TY - JOUR
T1 - Optimal catalyst curves: Connecting density functional theory calculations with industrial reactor design and catalyst selection
AU - Jacobsen, C.J.H.
AU - Dahl, Søren
AU - Boisen, A.
AU - Clausen, B.S.
AU - Topsoe, H.
AU - Logadottir, Ashildur
AU - Nørskov, Jens Kehlet
PY - 2002
Y1 - 2002
N2 - For ammonia synthesis catalysts a volcano-type relationship has been found experimentally. We demonstrate that by combining density functional theory calculations with a microkinetic model the position of the maximum of the volcano curve is sensitive to the reaction conditions. The catalytic ammonia synthesis activity, to a first approximation, is a function only of the binding energy of nitrogen to the catalyst. Therefore, it is possible to evaluate which nitrogen binding energy is optimal under given reaction conditions. This leads to the concept of optimal catalyst curves, which illustrate the nitrogen binding energies of the optimal catalysts at different temperatures, pressures, and synthesis gas compositions. Using this concept together with the ability to prepare catalysts with desired binding energies it is possible to optimize the ammonia process. In this way a link between first-principle quantum mechanical calculations of gas-surface interactions, reactor design, and catalyst selection has been established for the first time.
AB - For ammonia synthesis catalysts a volcano-type relationship has been found experimentally. We demonstrate that by combining density functional theory calculations with a microkinetic model the position of the maximum of the volcano curve is sensitive to the reaction conditions. The catalytic ammonia synthesis activity, to a first approximation, is a function only of the binding energy of nitrogen to the catalyst. Therefore, it is possible to evaluate which nitrogen binding energy is optimal under given reaction conditions. This leads to the concept of optimal catalyst curves, which illustrate the nitrogen binding energies of the optimal catalysts at different temperatures, pressures, and synthesis gas compositions. Using this concept together with the ability to prepare catalysts with desired binding energies it is possible to optimize the ammonia process. In this way a link between first-principle quantum mechanical calculations of gas-surface interactions, reactor design, and catalyst selection has been established for the first time.
M3 - Journal article
SN - 0021-9517
VL - 205
SP - 382
EP - 387
JO - Journal of Catalysis
JF - Journal of Catalysis
IS - 2
ER -