0.13μm DSP芯片静态电流测试失效分析研究

静态电流(IDDQ)测试是一种很灵敏且具有成本效益的集成电路测试技术,针对0.13μm某种DSP芯片在量产初期所遇到的IDDQ测试失效情况,利用激光束诱导电阻值变化(OBIRCH)、电压对比(VC)、扫描电镜(SEM)和聚焦离子束(FIB)等电学与物理失效分析方法,确定由离子注入偏差所引起的MOS器件物理缺陷是造成IDDQ失效的原因,据此进行了离子注入光阻的工艺改进,最终实现了成品率的提升.     

Preparation and characterization of wollastonite/titanium oxide nanofiber bioceramic composite as a future implant material

In this study, novel composites consisting of electrospun titanium dioxide (TiO₂) nanofibers incorporated into high-purity wollastonite glass ceramics were prepared as materials for use in hard tissue engineering applications. These materials were characterized and investigated by means of physical, mechanical and in vitro studies. The proposed composite showed greater densification and better mechanical characteristics compared to pure wollastonite. The influence of densification temperature and TiO₂ content was investigated. Typically, TiO₂/wollastonite composites having 0, 10, 20 and 30 wt% metal oxide nanofibers were sintered at 900, 1100 and 1250 °C. The results indicated that increasing TiO₂ nanofibers content leads to increase the bulk density, compressive strength and microhardness with negligible, high and moderate influence for the densification temperature, respectively. While porosity and water adsorption capacity decreased with increasing the metal oxide nanofibers with a considerable impact for the sintering temperature in both properties. Moreover, bone-like apatite formed on the surface of wollastonite and wollastonite/TiO₂ nanofibers soaked in simulated body fluid (SBF). All these results show that the inclusion of TiO₂ nanofibers improved the characteristics of wollastonite while preserving its in vitro bioactivity; hence, the proposed composite may be used as a bone substitute in high load bearing sites.     

MAO-DCPD composite coating on Mg alloy for degradable implant applications

Magnesium (Mg) is a promising metallic material for use as degradable orthopedic implants. The density and Young's modulus of Mg are close to those of human bone, and it is non-toxic and degradable in body fluids. However, the realization of Mg as an implant material is hampered by its high corrosion rate. The present article aims at improving the corrosion resistance and bioactivity of a Mg alloy AZ80 via surface treatment. AZ80 was coated with a composite coating consisting of an oxide layer formed by micro-arc oxidation (MAO) and a top layer of dicalcium phosphate dihydrate (DCPD, CaHPO₄·2H₂O) fabricated by electrodeposition. The corrosion behavior and apatite-forming ability in simulated body fluids (SBFs) were studied using hydrogen evolution measurements and SEM. The results show that the MAO-DCPD composite coating significantly reduces the corrosion rate of AZ80 and at the same time enhances the deposition of apatite on the coating.     

生物医用钛及钛合金的研制、生产和应用

简介了新型生物医用功能材料用钛及钛合金的研制历史、生产、标准和应用。     

Improved Fibroblast Functionalities by Microporous Pattern Fabricated by Microelectromechanical Systems

Fibroblasts, which play an important role in biological seal formation and maintenance, determine the long-term success of percutaneous implants. In this study, well-defined microporous structures with micropore diameters of 10–60 µm were fabricated by microelectromechanical systems and their influence on the fibroblast functionalities was observed. The results show that the microporous structures with micropore diameters of 10–60 µm did not influence the initial adherent fibroblast number; however, those with diameters of 40 and 50 µm improved the spread, actin stress fiber organization, proliferation and fibronectin secretion of the fibroblasts. The microporous structures with micropore diameters of 40–50 µm may be promising for application in the percutaneous part of an implant.     

Cell Adhesion and in Vivo Osseointegration of Sandblasted/Acid Etched/Anodized Dental Implants

The authors describe a new type of titanium (Ti) implant as a Modi-anodized (ANO) Ti implant, the surface of which was treated by sandblasting, acid etching (SLA), and anodized techniques. The aim of the present study was to evaluate the adhesion of MG-63 cells to Modi-ANO surface treated Ti in vitro and to investigate its osseointegration characteristics in vivo. Four different types of Ti implants were examined, that is, machined Ti (control), SLA, anodized, and Modi-ANO Ti. In the cell adhesion study, Modi-ANO Ti showed higher initial MG-63 cell adhesion and induced greater filopodia growth than other groups. In vivo study in a beagle model revealed the bone-to-implant contact (BIC) of Modi-ANO Ti (74.20% ± 10.89%) was much greater than those of machined (33.58% ± 8.63%), SLA (58.47% ± 12.89), or ANO Ti (59.62% ± 18.30%). In conclusion, this study demonstrates that Modi-ANO Ti implants produced by sandblasting, acid etching, and anodizing improve cell adhesion and bone ongrowth as compared with machined, SLA, or ANO Ti implants. These findings suggest that the application of Modi-ANO surface treatment could improve the osseointegration of dental implant.     

Evaluation of susceptibility of hydrogen-induced cracking in micro-alloyed armour steel welds using a geometry-modified implant test

Susceptibility to hydrogen-induced cracking (HIC) was evaluated in steel welds for quenched and tempered armouring steel of 4.5 mm thickness. The welds were produced using the shielded metal arc welding process with low heat support and AWS E11018M 2.4 mm consumable. The susceptibility to HIC was evaluated by means of an implant test with modified geometry in welded joints with and without preheating being applied, using consumables in ideal stock conditions and exposed to the atmosphere. It was found that the consumable stock conditions were more relevant than preheating in regard to susceptibility to HIC.     

Analysis of the fatigue behaviour characterized by stiffness and permanent deformation for different distal volar radius compression plates

Fractures of the distal radius are with 10% the most frequent fractures of the human skeleton. In order to stabilize the fracture which is essential for succesful bone-healing, distal volar compression using dorsal compression plates is often used. Among the most important, but until now sparsely investigated criteria for implant-quality is the fatigue behaviour of the system of radius and stabilizing implant. Several types of implants were tested in combination with synthetic bones in the fatigue regime. The fatigue behaviour of samples was characterized using the parameters stiffness, tilting angle and reduction of the fracture gap which can be expressed by the permanent deformation of the system. The study of the evolution of these properties allows an interpretation of the mechanisms governing fatigue. Thus, a comparison of different implant types was obtained. Results show that the geometry of the implant as well as the positioning and type of the used screws has a profound effect on the characteristics of the system.