A theoretical framework for the dynamic analysis of a printed wiring board under mechanical and thermal loading

He, Xiaoling

12 1900

No description available.

Microelectronics Reliability

Printed circuits Testing

Nonlinear theories

Design of an advanced system for inspection of microelectronic devices and their solder connections using laser-induced virbration techniques

Howard, Turner A.

08 1900

No description available.

Microelectronics Testing

Solder and soldering Quality control

Interfacial fluid pressure and pad viscoelasticity during chemical meachanical polishing

Hight, J. Robert

05 1900

No description available.

Grinding and polishing

Electrolytic polishing

Microelectronics Materials

Viscoeleastcity

High yield flip chip processing and failure mode analysis for surface mount applications

Tsai, Wen-Kai Mike

08 1900

No description available.

Surface mount technology

Microelectronics Testing

Packaging

Study of warpage of base substrates and materials for large-area MCM-D packaging

Dang, Anh Xuan-Hung

12 1900

No description available.

Multichip modules (Microelectronics)

Microelectronic packaging Materials

Establishment of an analytical and experimental test facility for the evaluation of thermal management in microelectric packages

Campbell, James Stephen, Jr.

05 1900

No description available.

Microelectronic packaging Testing

Microelectronics

Thermal stresses

Processing of low permittivity silica thin films

Kokan, Julie Runyan

12 1900

No description available.

Thin films

Silica

Multichip modules (Microelectronics)

Vacuum field emission microelectronic devices based on silicon nanowhiskers

Thongpang, Sanitta

January 2007

Vacuum field emission devices have become a promising candidate for emerging display technology due to their interesting properties compared to conventional thermionic emission devices that require high temperature and power to operate. Unlike thermionic emission, field emission devices can induce the electrons to emit at low temperature; sharp and thin emitters on the cathode are desired in order to increase the field emission. Many candidates from other research groups, such as Carbon Nanotubes (CNTs), SiC and ZnO, appear to have high field emission, but their complicated fabrication processes are the drawback. The silicon nanowhiskers produced by Geological & Nuclear Sciences (GNS) using Electron-Beam Rapid Thermal Annealing (EB-RTA) are an alternative material that is fast, inexpensive and uncomplicated to produce. They are based on the thermal desorption of silicon oxide, which forms silicon nanowhiskers on the silicon wafer in a short duration. Field emission diode structures on Silicon on Insulator (SOI) wafers were fabricated in order to investigate the field emission due to these GNS silicon nanowhiskers. An uncomplicated fabrication process using photolithography and etching process was developed. Electron beam lithography (EBL) was also used to create the different feature sizes directly onto the SOI wafer. The silicon nanowhiskers grown on these structures are as high as 35 nm with density distribution up to 30 µm⁻¹. The electrical characteristics of these devices are diode-like when the voltage range from -40 V to 40 V is applied. The best samples produced an emitted current as high as 2 mA, which is suitable for many applications, such as flat panel displays, x-ray sources and high frequency devices. However, in some cases, the diode structures failed to show the diode-like characteristics, perhaps as a result of bad contact connections or the emitters have been worn out after applying high voltage for some time. Device life time and stability were also considered and investigated via a number of electrical measurements for a period of time as long as one hour in this study. Even though these nanowhiskers have shown promising results, there are still many aspects to be considered to improve the experiments, such as the vacuum system and better contacts.

Vacuum microelectronics

silicon nanowhiskers

field emission display

Work function tuning of reactively sputtered MoxSiyNz metal gate electrodes for advanced CMOS technology

Patel, Pommy

14 July 2008

Due to continued transistor scaling, work function tuning of metal gates has become important for advanced CMOS applications. Specifically, this research has been undertaken to discover the tuning of the MoxSiyNz gate work function through the incorporation of nitrogen. Metal Oxide Semiconductor (MOS) capacitors were fabricated using thermal SiO2 as gate oxide on lightly doped p-type Si wafer. A molybdenum silicide (MoSi2) target was reactively sputtered at 10mTorr in presence of N2 and Ar. The gas flow ratio, RN = N2/ (N2+Ar), was adjusted to vary the nitrogen concentration in MoSiN films. The gate work function (Фm) was extracted from capacitance-voltage (CV) measurements using the VFB-tox method. Interfacial barrier heights were measured using internal photoemission (IPE) as an independent confirmation of the MoSiN gate work function. The work function was found to decrease linearly (from ~4.7eV to ~4.4eV) for increasing gas flow ratios (from 10% to 40%). Secondary ion mass spectrometry (SIMS) depth profiles suggested that the nitrogen concentration was relatively uniform throughout the film. X-Ray Photoelectron Spectroscopy (XPS) surface analysis showed a steady increase in the total nitrogen concentration (from ~20% to 32%) in these films as gas flow ratio was increased. These data suggests that the increase in nitrogen concentration in MoSiN films corresponds directly with the lowering of MoSiN work function. These results clearly demonstrate that the work function of MoxSiyNz can be varied ~0.3 eV by adjusting the nitrogen concentration.

microelectronics

CMOS

capacitor

metal work function

Flow boiling of FC-72 from a screen laminate extended surface matrix

Holland, Ben.

January 2006

Thesis (M.S.)--University of Nevada, Reno, 2006. / "December, 2006." Includes bibliographical references (leaves 48-51). Online version available on the World Wide Web.