Joseph Abel scite author profile

Sitnitsky

et al. 2010

Ballistic electron emission microscopy is utilized to investigate the hot-electron scattering properties of Cu through Cu/Si(001) Schottky diodes. A Schottky barrier height of 0.64±0.02 eV and a hot-electron attenuation length of 33.4±2.9 nm are measured at a tip bias of 1.0 eV and a temperature of 80 K. The dependence of the attenuation length with tip bias is fit to a Fermi liquid model that allows extraction of the inelastic and elastic scattering components. This modeling indicates that elastic scattering due to defects, grain boundaries, and interfaces is the dominant scattering mechanism in this energy range.

Hot electron transport studies of the Cu/Si(001) interface using ballistic electron emission microscopy

Sitnitsky

et al. 2009

Articles you may be interested inSchottky barrier height measurements of Cu/Si(001), Ag/Si(001), and Au/Si(001) interfaces utilizing ballistic electron emission microscopy and ballistic hole emission microscopy AIP Advances 3, 112110 (2013); 10.1063/1.4831756 Hot-electron transport studies of the Ag/Si(001) interface using ballistic electron emission microscopy J. Vac. Sci. Technol. A 28, 643 (2010); 10.1116/1.3397795 Ambipolar ballistic electron emission microscopy studies of gate-field modified Schottky barriers Appl. Phys. Lett. 96, 242106 (2010); 10.1063/1.3453866Ion-bombardment effects on PtSi /n -Si Schottky contacts studied by ballistic electron emission microscopy

Signatures of the semiconductor crystallographic orientation on the charge transport across non-epitaxial diodes

Barraza‐Lopez

et al. 2012

The hot electron attenuation length of Ag is measured utilizing ballistic electron emission microscopy on nanoscale Schottky diodes for Si(001) and Si(111) substrates. Marked differences in the attenuation length are observed at biases near the Schottky barrier depending upon the substrate orientation, increasing by an order of magnitude only for Si(001). These results provide clear evidence that the crystallographic orientation of the semiconductor substrate and parallel momentum conservation affect the charge transport across these interfaces. A theoretical model reproduces the effect that combines a free-electron description within the metal with an ab-initio description of the electronic structure of the semiconductor.

Temperature dependent spin precession measurements in trilayer graphene utilizing co/graphene contacts

Matsubayashi

et al. 2012

The temperature dependence of the spin lifetime and spin diffusion coefficient of exfoliated multilayer graphene is measured using nonlocal spin detection and spin precession measurements. Low impedance cobalt contacts are utilized for spin injection and readout. A decrease in spin lifetime with increasing temperature is observed as well as an increase in the spin diffusion coefficient with increasing temperature. This observation provides some insight into the relevant spin relaxation mechanisms that are occurring in this trilayer graphene sample.

Fabrication of an electrical spin transport device utilizing a diazonium salt/hafnium oxide interface layer on epitaxial graphene grown on 6 H-SiC(0001)

Matsubayashi

Murray

et al. 2012

Nonlocal Hanle spin precession devices are fabricated on wafer scale epitaxial graphene utilizing conventional and scalable processing methods. To improve spin injection and reduce contact related spin relaxation, hafnium oxide is utilized as an interface barrier between the graphene on SiC(0001) and ferromagnetic metal contacts. The hafnium oxide layer is deposited by atomic layer deposition utilizing an organic seed layer. Spin precession is observed in the epitaxial graphene.