Heterogeneous Catalysts. Группа авторов

Heterogeneous Catalysts - Группа авторов


Скачать книгу
an H2 molecule by breaking the hydrogen–hydrogen bond, the active site must be able to transfer enough electron density into antibonding orbital of H2. Clusters offer unprecedented opportunities to fine‐tune the electronic nature of the active site (and hence its reactivity) by choosing a specific cluster with an appropriate type and number of atoms. Clusters are often called “superatoms,” with the notion that a periodic table can be built up in the third dimension whereby the energy levels of the cluster are altered by changing the number of atoms (of the same element) in the cluster. At the other extreme (Figure 5.1, right) are cases of the bulk metal lattices or large NPs, with electronic properties described by band theory. The number of atoms in such systems is huge (think of 1 mol, 6.022 × 1023 atoms), and hence number, and energy density, of MO‐like orbitals is also huge, making gaps between adjacent orbitals smaller than the intrinsic uncertainties of their energies. Hence the energy levels form continuous “bands” that are allowed to be occupied by electrons (cf. forbidden “gaps” between these bands). At 0 K, electrons in the bulk‐like system occupy the lowest possible energy bands to an upper level called the Fermi level. If the Fermi level lies below the top of a partially occupied by electron band, under ambient conditions, a Maxwell–Boltzmann distribution of electrons will prevail with respect to the energies and mobility of the electrons of the system, yielding a conductor.

      Let us now traverse from the extreme of the bulk metal back to clusters on the example of gold. As gold metal particles become nanosized, new characteristics emerge, such as unique optical properties due to the surface plasmon resonance enabled by the nano‐confinement of the shared electrons. Upon reaching size of ∼3 nm for Au particles on titania [2] or between Au246 and Au279 for Au clusters decorated with thiol ligands (‐SR) [3], the continuous bands typical of metals break up due to these systems being composed of small enough number of atoms. The energy differences between at least some orbitals within the former continuous band become significant, leading to appearance of the band gaps and onset of the semiconductor behavior. In the case of Au NPs on TiO2, such a transition coincides with emergence of superior catalytic activity in CO oxidation [2]. The size of metal particles at which such a transition occurs could be assigned as the upper limit of metal cluster sizes, enabling differentiation of clusters from larger NPs based on the electronic structures of each class.

Illustration of selecting specific cluster species using quadrupole for deposition on substrate followed by model catalytic studies and characterization.

      Source: Reprinted with permission from Vajda and White [4]. Copyright 2015, American Chemical Society. (See online version for color figure).

Size‐dependent overall CO oxidation reactivity of gold clusters, Aun, supported on defect‐rich MgO(100) films, expressed as the number of CO2 molecules per cluster.

      Source: Reprinted with permission from Sanchez et al. [8]. Copyright 1999, American Chemical Society.


Скачать книгу