Mighfar Imam scite author profile

We provide direct evidence that irradiation of a graphene membrane on Ir with low-energy Ar ions induces formation of solid noble-gas nanobubbles. Their size can be controlled by thermal treatment, reaching tens of nanometers laterally and height of 1.5 nm upon annealing at 1080 °C. Ab initio calculations show that Ar nanobubbles are subject to pressures reaching tens of GPa, their formation being driven by minimization of the energy cost of film distortion and loss of adhesion.

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Change of cobalt magnetic anisotropy and spin polarization with alkanethiolates self-assembled monolayers

Campiglio

Breitwieser

Repain

et al. 2015

New J. Phys.

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We demonstrate that the deposition of a self-assembled monolayer of alkanethiolates on a 1 nm thick cobalt ultrathin film grown on Au(111) induces a spin reorientation transition from in-plane to outof-plane magnetization. Using ab initio calculations, we show that a methanethiolate layer changes slightly both the magnetocrystalline and shape anisotropy, both effects almost cancelling each other out for a 1 nm Co film. Finally, the change in hysteresis cycles upon alkanethiolate adsorption could be assigned to a molecular-induced roughening of the Co layer, as shown by STM. In addition, we calculate how a methanethiolate layer modifies the spin density of states of the Co layer and we show that the spin polarization at the Fermi level through the organic layer is reversed as compared to the uncovered Co. These results give new theoretical and experimental insights for the use of thiol-based self-assembled monolayers in spintronic devices.

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Elastic and chemical contributions to the stability of magnetic surface alloys on Ru(0001)

2009

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We have used density functional theory to study the structural stability of surface alloys. Our systems consist of a single pseudomorphic layer of MxN1−x on the Ru(0001) surface, where M = Fe or Co, and N = Pt, Au, Ag, Cd, or Pb. Several of the combinations studied by us display a preference for atomically mixed configurations over phase-segregated forms. We have also performed further ab initio calculations to obtain the parameters describing the elastic interactions between atoms in the alloy layer, including the effective atomic sizes at the surface. We find that while elastic interactions favor alloying for all the systems considered by us, in some cases chemical interactions disfavor atomic mixing. We show that a simple criterion (analogous to the Hume-Rothery first law for bulk alloys) need not necessarily work for strain-stabilized surface alloys, because of the presence of additional elastic contributions to the alloy heat of formation, that will tend to oppose phase segregation.

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SixC1−xO2 alloys: A possible route to stabilize carbon-based silica-like solids?

Aravindh

Arkundato

Barman

et al. 2007

Solid State Communications

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Mighfar Imam

Nanobubbles at GPa Pressure under Graphene

Change of cobalt magnetic anisotropy and spin polarization with alkanethiolates self-assembled monolayers

Elastic and chemical contributions to the stability of magnetic surface alloys on Ru(0001)

SixC1−xO2 alloys: A possible route to stabilize carbon-based silica-like solids?

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