Sarah Raby-Buck scite author profile

²

,

Ingram

³

et al. 2022

The use of temperature-controlled mechanochemistry to enable the mechanochemical nickel-catalyzed Suzuki-Miyaura coupling is herein described. Transitioning from a capricious room-temperature protocol, through to a heated, PID-controlled programmable jar heater manifold was required to deliver an efficient method for the coupling of aryl sulfamates (derived from ubiquitous phenols) and aryl boronic acid species. Furthermore, this process is conducted using a base-metal nickel catalyst, in the absence of bulk solvent, and in the absence of air/moisture sensitive reaction set-ups. This methodology is showcased through translation to large-scale twin-screw extrusion methodology enabling 200-fold scale increase, producing decagram quantities of CÀ C coupled material.

Mechanochemical techniques for the activation and use of zero-valent metals in synthesis

Jones

¹

,

Leitch

²

,

³

et al. 2022

Activating raw, zero-valent metals is an essential capability for chemical processes, including synthesis and catalysis. In recent years there has been the discovery and growing intensity in the use of mechanical action, through the utility of ball-mills, to facilitate the activation of zero-valent metals.The complexity of the synthetic reaction systems in which these processing techniques can be used has now reached a tipping-point, where, amongst others, cross-electrophile coupling, radical reactions and new modes of zero-valent reactivity have been demonstrated. In addition, the technique of ballmilling is synonymous with solvent minimisation for the reaction component of a synthetic process.In this review we demonstrate that together, these developments paint an intriguing picture where the combination of the technique of ball-milling and chemical synthesis mediated by zero-valent metals could deliver a sustainable platform for chemical synthesis, catalysis and new reaction discovery for the future.

Temperature‐Controlled Mechanochemistry for the Nickel‐Catalyzed Suzuki–Miyaura‐Type Coupling of Aryl Sulfamates via Ball Milling and Twin‐Screw Extrusion.**

Bolt

¹

,

²

,

Ingram

³

et al. 2022

The use of temperature-controlled mechanochemistry to enable the mechanochemical nickel-catalyzed Suzuki-Miyaura coupling is herein described. Transitioning from a capricious room-temperature protocol, through to a heated, PID-controlled programmable jar heater manifold was required to deliver an efficient method for the coupling of aryl sulfamates (derived from ubiquitous phenols) and aryl boronic acid species. Furthermore, this process is conducted using a base-metal nickel catalyst, in the absence of bulk solvent, and in the absence of air/moisture sensitive reaction set-ups. This methodology is showcased through translation to large-scale twin-screw extrusion methodology enabling 200-fold scale increase, producing decagram quantities of CÀ C coupled material.

Temperature-Controlled Mechanochemistry for the Nickel-Catalyzed Suzuki-Miyaura-Type Coupling of Aryl Sulfamates via Ball Milling and Twin-Screw Extrusion

Bolt

¹

,

²

,

Ingram

³

et al. 2022

Preprint

0

The use of temperature-controlled mechanochemistry to enable the mechanochemical nickel-catalyzed Suzuki-Miyaura coupling is herein described. Transitioning from a capricious room-temperature protocol, through to a heated, PID-controlled programmable jar heater manifold was required to deliver an efficient method for the coupling of aryl sulfamates (derived from ubiquitous phenols) and aryl boronic acid species. Furthermore, this process is conducted using a base-metal nickel catalyst, in the absence of bulk solvent, and in the absence of air/moisture sensitive reaction set-ups. This methodology is showcased through translation to large-scale twin-screw extrusion methodology enabling 200-fold scale increase, producing decagram quantities of C-C coupled material.