C-N Bond Formation by Nitrous Oxide Capture

Nitrous oxide (N2O), commonly known as “laughing gas” for its physiological effects, is both a potent greenhouse gas an ozone depleting substance. Indeed, it is a major contributor to climate change, thereby posing a critical concern for contemporary society. Nitrous oxide possesses a warming potential approximatively 300 times that of carbon dioxide and due to its high chemical stability, it persists in the atmosphere for over 100 years. Nitrous oxide is naturally present in the atmosphere as part of the global nitrogen cycle, a vital nutrient cycle for sustainable and biodiverse ecosystems. Since the industrial revolution, this cycle has been disturbed by the excessive use of ammonia (NH3) based fertilizer, intensive agriculture, and fossil fuels combustion, resulting in increased nitrous oxide emissions. It was estimated that nearly half of the global population would rely on ammonia based fertilizers for their food supply at the start of the 21st century, with further increases projected for the coming decades. Consequently, as global ammonia-based fertilizer use continues to rise, global nitrous oxide emissions are projected to increase. This imbalance has already compromised the viability of many ecosystems, leading to widespread biodiversity loss. Urgent measures are required to repurpose nitrous oxide! In this proposed research (N2OTOCARBON), we investigated strategies to capture nitrous oxide by mean of chemical transformations.
The overarching goal of N2OTOCARBON was to develop new reaction methodologies that enable the chemical capture of nitrous oxide for the synthesis of industrially relevant diazo containing compounds.

The specific objectives are as follows:
Objective 1 (O1): Discover new reactivities using anionic nucleophiles with nitrous oxide to access diazotates, a covalent nitrous oxide adduct (Work Package 1 - WP1).
Objective 2 (O2): Explore the stability of diazotates and their reactivity with main group compounds (Work
Package 2 - WP2).
Objective 3 (O3): Explore the reactivity of diazotates and "masked" diazotates to access synthetically versatile organic functional groups (Work Package 3 - WP3).

We developed a new approach to chemically activate and trap nitrous oxide (N2O) intact using bulky potassium phosphanides to form the corresponding diazotate, a covalent nitrous oxide adduct. We synthesized the diazotates from adamantyl- and tert-butyl-substituted phosphanides, isolated and structurally characterized them by X-ray crystallography, revealing distinct bent geometries of the P–N–N–O units. Reactivity studies demonstrated that these phosphinodiazotates are stable under inert conditions, react with Lewis acidic main group compounds such as boranes to form defined adducts, and can convert into phosphinito ligands upon reaction with transition metal complexes, showcasing potential utility in ligand synthesis. In another project, we developed a one-pot methodology for synthesizing azo olefins via N2O-mediated coupling of vinyllithium reagents with Grignard reagents.
This method (soon to be published) enables the preparation of diverse alkenyl-N2-R compounds (R = aryl, alkenyl, alkynyl, alkyl) in good yields, including previously inaccessible alkenyl-N2-alkenyl systems
This work establishes N2O as an efficient nitrogen donor for azo compound synthesis and expands its synthetic utility beyond oxygen-atom transfer chemistry.

The two studies establish covalent capture strategies of nitrous oxide (N2O) using anionic nucleophiles. First, the covalent capture of N2O by phosphanides enabled the isolation and structural characterization of phosphinodiazotate species, providing direct molecular-level insight into N2O activation and revealing new bonding motifs. Second, a one-pot methodology for the synthesis of azo olefins via N2O-mediated coupling of vinyllithium and Grignard reagents delivered diverse alkenyl-N2-R compounds, including previously inaccessible alkenyl-N2-alkenyl systems, in synthetically useful yields, moving beyond its traditional role as an oxygen-atom donor.