Your search keyword '"ARCIPRETE P."' showing total 5 results

1. Electronic properties of Bi-doped GaAs(001) semiconductors

Author

Honolka, Jan, Hogan, Conor D., Vondracek, Martin, Poliak, Yaroslav, Arciprete, Fabrizio, and Placidi, Ernesto

Subjects

Condensed Matter - Materials Science

Abstract

Despite its potential in the fields of optoelectronics and topological insulators, experimental electronic band structure studies of Bi-doped GaAs are scarce. The reason is the complexity of growth which tends to leave bulk and in particular surface properties in an undefined state. Here we present an in depth investigation of structural and electronic properties of GaAsBi epilayers grown by molecular beam epitaxy with high (001) crystalline order and well-defined surface structures evident from low-energy electron diffraction. X-ray and ultraviolet photoemission spectrocopy as well as angle-resolved photoemission data at variable photon energies allows to disentangle a Bi-rich surface layer with $(1\times3)$ symmetry from the effects of Bi atoms incorporated in the GaAs bulk matrix. The influence of Bi concentrations up to $\approx 1$\% integrated in the GaAs bulk are visible in angle-resolved photoemission spectra after mild ion bombardment and subsequent annealing steps. Interpretation of our results is obtained via density functional theory simulations of bulk and $\beta 2(2\times 4)$ reconstructed slab geometries with and without Bi. Bi-induced energy shifts in the dispersion of GaAs heavy and light hole bulk bands are evident both in experiment and theory, which are relevant for modulations in the optical band gap and thus optoelectronic applications., Comment: 13 pages, 15 figures

Published

2018

2. Manipulation of electrical and ferromagnetic properties of photo-sensitized (Ga,Mn)As

Author

Diez, L. Herrera, Konuma, M., Placidi, E., Arciprete, F., Rushforth, A. W., Campion, R. P., Gallagher, B. L., Honolka, J., and Kern, K.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

We present the manipulation of magnetic and electrical properties of (Ga,Mn)As by the adsorption of dye-molecules as a first step towards the realization of light-controlled magnetic-semiconductor/dye hybrid devices. A significant lowering of the Curie temperature with a corresponding increase in electrical resistance and a higher coercive field is found for the GaMnAs/fluorescein system with respect to (Ga,Mn)As. Upon exposure to visible light a shift in Curie temperature towards higher values and a reduction of the coercive field can be achieved in photo-sensitized (Ga,Mn)As. A mayor change in the XPS spectrum of (Ga,Mn)As indicates the appearance of occupied levels in the energy range corresponding to the (Ga,Mn)As valence band states upon adsorption of fluorescein. This points towards a hole quenching effect at the molecule-(Ga,Mn)As interface which is susceptible to light exposure., Comment: 4 pages, 4 figures

Published

2010

3. Temperature dependent Neel wall dynamics in GaMnAs/GaAs

Author

Honolka, J., Diez, L. Herrera, Kremer, R. K., Kern, K., Placidi, E., and Arciprete, F.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

Extensive Kerr microscopy studies reveal a strongly temperature dependent domain wall dynamics in Hall-bars made from compressively strained GaMnAs. Depending on the temperature magnetic charging of domain walls is observed and nucleation rates depend on the Hall-geometry with respect to the crystal axes. Above a critical temperature where a biaxial-to-uniaxial anisotropy transition occurs a drastic increase of nucleation events is observed. Below this temperature, the nucleation of domains tends to be rather insensitive to temperature. This first spatially resolved study of domain wall dynamics in patterned GaMnAs at variable temperatures has important implications for potential single domain magneto-logic devices made from ferromagnetic semiconductors., Comment: Figures 2 and 6 not correctly TeXified

Published

2009

4. Experimental corroboration of the Mulheran-Blackman explanation of the scale invariance in thin film growth: the case of InAs quantum dots on GaAs(001)

Author

Fanfoni, M., Placidi, E., Arciprete, F., Orsini, E., Patella, F., and Balzarotti, A.

Subjects

Condensed Matter - Materials Science

Abstract

Mulheran and Blackman have provided a simple and clear explanation of the scale invariance of the island size distribution at the early stage of film growth [Phil. Mag. Lett. 72, 55 (1995)]. Their theory is centered on the concept of capture zone properly identified by Voronoi cell. Here we substantiate experimentally their theory by studying the scale invariance of InAs quantum dots (QDs) forming on GaAs(001) substrate. In particular, we show that the volume distributions of QDs well overlap the corrisponding experimental distributions of the Voronoi-cell areas. The interplay between the experimental data and the numerical simulations allowed us to determine the spatial correlation length among QDs.

Published

2006

5. How kinetics drives the two- to three-dimensional transition in semiconductor strained heterostructures: the case of InAs/GaAs(001)

Author

Arciprete, F., Placidi, E., Sessi, V., Fanfoni, M., Patella, F., and Balzarotti, A.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

The two- to three-dimensional growth transition in the InAs/GaAs(001) heterostructure has been investigated by atomic force microscopy. The kinetics of the density of three dimensional quantum dots evidences two transition thresholds at 1.45 and 1.59 ML of InAs coverage, corresponding to two separate families, small and large. Based on the scaling analysis, such families are characterized by different mechanisms of aggregation, involving the change of the critical nucleus size. Remarkably, the small ones give rise to a wealth of "monomers" through the erosion of the step edges, favoring the explosive nucleation of the large ones., Comment: 10 pages, 3 figures. Submitted to Phys. Rev. Lett

Published

2005