Orbital magnetism in the ballistic regime: geometrical effects

This study employed finite element analysis to simulate ultrasonic metal bump direct bonding. The stress distribution on bonding interfaces in metal bump arrays made of Al, Cu, and Ni/Pd/Au was simulated by adjusting geometrical parameters of the bumps, including the shape, size, and height; the bonding was performed with ultrasonic vibration with a frequency of 35 kHz under a force of 200 N, temperature of 200 °C, and duration of 5 s. The simulation results revealed that the maximum stress of square bumps was greater than that of round bumps. The maximum stress of little square bumps was at least 15% greater than those of little round bumps and big round bumps. An experimental demonstration was performed in which bumps were created on Si chips through Al sputtering and lithography processes. Subtractive lithography etching was the only effective process for the bonding of bumps, and Ar plasma treatment magnified the joint strength. The actual joint shear strength was positively proportional to the simulated maximum stress. Specifically, the shear strength reached 44.6 MPa in the case of ultrasonic bonding for the little Al square bumps.

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TRANSPORT PROPERTIES OF 2D ELECTRON GAS IN AN n-InGaAs/GaAs DQW IN A VICINITY OF LOW MAGNETIC-FIELD-INDUCED HALL INSULATOR–QUANTUM HALL LIQUID TRANSITION

International Journal of Nanoscience ◽

10.1142/s0219581x07004523 ◽

2007 ◽

Vol 06 (03n04) ◽

pp. 173-177

Author(s):

YU. G. ARAPOV ◽

S. V. GUDINA ◽

G. I. HARUS ◽

V. N. NEVEROV ◽

N. G. SHELUSHININA ◽

...

Keyword(s):

Magnetic Field ◽

Electron Gas ◽

Quantum Hall ◽

Zero Magnetic Field ◽

Double Quantum ◽

Ballistic Regime ◽

2D Electron Gas ◽

Double Quantum Well ◽

Liquid Transition ◽

Low Magnetic Field

The resistivity (ρ) of low mobility dilute 2D electron gas in an n- InGaAs / GaAs double quantum well (DQW) exhibits the monotonic "insulating-like" temperature dependence (dρ/dT < 0) at T = 1.8–70 K in zero magnetic field. This temperature interval corresponds to a ballistic regime (kBTτ/ħ > 0.1–3.5) for our samples, and the electron density is on an "insulating" side of the so-called B = 0 2D metal–insulator transition. We show that the observed features of localization and Landau quantization in a vicinity of the low magnetic-field-induced insulator–quantum Hall liquid transition is due to the σxy(T) anomalous T-dependence.

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Experimental and Computational Analyses of Pressure Differentials in Flexible Ducts With Different Bent Angles

Volume 2: Fora, Parts A and B ◽

10.1115/fedsm2007-37652 ◽

2007 ◽

Author(s):

Ray R. Taghavi ◽

Wonjin Jin ◽

Mario A. Medina

Keyword(s):

Pressure Drop ◽

Static Pressure ◽

Complex Geometry ◽

Analysis Data ◽

Secondary Flows ◽

Low Flow ◽

Pressure Drops ◽

Pressure Distributions ◽

Geometrical Effects ◽

Cfd Analyses

A set of experimental analyses was conducted to determine static pressure drops inside non-metallic flexible, spiral wire helix core ducts, with different bent angles. In addition, Computational Fluid Dynamics (CFD) solutions were performed and verified by comparing them to the experimental data. The CFD computations were carried out to produce more systematic pressure drop information through these complex-geometry ducts. The experimental setup was constructed according to ASHRAE Standard 120-1999. Five different bent angles (0, 30, 45, 60, and 90 degrees) were tested at relatively low flow rates (11 to 89 CFM). Also, two different bent radii and duct lengths were tested to study flexible duct geometrical effects on static pressure drops. FLUENT 6.2, using RANS based two equations - RNG k-ε model, was used for the CFD analyses. The experimental and CFD results showed that larger bent angles produced larger static pressure drops in the flexible ducts. CFD analysis data were found to be in relatively good agreement with the experimental results for all bent angle cases. However, the deviations became slightly larger at higher velocity regimes and at the longer test sections. Overall, static pressure drop for longer length cases were approximately 0.01in.H2O higher when compared to shorter cases because of the increase in resistance to the flow. Also, the CFD simulations captured more pronounced static pressure drops that were produced along the sharper turns. The stronger secondary flows, which resulted from higher and lower static pressure distributions in the outer and inner surfaces, respectively, contributed to these higher pressure drops.

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Geometrical Effects on Sintering Dynamics of Cu–Ag Core–Shell Nanoparticles

The Journal of Physical Chemistry C ◽

10.1021/acs.jpcc.6b05515 ◽

2016 ◽

Vol 120 (31) ◽

pp. 17791-17800 ◽

Cited By ~ 25

Author(s):

Jiaqi Wang ◽

Seungha Shin ◽

Anming Hu

Keyword(s):

Core Shell ◽

Shell Nanoparticles ◽

Geometrical Effects ◽

Core Shell Nanoparticles

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Anomalies in the orbital magnetism of neutrons in the 190,192Pt nuclei

Physics of Atomic Nuclei ◽

10.1134/1.1378873 ◽

2001 ◽

Vol 64 (5) ◽

pp. 843-848 ◽

Cited By ~ 1

Author(s):

I. B. Kovgar ◽

A. I. Levon ◽

R. S. Poznyak ◽

O. V. Sevastyuk

Keyword(s):

Orbital Magnetism

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Formation and Structure of Work Material in the Friction Stir Forming Process

Journal of Manufacturing Science and Engineering ◽

10.1115/1.4030641 ◽

2015 ◽

Vol 137 (5) ◽

Cited By ~ 12

Author(s):

Sladjan Lazarevic ◽

Kenneth A. Ogata ◽

Scott F. Miller ◽

Grant H. Kruger ◽

Blair E. Carlson

Keyword(s):

Steel Sheet ◽

Dissimilar Materials ◽

Mechanical Interlocking ◽

Forming Process ◽

Friction Stir ◽

Joint Structure ◽

Work Material ◽

Formation Zone ◽

Significant Process ◽

Geometrical Effects

Friction stir forming (FSF) is a new environmentally friendly manufacturing process for lap joining of dissimilar materials. Fundamentally, this process is based on frictionally heating and mechanically stirring work material of the top piece in a plasticized state to form a mechanical interlocking joint within the bottom material. In this research, the significant process parameters were identified and optimized for Al 6014 alloy and mild steel using a design of experiments (DOE) methodology. The overall joint structure and grain microstructure were mapped as the FSF process progressed and the aluminum work material deformed through different stages. It was found that the work material within the joint exhibited two layers, thermomechanical affected zone, which formed due to the contact pressure and angular momentum of the tool, and heat affected formation zone, which was composed of work material formed through the hole in the steel sheet and into the anvil cavity. Two different geometries of anvil design were employed to investigate geometrical effects during FSF of the aluminum. It was found that the direction and amount of work material deformation under the tool varies from the center to the shoulder.

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