Reactions of 1,5-diketones with HO open an ozone-free approach to ozonides. Bridged ozonides are formed readily at room temperature in the presence of strong Brønsted or Lewis acids such as HSO, p-TsOH, HBF, or BF·EtO. The expected bridged tetraoxanes, the products of double HO addition, were not detected. This procedure is readily scalable to produce gram quantities of the ozonides. Bridged ozonides are stable and can be useful as building blocks for bioconjugation and further synthetic transformations. Although less stabilized by anomeric interactions than bis-peroxides, ozonides have an intrinsic advantage of having only one weak O-O bond. The role of the synergetic framework of anomeric effects in bis-peroxides is to overcome this intrinsic disadvantage. As the computational data have shown, this is only possible when all anomeric effects in bis-peroxides are activated to their fullest degree. Consequently, the cyclization selectivity is determined by the length of the bridge between the two carbonyl groups of the diketone. The generally large thermodynamic preference for the formation of cyclic bis-peroxides disappears when 1,5-diketones are used as the bis-cyclization precursors. Stereoelectronic analysis suggests that the reason for the bis-peroxide absence is the selective deactivation of anomeric effects in a [3.2.2]tetraoxanonane skeleton by a structural distortion imposed on the tetraoxacyclohexane subunit by the three-carbon bridge.
Stable
bridged azaozonides can be selectively assembled via a catalyst-free
three-component condensation of 1,5-diketones, hydrogen peroxide,
and an NH-group source such as aqueous ammonia or ammonium salts.
This procedure is scalable and can produce gram quantities of bicyclic
stereochemically rich heterocycles. The new azaozonides are thermally
stable and can be stored at room temperature for several months without
decomposition and for at least 1 year at −10 °C. The chemical
stability of azaozonides was explored for their subsequent selective
transformations including the first example of an aminoperoxide rearrangement
that preserves the peroxide group. The amino group in aminoperoxides
has remarkably low nucleophilicity and does not participate in the
usual amine alkylation and acylation reactions. These observations
and the 15 pK
a units decrease in basicity
in comparison with a typical dialkyl amine are attributed to the strong
hyperconjugative nN→σ*C–O interaction with the two antiperiplanar C–O bonds. Due to
the weakness of the complementary nO→σ*C–N donation from the peroxide oxygens (a consequence
of “inverse α-effect”), this interaction depletes
electron density from the NH moiety, protects it from oxidation, and
makes it similar in properties to an amide.
The catalyst H3+xPMo12−x+6Mox+5O40 supported on SiO2 was developed for peroxidation of 1,3‐ and 1,5‐diketones with hydrogen peroxide with the formation of bridged 1,2,4,5‐tetraoxanes and bridged 1,2,4‐trioxolanes (ozonides) with high yield based on isolated products (up to 86 and 90 %, respectively) under heterogeneous conditions. Synthesis of peroxides under heterogeneous conditions is a rare process and represents a challenge for this field of chemistry, because peroxides tend to decompose on the surface of a catalyst . A new class of antifungal agents for crop protection, that is, cyclic peroxides: bridged 1,2,4,5‐tetraoxanes and bridged ozonides, was discovered. Some ozonides and tetraoxanes exhibit a very high antifungal activity and are superior to commercial fungicides, such as Triadimefon and Kresoxim‐methyl. It is important to note that none of the fungicides used in agricultural chemistry contains a peroxide fragment.
We
describe an efficient one-pot procedure that “folds”
acyclic triketones into structurally complex, pharmaceutically relevant
tricyclic systems that combine high oxygen content with unusual stability.
In particular, β,γ′-triketones are converted into
three-dimensional polycyclic peroxides in the presence of H2O2 under acid
catalysis. These transformations are fueled by stereoelectronic frustration
of H2O2, the parent peroxide, where the lone
pairs of oxygen are not involved in strongly stabilizing orbital interactions.
Computational analysis reveals how this frustration is relieved in
the tricyclic peroxide products, where strongly stabilizing anomeric n
O→σC–O
* interactions are activated. The calculated
potential energy surfaces for these transformations combine labile,
dynamically formed cationic species with deeply stabilized intermediate
structures that correspond to the introduction of one, two, or three
peroxide moieties. Paradoxically, as the thermodynamic stability of
the peroxide products increases along this reaction cascade, the kinetic
barriers for their formation increase as well. This feature of the
reaction potential energy surface, which allows separation of mono-
and bis-peroxide tricyclic products, also explains why formation of
the most stable tris-peroxide is the least kinetically viable and
is not observed experimentally. Such unique behavior can be explained
through the “inverse α-effect”, a new stereoelectronic
phenomenon with many conceptual implications for the development of
organic functional group chemistry.
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