Density functional theory calculations of the hydrazine decomposition mechanism on the planar and stepped Cu(111) surfaces

Tafreshi, Saeedeh Sarabadani; Roldan, Alberto; Leeuw, Nora H. de

doi:10.1039/c5cp03204k

Cited by 39 publications

(20 citation statements)

References 63 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…44 Thus, the Ni located at the vertex of the cluster could be a source of electrons for an eventual reaction with electron receptor molecules approaching the cluster from the gas phase. 50 Analysing the electron density difference between the cluster and the surface (Fig. 3), we have conrmed a charge accumulation between the Ni atoms directly bonded to the surface and the surface atoms; there is no charge relocation between the top Ni atom which remains fully metallic.…”

Section: Resultsmentioning

confidence: 98%

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study

2018

Self Cite

View full text Add to dashboard Cite

The performance of supported metal catalysts, such as nickel nanoparticles decorating yttria-stabilized zirconia (YSZ), depends on their microstructure and the metal-support interface. Here, we have used spin polarized density functional theory (DFT) to evaluate different Ni cluster geometries and determined the electronic structure of the most stable configurations. We have described the interaction of Nin (n = 1-10) clusters supported on the cubic ZrO2(111) and YSZ(111) surfaces, which show a preference for pyramidal shapes rather than flat structures wetting the surface. The interfacial interaction is characterized by charge transfer from the cluster to the surface. We also show how yttrium, present in YSZ, affects the Ni-Ni interaction. Through analysing the difference between the cohesive energy and the clustering energy, we show the preference of Ni-Ni bond formation over Ni-surface interaction; this energy difference decreases with the increase of the Nin cluster size. From the evaluation of the Ni atomic hopping rates on YSZ, we have demonstrated that under different temperature conditions, Ni atoms aggregate with other atoms and clusters, which affects the cluster size stability.

show abstract

Section: Resultsmentioning

confidence: 98%

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study

2018

Self Cite

View full text Add to dashboard Cite

show abstract

“…We did not observe, however, a loss of the total N1s peak intensity, which suggests that the reaction product is still adsorbed on the surface. It is most probably caused by the fact that NH 2 in its less stable monomeric (amidogen) and more stable dimeric (hydrazine) forms are known to adsorb strongly to the Cu surfaces …”

Section: Figurementioning

confidence: 89%

“…It is most probably caused by the fact that NH 2 in its less stable monomeric (amidogen) and more stable dimeric (hydrazine) forms are known to adsorb strongly to the Cu surfaces. [27,28] The presence of the Cl-superstructure has a remarkably different influence on the chemical properties of Cu(001). The BEs of both N1s peaks and the C1s peak originating from 2HTPP after its cold-deposition (T = 100 K) on Cl/Cu (Figure 2c,d) are significantly lower than the respective BEs on N/Cu (Figure 2a,b) or on other substrates including Au(111), Ag(111), Cu (001) and O/Cu(001) [23,26,29] and amount to 398.9 eV, 396.8 eV and 283.7 eV for pyrrolic N1s, iminic N1s and C1s, respectively.…”

mentioning

confidence: 99%

Probing the Reactivity of Functionalized Surfaces by Porphyrin Metalation

et al. 2016

View full text Add to dashboard Cite

The presence of N‐ and Cl‐induced superstructures is shown to drastically alter the physicochemical properties of the Cu(001) substrate. We present coherent evidence that N‐ and Cl‐c(2x2) superstructures on Cu(001) decisively impact the metalation reaction of 5,10,15,20‐tetraphenylporphyrin (2HTPP) as well as the on‐surface diffusion and assembly of this molecule. The N superstructure facilitates the metalation reaction and self‐assembled molecular domains of CuTPP are formed at room temperature (RT). In contrast, the Cl superstructure completely inhibits the self‐metalation reaction requiring metal atoms to be deposited from the top and causes 2HTPP to assemble into small clusters. A spectro‐microscopy correlation approach combining X‐ray Photoelectron Spectroscopy (XPS), Ultraviolet Photoelectron Spectroscopy (UPS), Low Energy Electron Diffraction (LEED) and Scanning Tunneling Microscopy (STM) has been utilized in this study.

