79 research outputs found
Formation and stability of a two-dimensional nickel silicide on Ni (111) an Auger, LEED, STM, and high-resolution photoemission Study
Using low energy electron diffraction (LEED), Auger electron spectroscopy
(AES), scanning tunnelling microscopy (STM) and high resolution photo-electron
spectroscopy (HR-PES) techniques we have studied the annealing effect of one
silicon monolayer deposited at room temperature onto a Ni (111) substrate. The
variations of the Si surface concentration, recorded by AES at 300{\deg}C and
400{\deg}C, show at the beginning a rapid Si decreasing followed by a slowing
down up to a plateau equivalent to about 1/3 silicon monolayer. STM images and
LEED patterns, both recorded at room temperature just after annealing, reveal
the formation of an ordered hexagonal superstructure(rot3xrot3)R30{\deg}-type.
From these observations and from a quantitative analysis of HR-PES data,
recorded before and after annealing, we propose that the (rot3 x
rot3)R30{\deg}superstructure corresponds to a two dimensional (2D) Ni2Si
surface silicide.Comment: Journal Physical Review B (2012
Evidence of silicene in honeycomb structures of silicon on Ag(111)
In the search for evidence of silicene, a two-dimensional honeycomb lattice
of silicon, it is important to obtain a complete picture for the evolution of
Si structures on Ag(111), which is believed to be the most suitable substrate
for growth of silicene so far. In this work we report the finding and evolution
of several monolayer superstructures of silicon on Ag(111) depending on the
coverage and temperature. Combined with first-principles calculations, the
detailed structures of these phases have been illuminated. These structure were
found to share common building blocks of silicon rings, and they evolve from a
fragment of silicene to a complete monolayer silicene and multilayer silicene.
Our results elucidate how silicene formes on Ag(111) surface and provide
methods to synthesize high-quality and large-scale silicene.Comment: 6 pages, 4 figure
Phosphorene: Fabrication, Properties and Applications
Phosphorene, the single- or few-layer form of black phosphorus, was recently
rediscovered as a twodimensional layered material holding great promise for
applications in electronics and optoelectronics. Research into its fundamental
properties and device applications has since seen exponential growth. In this
Perspective, we review recent progress in phosphorene research, touching upon
topics on fabrication, properties, and applications; we also discuss challenges
and future research directions. We highlight the intrinsically anisotropic
electronic, transport, optoelectronic, thermoelectric, and mechanical
properties of phosphorene resulting from its puckered structure in contrast to
those of graphene and transition-metal dichalcogenides. The facile fabrication
and novel properties of phosphorene have inspired design and demonstration of
new nanodevices; however, further progress hinges on resolutions to technical
obstructions like surface degradation effects and non-scalable fabrication
techniques. We also briefly describe the latest developments of more
sophisticated design concepts and implementation schemes that address some of
the challenges in phosphorene research. It is expected that this fascinating
material will continue to offer tremendous opportunities for research and
development for the foreseeable future.Comment: invited perspective for JPC
High resolution imaging of superficial mosaicity in single crystals using grazing incidence fast atom diffraction
International audienceA new table top technique is used to simultaneously analyze the local morphology of crystalline surfaces as well as the misalignment of large scale domains at the topmost surface layer. The approach is based on fast atom diffraction at grazing incidence (GIFAD); the diffraction pattern yields the structural characteristics and the topology of the surface electronic density with atomic resolution. If superficial mosaicity is present, diffraction patterns arising from each mosaic domain can be distinguished, providing high sensitivity to the properties of each of the domains. Taking NaCl(001) as an example, we observe a discrete tilt angle distribution of the mosaic domains following an arithmetic progression with a 0.025° ± 0.005° difference; a twist mosaic angle of 0.09° ± 0.01° is also observed
Técnicas de computação no ensino de física : pêndulo simples e movimento de projéteis
International audienc
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