Prediction of a low-temperature N(2) dissociation catalyst exploiting near-IR–to–visible light nanoplasmonics

Despite more than a century of advances in catalyst and production plant design, the Haber-Bosch process for industrial ammonia (NH(3)) synthesis still requires energy-intensive high temperatures and pressures. We propose taking advantage of sunlight conversion into surface plasmon resonances in Au nanoparticles to enhance the rate of the N(2) dissociation reaction, which is the bottleneck in NH(3) production. We predict that this can be achieved through Mo doping of the Au surface based on embedded multireference correlated wave function calculations. The Au component serves as a light-harvesting antenna funneling energy onto the Mo active site, whereby excited-state channels (requiring 1.4 to 1.45 eV, near-infrared–to–visible plasmon resonances) may be accessed. This effectively lowers the energy barriers to 0.44 to 0.77 eV/N(2) (43 to 74 kJ/mol N(2)) from 3.5 eV/N(2) (335 kJ/mol N(2)) in the ground state. The overall process requires three successive surface excitation events, which could be facilitated by amplified resonance energy transfer due to plasmon local field enhancement.