Modulation of the thermodynamic, kinetic, and magnetic properties of the hydrogen monomer on graphene by charge doping

Huang, Liang‐Feng; Ni, Mei; Zhang, Guo Ren; Zhou, Wang-Huai; Li, Yonggang; Zheng, Xiao; Zhang, Zhi

doi:10.1063/1.3624657

Cited by 59 publications

(87 citation statements)

References 71 publications

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“…The electronic state thus induced will correspond to that of a nonmagnetic insulator for large concentrations [1][2][3][4][5], an antiferromagnet for intermediate concentrations [19], or a paramagnet for low concentrations [12]. At room temperature, which for practical applications is the most interesting case, both desorption and diffusion processes are, in principle, active [20][21][22][23][24][25][26][27][28][29][30]. If desorption rates are larger than diffusion ones, the sample will loose H from both sublattices, but at different rates.…”

Section: Introductionmentioning

confidence: 99%

“…This result does not qualitatively depend on the specific values of the migration and desorption barriers. For instance, upon changing the carrier concentration of the bilayer system, which, in turn, changes the magnitude of these barriers [29], we always obtain such temporary distribution of H, only the final fate of the atoms being affected. For hole doping, all atoms eventually form dimers or clusters while for electron doping (or no doping) all atoms eventually desorb.…”

Section: Introductionmentioning

confidence: 99%

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Theoretical study of the dynamics of atomic hydrogen adsorbed on graphene multilayers

et al. 2015

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We present a theoretical study of the dynamics of H atoms adsorbed on graphene bilayers with Bernal stacking. First, through extensive density functional theory calculations, including van der Waals interactions, we obtain the activation barriers involved in the desorption and migration processes of a single H atom. These barriers, along with attempt rates and the energetics of H pairs, are used as input parameters in kinetic Monte Carlo simulations to study the time evolution of an initial random distribution of adsorbed H atoms. The simulations reveal that, at room temperature, H atoms occupy only one sublattice before they completely desorb or form clusters. This sublattice selectivity in the distribution of H atoms may last for sufficiently long periods of time upon lowering the temperature down to 0• C. The final fate of the H atoms, namely, desorption or cluster formation, depends on the actual relative values of the activation barriers which can be tuned by doping. In some cases, a sublattice selectivity can be obtained for periods of time experimentally relevant even at room temperature. This result shows the possibility for observation and applications of the ferromagnetic state associated with such distribution.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Theoretical study of the dynamics of atomic hydrogen adsorbed on graphene multilayers

et al. 2015

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“…As shown in Figure 3a, the largest adsorption energy of the gallium adatom on Ga-doped graphene surface is −0.509 eV, which is only 0.16 eV (absolute value) larger than that on pristine graphene. These results can be explained by the fact that, after replacing the carbon atom, the gallium atom becomes an acceptor and thus easily interacts with the metal gallium [34,35]. As can be seen from Figure 3b, all the adsorption energies of the gallium adatom are reduced when they are adsorbed on N-doped graphene.…”

Section: Adsorption On Doped Graphenementioning

confidence: 54%

“…The results indicate that the incorporation of oxygen impurities makes it harder for the gallium atom to be adsorbed on the graphene, and even physical adsorption becomes very difficult. the gallium atom becomes an acceptor and thus easily interacts with the metal gallium [34,35]. As can be seen from Figure 3b, all the adsorption energies of the gallium adatom are reduced when they are adsorbed on N-doped graphene.…”

Section: Adsorption On Doped Graphenementioning

confidence: 56%

Strain Effects in Gallium Nitride Adsorption on Defective and Doped Graphene: First-Principles Calculations

Yan

Gan

et al. 2018

Crystals

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Transferable, low-stress gallium nitride grown on graphene for flexible lighting or display applications may enable next-generation optoelectronic devices. However, the growth of gallium nitride on graphene is challenging. In this study, the adsorptions of initial nucleation process of gallium nitride on graphene were investigated using first-principles calculations based on density functional theory. The adsorption energies and the role of in-plane strains were calculated for different possible configurations of the adatoms on the surfaces of vacancy defect and doped graphene. Compared with the results of the gallium adatom, adsorption of the nitrogen atom on graphene was found to exhibit greater stability. The calculations reveal that the vacancy defect core enhanced the adsorption stability of the adatom on graphene, whereas the incorporation of oxygen impurity greatly reduced the stable adsorption of the gallium and nitrogen adatoms. Furthermore, the calculations of strain showed that the lattice expansion led to increased stability for all adsorption sites and configuration surfaces, except for the nitrogen adatom adsorbed over the gallium atom in Ga-doped graphene. The study presented in this paper may have important implications in understanding gallium nitride growth on graphene.

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“…32 At this point it is interesting to study the effect of doping on the chemisorption energy. 40 By adding electrons or holes the Fermi energy would move from the Dirac points where the density of states is zero, to energies where the density of states is larger and, eventually, at the van Hove logarithmic singularities, where the density of states is much larger. In Figure 6 we show the calculated density of states at the Fermi as a function of the extra charge.…”

Section: Hydrogen Adsorptionmentioning

confidence: 99%

Selective Hydrogen Adsorption in Graphene Rotated Bilayers

Brihuega

Ynduráin

2017

J. Phys. Chem. B

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The absorption energy of atomic hydrogen at rotated graphene bilayers is studied using ab initio methods based on the density functional theory including van der Waals interactions. We find that, due to the surface corrugation induced by the underneath rotated layer and the perturbation of the electronic density of states near the Fermi energy, the atoms with an almost AA stacking are the preferential ones for hydrogen chemisorption. The adsorption energy difference between different atoms can be as large as 80 meV. In addition, we find that, due to the logarithmic van Hove singularities in the electronic density of states at energies close to the Dirac point, the adsorption energy of either electron or hole doped samples is substantially increased. We also find that the adsorption energy increases with the decrease of the rotated angle between the layers.Finally, the large zero point energy of the C-H bond (∼ 0.3eV ) suggests adsorption and desorption of atomic hydrogen and deuterium should behave differently.

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Modulation of the thermodynamic, kinetic, and magnetic properties of the hydrogen monomer on graphene by charge doping

Cited by 59 publications

References 71 publications

Theoretical study of the dynamics of atomic hydrogen adsorbed on graphene multilayers

Theoretical study of the dynamics of atomic hydrogen adsorbed on graphene multilayers

Strain Effects in Gallium Nitride Adsorption on Defective and Doped Graphene: First-Principles Calculations

Selective Hydrogen Adsorption in Graphene Rotated Bilayers

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