Experimental evidence for competitive NO and OC bond homolysis in gas-phase alkoxyamines

• [M − H]− anions of alkoxyamines are examined by tandem mass spectrometry.
• Collision-induced dissociation yields radical product ions by homolytic cleavage.
• Efficacy of OC and NO homolysis is dependent on alkoxyamine substituents.
• OC homolysis is prevalent in most cases.

The extensive use of alkoxyamines in controlled radical polymerisation and polymer stabilisation is based on rapid cycling between the alkoxyamine (R1R2NOR3) and a stable nitroxyl radical (R1R2NO
• ) via homolysis of the labile OC bond. Competing homolysis of the alkoxyamine NO bond has been predicted to occur for some substituents leading to production of aminyl and alkoxyl radicals. This intrinsic competition between the OC and NO bond homolysis processes has to this point been difficult to probe experimentally. Herein we examine the effect of local molecular structure on the competition between NO and OC bond cleavage in the gas phase by variable energy tandem mass spectrometry in a triple quadrupole mass spectrometer. A suite of cyclic alkoxyamines with remote carboxylic acid moieties (HOOCR1R2NOR3) were synthesised and subjected to negative ion electrospray ionisation to yield [M − H]− anions where the charge is remote from the alkoxyamine moiety. Collision-induced dissociation of these anions yield product ions resulting, almost exclusively, from homolysis of OC and/or NO bonds. The relative efficacy of NO and OC bond homolysis was examined for alkoxyamines incorporating different R3 substituents by varying the potential difference applied to the collision cell, and comparing dissociation thresholds of each product ion channel. For most R3 substituents, product ions from homolysis of the OC bond are observed and product ions resulting from cleavage of the NO bond are minor or absent. A limited number of examples were encountered however, where NO homolysis is a competitive dissociation pathway because the OC bond is stabilised by adjacent heteroatom(s) (e.g. R3 = CH2F). The dissociation threshold energies were compared for different alkoxyamine substituents (R3) and the relative ordering of these experimentally determined energies is shown to correlate with the bond dissociation free energies, calculated by ab initio methods. Understanding the structure-dependent relationship between these rival processes will assist in the design and selection of alkoxyamine motifs that selectively promote the desirable OC homolysis pathway.

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