The stability of the (100) MoS2 surface has been studied using periodic DFT calculations taking into account
various parameters such as the temperature and the partial pressure ratios of H2 and H2S present in the surrounding atmosphere. It appears that the sulfur coverage of the surface is strongly dependent on the H2/H2S
ratio and that under working conditions, the most stable surface does not contain any coordinately unsaturated
sites (CUS). Direct comparisons with experimental literature data such as EXAFS or TPR measurements
show a good agreement between calculations and these experiments. The second part of the study deals with
the behavior of hydrogen on the surfaces. The endothermic dissociation always leads to Mo−H and S−H
groups. This implies that hydrogen is not stable on the MoS2 surface unless at very high pressure or very low
temperature. Furthermore, H2 dissociation on the surface will not lead to the formation of CUS.
Both cubic and hexagonal phases of ZnS are modeled using interatomic potential based simulations and density functional theory. A new set of potential parameters is derived, showing improved behavior compared with the previous ones. Results obtained with this new potential model show very good agreement with those obtained with density functional theory calculations and with experimental results when available. To calculate crystal morphologies for both phases, we perform an extensive study of the surface energies. In the cubic phase we take into account all the nonpolar surfaces with Miller indexes 0, 1, 2, 3, and 4, and all the polar surfaces with indexes 0, 1, and 2. The nonpolar (110) surface is the most stable surface in this phase and entirely dominates the crystal morphology, which is a dodecahedron showing only the (110) surface and its equivalents. In the hexagonal phase we find that it is necessary to take into account polar surfaces to obtain the crystal morphology, which has a highly anisotropic, cylindrical-like shape, with nonpolar surfaces on the sides and polar surfaces closing the cylinder.
Hydrogen adsorption on Mo[bond]S, Co[bond]Mo[bond]S, and Ni[bond]Mo[bond]S (10 1 macro 0) surfaces has been modeled by means of periodic DFT calculations taking into account the gaseous surrounding of these catalysts in working conditions. On the stable Mo[bond]S surface, only six-fold coordinated Mo cations are present, whereas substitution by Co or Ni leads to the creation of stable coordinatively unsaturated sites. On the stable MoS(2) surface, hydrogen dissociation is always endothermic and presents a high activation barrier. On Co[bond]Mo[bond]S surfaces, the ability to dissociate H(2) depends on the nature of the metal atom and the sulfur coordination environment. As an adsorption center, Co strongly favors molecular hydrogen activation as compared to the Mo atoms. Co also increases the ability of its sulfur atom ligands to bind hydrogen. Investigation of surface acidity using ammonia as a probe molecule confirms the crucial role of sulfur basicity on hydrogen activation on these surfaces. As a result, Co[bond]Mo[bond]S surfaces present Co[bond]S sites for which the dissociation of hydrogen is exothermic and weakly activated. On Ni[bond]Mo[bond]S surfaces, Ni[bond]S pairs are not stable and do not provide for an efficient way for hydrogen activation. These theoretical results are in good agreement with recent experimental studies of H(2)[bond]D(2) exchange reactions.
We present a comprehensive comparison of through-space heteronuclear correlation techniques for solid state NMR, combining indirect detection and single-channel recoupling method. These techniques, named D-HMQC and D-HSQC, do not suffer from dipolar truncation and can be employed to correlate quadrupolar nuclei with spin-1/2 nuclei. The heteronuclear dipolar couplings are restored under magic-angle spinning by applying supercycled symmetry-based pulse sequences (SR412) or simultaneous frequency and amplitude modulation (SFAM). The average Hamiltonian theory (AHT) of these recoupling methods is developed. These results are applied to analyze the performances of D-HMQC and D-HSQC sequences. It is shown that, whatever the magnitude of spin interations, D-HMQC experiment offers larger efficiency and higher robustness than D-HSQC. Furthermore, the spectral resolution in both dimensions of proton detected two-dimensional D-HMQC and D-HSQC spectra can be enhanced by applying recently introduced symmetry-based homonuclear dipolar decoupling schemes that cause a z-rotation of the spins. This is demonstrated by 1H-13C and 1H-23Na correlation experiments on l-histidine and NaH2PO4, respectively. The two-dimensional heteronuclear 1H-23Na correlation spectrum yields the assignment of 23Na resonances of NaH2PO4. This assignment is corroborated by first-principles calculations.
We investigate theoretically, by quantum DFT calculations, the adsorption of H2 molecules on the [100]
MoS2 surfaces, considering various edge sulfur stoichiometries. Depending on the nature of the gas phase,
the adsorption energies vary from strongly positive values to strongly negative ones. Using these energies,
we have constructed a thermodynamic diagram, which gives the stoichiometry of the edges and the nature of
the adsorbed hydrogen atoms as a function of the total pressure and of the P
H
2
S/P
H
2
partial pressure ratio and
determines the best conditions to examine the S−H groups using spectroscopic techniques.
Experimental IR spectra of carbon monoxide adsorbed on a series of Mo/Al2O3, CoMo/Al2O3, and NiMo/Al2O3 sulfided catalysts have been compared to ab initio DFT calculations of CO adsorption on CoMo and NiMo model surfaces. This approach allows the main IR features of CO adsorbed on the sulfide phase to be assigned with an uncertainty of 15 cm(-1). On the CoMo system, the band at 2070 cm(-1) is specific of the promotion by Co and is assigned to CO interacting either with a Co atom or with a Mo atom adjacent to a Co atom. On the NiMo system, CO adsorption on Ni centers of the promoted phase leads to a high-wavenumber band at approximately 2120 cm(-1) that strongly overlaps the band at 2110 cm(-1) characteristic of nonpromoted Mo sites. For NiMo and CoMo catalysts, broad shoulders at low wave numbers (below 2060 cm(-1)) are characteristic of Mo centers adjacent to promoter atoms, indicating a partial decoration of the MoS2 edges by the promoter.
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