Nitrogen dissociation on Fe: Activated, non-activated or both?

The role of dynamics in heterogeneous catalysis: Surface diffusivity and N2 decomposition on Fe(111)

Dynamics has long been recognized to play an important role in heterogeneous catalytic processes. However, until recently, it has been impossible to study their dynamical behavior at industry-relevant temperatures. Using a combination of machine learning potentials and advanced simulation techniques, we investigate the cleavage of the N[Formula: see text] triple bond on the Fe(111) surface. We find that at low temperatures our results agree with the well-established picture. However, if we increase the temperature to reach operando conditions, the surface undergoes a global dynamical change and the step structure of the Fe(111) surface is destabilized. The catalytic sites, traditionally associated with this surface, appear and disappear continuously. Our simulations illuminate the danger of extrapolating low-temperature results to operando conditions and indicate that the catalytic activity can only be inferred from calculations that take dynamics fully into account. More than that, they show that it is the transition to this highly fluctuating interfacial environment that drives the catalytic process.

The 2007 Nobel Prize in Chemistry for surface chemistry: understanding nanoscale phenomena at surfaces

The 2007 Nobel Prize in Chemistry was awarded to Gerhard Ertl for his seminal work in the area of surface science, particularly at the gas-solid interface. Although Ertl began his career at a time when the term "nanotechnology" was not yet known, his contributions to the field have paved the way for many future scientists in this area and led to a deeper understanding of catalysis and other surface-specific processes at the nanoscale. Here, we summarize the scientific developments that guided early progress in surface science, and we explore the major advancements in Ertl's career, including his work on adsorption and oxidation of small molecules on metal surfaces. Significant contributions of other key scientists to this rich area are also presented.

Predicting Catalysis: Understanding Ammonia Synthesis from First-Principles Calculations

Here, we give a full account of a large collaborative effort toward an atomic-scale understanding of modern industrial ammonia production over ruthenium catalysts. We show that overall rates of ammonia production can be determined by applying various levels of theory (including transition state theory with or without tunneling corrections, and quantum dynamics) to a range of relevant elementary reaction steps, such as N(2) dissociation, H(2) dissociation, and hydrogenation of the intermediate reactants. A complete kinetic model based on the most relevant elementary steps can be established for any given point along an industrial reactor, and the kinetic results can be integrated over the catalyst bed to determine the industrial reactor yield. We find that, given the present uncertainties, the rate of ammonia production is well-determined directly from our atomic-scale calculations. Furthermore, our studies provide new insight into several related fields, for instance, gas-phase and electrochemical ammonia synthesis. The success of predicting the outcome of a catalytic reaction from first-principles calculations supports our point of view that, in the future, theory will be a fully integrated tool in the search for the next generation of catalysts.