TY - JOUR
T1 - Mechanistic insights into heterogeneous methane activation
AU - Latimer, Allegra A.
AU - Aljama, Hassan
AU - Kakekhani, Arvin
AU - Yoo, Jong Suk
AU - Kulkarni, Ambarish
AU - Tsai, Charlie
AU - Garcia-Melchor, Max
AU - Abild-Pedersen, Frank
AU - Nørskov, Jens K.
N1 - Publisher Copyright:
© the Owner Societies 2017.
PY - 2017
Y1 - 2017
N2 - While natural gas is an abundant chemical fuel, its low volumetric energy density has prompted a search for catalysts able to transform methane into more useful chemicals. This search has often been aided through the use of transition state (TS) scaling relationships, which estimate methane activation TS energies as a linear function of a more easily calculated descriptor, such as final state energy, thus avoiding tedious TS energy calculations. It has been shown that methane can be activated via a radical or surface-stabilized pathway, both of which possess a unique TS scaling relationship. Herein, we present a simple model to aid in the prediction of methane activation barriers on heterogeneous catalysts. Analogous to the universal radical TS scaling relationship introduced in a previous publication, we show that a universal TS scaling relationship that transcends catalysts classes also seems to exist for surface-stabilized methane activation if the relevant final state energy is used. We demonstrate that this scaling relationship holds for several reducible and irreducible oxides, promoted metals, and sulfides. By combining the universal scaling relationships for both radical and surface-stabilized methane activation pathways, we show that catalyst reactivity must be considered in addition to catalyst geometry to obtain an accurate estimation for the TS energy. This model can yield fast and accurate predictions of methane activation barriers on a wide range of catalysts, thus accelerating the discovery of more active catalysts for methane conversion.
AB - While natural gas is an abundant chemical fuel, its low volumetric energy density has prompted a search for catalysts able to transform methane into more useful chemicals. This search has often been aided through the use of transition state (TS) scaling relationships, which estimate methane activation TS energies as a linear function of a more easily calculated descriptor, such as final state energy, thus avoiding tedious TS energy calculations. It has been shown that methane can be activated via a radical or surface-stabilized pathway, both of which possess a unique TS scaling relationship. Herein, we present a simple model to aid in the prediction of methane activation barriers on heterogeneous catalysts. Analogous to the universal radical TS scaling relationship introduced in a previous publication, we show that a universal TS scaling relationship that transcends catalysts classes also seems to exist for surface-stabilized methane activation if the relevant final state energy is used. We demonstrate that this scaling relationship holds for several reducible and irreducible oxides, promoted metals, and sulfides. By combining the universal scaling relationships for both radical and surface-stabilized methane activation pathways, we show that catalyst reactivity must be considered in addition to catalyst geometry to obtain an accurate estimation for the TS energy. This model can yield fast and accurate predictions of methane activation barriers on a wide range of catalysts, thus accelerating the discovery of more active catalysts for methane conversion.
UR - http://www.scopus.com/inward/record.url?scp=85011805042&partnerID=8YFLogxK
U2 - 10.1039/c6cp08003k
DO - 10.1039/c6cp08003k
M3 - Article
C2 - 28094377
AN - SCOPUS:85011805042
SN - 1463-9076
VL - 19
SP - 3575
EP - 3581
JO - Physical Chemistry Chemical Physics
JF - Physical Chemistry Chemical Physics
IS - 5
ER -