374.0 kcal mol–1, which, when combined with the experimental EA of aminomethoxy in a thermochemical cycle, provides a determination of the O–H bond dissociation energy, D0(H2C(NH2)O–H) as 106(2) kcal mol–1. Comparisons of the EAs and T0(Ã ← X̃) for the aminomethoxy, methoxy, ethoxy, and hydroxymethoxy radicals provides insight into how the substituent group affects the electronic structure of singly substituted alkoxy radicals. PY - 2018 SP - 4954 EP - 4962 T2 - The Journal of Physical Chemistry A TI - Photoelectron Spectroscopy of the Aminomethoxide Anion, H2C(NH2)O- UR - https://pubs.acs.org/doi/pdf/10.1021/acs.jpca.8b02921 VL - 122 SN - 1089-5639 ER -