Improved electrical characteristics of CoSi2 usingHF-vapor pretreatment

We have developed a simple process to form epitaxial CoSi₂ for shallow junctions. Prior to metal deposition, the patterned wafers were treated with HF-vapor passivation. As observed by scanning tunneling microscopy (STM), this HF treatment drastically improves the native oxide-induced surface roughness. The epitaxial behavior was confirmed by cross-sectional transmission electron microscopy (TEM). Decreased sheet resistance and leakage current, and improved thermal stability are displayed by the HF treated samples, which is consistent with STM and TEM results     

The Effect of a Zinc Interlayer on the Microstructure and Mechanical Properties of a Magnesium Alloy (AZ31)–Aluminum Alloy (6060) Joint Produced by Liquid–Solid Compound Casting

Bimetallic AZ31/6060 joints were produced by compound casting. The process involved pouring liquid magnesium alloy onto a solid aluminum alloy insert placed in a mold. Inserts with and without a zinc surface layer were used. For an insert with no Zn layer, the bonding zone was characterized by a non-homogeneous microstructure. In the area adjacent to the AZ31, there was a eutectic (γ and α(Mg)). In the area close to the 6060 alloy, two continuous layers of the γ and β phases were detected. When a 6060 insert with a Zn layer was used, the bonding zone was mainly composed of Mg-Al-Zn phases. The joint without a Zn interlayer had low shear strength (5.5–11.3 MPa). The presence of the Zn interlayer caused a significant increase in the joint strength (39.8–46.6 MPa). The micro-indentation data suggest a less brittle fracture character of the bonding zone with a Zn layer.

     

Ceramic-on-ceramic catastrophic liner failure in total hip arthroplasty: Morphological and compositional analysis of fractured ceramic components

Surface bearing of total hip arthroplasty (THA) still is a strong subject of study due to the relatively high rate of failures caused by a multiplicity of factors including surgical technique, patient's attitude, and type/characteristics of the materials used (metal, ceramics, polyethylene) with their specific risk factors. Fractures of the ceramic components are rare but catastrophic events, with many concerns among the orthopaedic surgeons. Such complication is usually evaluated from a clinical viewpoint; this study provides a materials scientist's complementary perspective and comprehensively evaluates the surface and the mechanism of rupture of the ceramic liner in two cases with different ceramics (Biolox Forte and Biolox Delta) after ceramic-on-ceramic THA. The morphological and compositional analyses of the ceramic components were performed by field-emission scanning electron microscopy (FESEM) and energy dispersive spectroscopy (EDS), along with macroscopic pictures. The SEM analysis of the ceramic liner showed many wear signs in all directions, while the EDS revealed the presence of titanium near to the fracture border, which might be interpreted as a consequence of the catastrophic contact between ceramic liner and metal back. Biolox Delta and Biolox Forte ceramic liners showed different patterns of fracture and surface modifications that are illustrated and discussed.     

Fire performance and mechanical properties of acrylonitrile‐butadiene‐styrene copolymer/modified expandable graphite composites

The fire performance and mechanical properties of an acrylonitrile‐butadiene‐styrene (ABS) copolymer compounded with different expandable graphites (EG) and fire retardants were studied by using the limiting oxygen index test, the UL‐94 test, a mechanical test, and a thermogravimetric analysis. The ground EG treated with phosphoric acid and silane could have the great increase of the volume expansion ratio. The addition of the treated EG in ABS significantly enhances the fire performance but decreases the impact strength of ABS. ABS with the treated EG has a much higher impact strength than with the as‐received EG because of the smaller particle size of the treated EG and the better adhesion between the ABS and the treated EG. The addition of modified ammonium polyphosphate or decabromodiphenyl oxide/antimony trioxide can considerably improve the fire performance of ABS/treated EG composites because of a synergistic effect. The V‐0 grade (UL‐94) ABS composite with the limiting oxygen index of 32.5 can be obtained by adding small amounts of the treated EG and modified ammonium polyphosphate into ABS. Thermogravimetric analysis results indicate that the initial vapor release temperatures and the weight loss rates of ABS/EG composites are closely related to their fire performance and affected by the fire retardant used. Copyright © 2011 John Wiley & Sons, Ltd.     

Plasmonic green nanolaser based on a metal-oxide-semiconductor structure

Realization of smaller and faster coherent light sources is critically important for the emerging applications in nanophotonics and information technology. Semiconductor lasers are arguably the most suitable candidate for such purposes. However, the minimum size of conventional semiconductor lasers utilizing dielectric optical cavities for sustaining laser oscillation is ultimately governed by the diffraction limit (～(λ/2n)(3) for three-dimensional (3D) cavities, where λ is the free-space wavelength and n is the refractive index). Here, we demonstrate the 3D subdiffraction-limited laser operation in the green spectral region based on a metal-oxide-semiconductor (MOS) structure, comprising a bundle of green-emitting InGaN/GaN nanorods strongly coupled to a gold plate through a SiO(2) dielectric nanogap layer. In this plasmonic nanocavity structure, the analogue of MOS-type "nanocapacitor" in nanoelectronics leads to the confinement of the plasmonic field into a 3D mode volume of 8.0 × 10(-4) μm(3) (～0.14(λ/2n)(3)).     

Performance of high‐resolution TVD schemes for 1D dam‐break simulations

Abstract

The performance of high‐resolution total variation diminishing (TVD) schemes for simulating dam‐break problems are presented and evaluated. Three robust and reliable first‐order upwind schemes, namely FVS, Roe and HLLE schemes, are extended to six second‐order TVD schemes using two different approaches, the Sweby flux limiter approach and the direct MUSCL‐Hancock slope limiter. For idealized dam‐break flows, comparisons of the simulated results with the exact solutions show that the flux vector splitting (FVS) scheme coupled with the direct MUSCL‐Hancock (DMH) slope limiter approach has the best numerical performance among the presented schemes. Application of the FVS‐DMH scheme to a dam‐break experiment with sloping dry bed shows that the simulated water depths agree well with the measured.     

Reconfigurable Architecture for Deinterlacer based on Algorithm/Architecture Co-Design

This paper presents the algorithm and reconfigurable architecture of motion-adaptive deinterlacer for high-definition video. The content-adaptability of algorithm and the reconfiguration of architecture are concurrently explored by algorithm/architecture co-design methodology and Caltrop actor language (CAL) modeling of the dataflow. In the design methodology we employed, the CAL dataflow model is also very helpful in the verification of our deinerlacer. The proposed algorithm and architecture design of deinterlacer is more cost-efficient than two recently proposed works in terms of algorithmic performance and silicon area of VLSI implementation. Moreover, data path reconfiguration efficiently enables various interpolation schemes using less computational resource of hardware than non-reconfigurable architecture.