show abstract

“…Density functional theory (DFT) is commonly used to determine the energy pro le along the reaction pathway that will be employed in the micro-kinetic modelling. 26,27 We have successfully investigated the dissociative adsorption of hydrazine (N2H4) on the planar and stepped Cu(111) surfaces by rst-principles calcula-tions, 28 where the thermodynamic and kinetic potential energy surface (PES) showed that intermolecular dehydrogenation of hydrazine to produce NH3 and N2 is the favoured route among the explored reaction network. 28 Based on the identi ed mechanism, we have established a micro-kinetic model to simulate a batch reactor where hydrazine is in contact with the planar Cu(111) surface, using 52 elementary reactions including adsorption, desorption, and reactions on the surface.…”

Section: Introductionmentioning

confidence: 99%

“…26,27 We have successfully investigated the dissociative adsorption of hydrazine (N2H4) on the planar and stepped Cu(111) surfaces by rst-principles calcula-tions, 28 where the thermodynamic and kinetic potential energy surface (PES) showed that intermolecular dehydrogenation of hydrazine to produce NH3 and N2 is the favoured route among the explored reaction network. 28 Based on the identi ed mechanism, we have established a micro-kinetic model to simulate a batch reactor where hydrazine is in contact with the planar Cu(111) surface, using 52 elementary reactions including adsorption, desorption, and reactions on the surface. We have evaluated the eff ects of temperature, initial N2H4 coverage and heating rate on a temperature-programmed reaction (TPR), as well as the selectivity towards the formation of NH3, N2, and H2, resulting in an excellent agreement with the experimental results.…”

Section: Introductionmentioning

confidence: 99%

Micro-kinetic simulations of the catalytic decomposition of hydrazine on the Cu(111) surface

2017

Self Cite

View full text Add to dashboard Cite

Hydrazine (NH) is produced at industrial scale from the partial oxidation of ammonia or urea. The hydrogen content (12.5 wt%) and price of hydrazine make it a good source of hydrogen fuel, which is also easily transportable in the hydrate form, thus enabling the production of Hin situ. NH is currently used as a monopropellant thruster to control and adjust the orbits and altitudes of spacecrafts and satellites; with similar procedures applicable in new carbon-free technologies for power generators, e.g. proton-exchange membrane fuel cells. The NH decomposition is usually catalysed by the expensive Ir/AlO material, but a more affordable catalyst is needed to scale-up the process whilst retaining reaction control. Using a complementary range of computational tools, including newly developed micro-kinetic simulations, we have derived and analysed the NH decomposition mechanism on the Cu(111) surface, where the energetic terms of all states have been corrected by entropic terms. The simulated temperature-programmed reactions have shown how the pre-adsorbed NH coverage and heating rate affect the evolution of products, including NH, N and H. The batch reactor simulations have revealed that for the scenario of an ideal Cu terrace, a slow but constant production of H occurs, 5.4% at a temperature of 350 K, while the discharged NH can be recycled into NH. These results show that Cu(111) is not suitable for hydrogen production from hydrazine. However, real catalysts are multi-faceted and present defects, where previous work has shown a more favourable NH decomposition mechanism, and, perhaps, the decomposition of NH improves the production of hydrogen. As such, further investigation is needed to develop a general picture.

show abstract

Density functional theory calculations of the hydrazine decomposition mechanism on the planar and stepped Cu(111) surfaces

Cited by 39 publications

References 63 publications

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study

Probing the Reactivity of Functionalized Surfaces by Porphyrin Metalation

Micro-kinetic simulations of the catalytic decomposition of hydrazine on the Cu(111) surface

Contact Info

Product

Resources

About

Density functional theory calculations of the hydrazine decomposition mechanism on the planar and stepped Cu(111) surfaces

Cited by 39 publications

References 63 publications

Stability and mobility of supported Nin (n = 1–10) clusters on ZrO2(111) and YSZ(111) surfaces: a density functional theory study

Stability and mobility of supported Nin (n = 1–10) clusters on ZrO2(111) and YSZ(111) surfaces: a density functional theory study

Probing the Reactivity of Functionalized Surfaces by Porphyrin Metalation

Micro-kinetic simulations of the catalytic decomposition of hydrazine on the Cu(111) surface

Contact Info

Product

Resources

About

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study

Stability and mobility of supported Ni_n (n = 1–10) clusters on ZrO₂(111) and YSZ(111) surfaces: a density functional theory study