Abstract
Infrared photodissociation (IR-PD) spectra of iron cluster dinitrogen adsorbate complexes [Fen(N2)m]+ for n = 8-20 reveal slightly redshifted IR active bands in the region of 2200-2340 cm-1. These bands mostly relate to stretching vibrations of end-on coordinated N2 chromophores, a μ1,end end-on binding motif. Density Functional Theory (DFT) modeling and detailed analysis of n = 13 complexes are consistent with an icosahedral Fe13 + core structure. The first adsorbate shell closure at (n,m) = (13,12)-as recognized by the accompanying paper on the kinetics of N2 uptake by cationic iron clusters-comes with extensive IR-PD band broadening resulting from enhanced couplings among adjacent N2 adsorbates. DFT modeling predicts spin quenching by N2 adsorption as evidenced by the shift of the computed spin minima among possible spin states (spin valleys). The IR-PD spectrum of (17,1) surprisingly reveals an absence of any structure but efficient non-resonant fragmentation, which might indicate some weakly bound (roaming) N2 adsorbate. The multiple and broad bands of (17,m) for all other cases than (17,1) and (17,7) indicate a high degree of variation in N2 binding motifs and couplings. In contrast, the (17,7) spectrum of six sharp bands suggests pairwise equivalent N2 adsorbates. The IR-PD spectra of (18,m) reveal additional features in the 2120-2200 cm-1 region, which we associate with a μ1,side side-on motif. Some additional features in the (18,m) spectra at high N2 loads indicate a μ1,tilt tilted end-on adsorption motif.
Highlights
The interaction of small molecules such as NO, N2, and H2 with transition metals (TM) is an early elementary step in heterogeneous catalysis.1-6 TM cations7-9 and TM clusters10-14 have served as model systems to mimic such catalysts and related elementary processes
Except [Fe17(N2)1]+, show at least one IR active band in the investigated region, and this band is most likely associated with stretching vibrations of end-on coordinated N2 chromophores
We find some evidence for such structures by our DFT modelling (Fig. 6), and the modelled vibrations come close to the experimental Infrared Photodissociation (IR-PD) spectrum (Fig. 7)
Summary
The interaction of small molecules such as NO, N2, and H2 with transition metals (TM) is an early elementary step in heterogeneous catalysis. TM cations and TM clusters have served as model systems to mimic such catalysts and related elementary processes. With the tandem cryo ion trap instrument at the Technische Universität Kaiserslautern (TUK) laboratory, we are able to conduct Infrared Photon Dissociation (IR-PD) spectroscopy experiments at temperatures down to 11 K as well as adsorption and reaction kinetics studies With this combination of methods, we were able to study the cluster-adsorbate-interaction of various TM clusters; e.g., for Nin+ clusters, we established a concept of size-dependent rough and smooth cluster surfaces.. We gain insights into coordination motifs and interactions of N2 adsorbates, and we receive some decisive support from our concomitant DFT modelling at the level of hybrid DFT functionals These methods are not applied in the cases of larger clusters
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