A second order isoparametric finite element analysis of dielectric waveguides with curved boundaries /

Welt, Daniel.

January 1984

No description available.

Finite element method.

Dielectric wave guides.

Electromagnetic Simulations of Exotic Phenomena in Engineered Materials:

Dodge, Tyler E.

January 2023

Thesis advisor: Krzysztof Kempa / “Simulations are like an experiment but on a computer.” – K. Kempa. Powerful ideas can be explored in immense detail and unmatched flexibility through computational resources. Combined with the beauty of electromagnetics, worlds of situations and problems can be uncovered. Of the many interesting phenomena available to study, a relatively recent explosion of engineered plasmonic materials has benefitted greatly from numerical breakthroughs in simulating Maxwell’s equations. Using these tools on novel metamaterial systems, composite materials with precisely designed structural features, the analysis and optimization probes the unique capabilities they have interacting with light. Example phenomena from this work includes fundamental principle breaking, extraordinary optical transmission, negative refraction, and superconductivity enhancement. The systems that harbor such outstanding feats fall into the umbrella term of metamaterials, each with distinct geometry and contrasting electrical properties that allow for an engineered control of the effective structural dielectric function. As the response to electromagnetic radiation, manipulating the dielectric function is key to creating and discovering the effects that control light, without changing any chemistry. This work scales pedagogically through the different types of metamaterials, beginning first with 2D planar checkerboard structures with highly non-linear percolation. In combination with spoofed plasmonics, the longstanding symmetry of the Babinet principle is challenged. Layers of checkerboards are then stacked and translated to create subwavelength gaps for which plasmonic coupling between layers aids in optical transmission. In fact, there is similar physics controlling other layered quasi-complementary structures shown by comparison to experimental transmittance data. A further stage introduces photonic crystals constructed out of 3D periodic lattice of nanoparticles. Photonic band structure calculations for properly designed systems suggest the possibility of bandwidths of the IR spectrum where the crystal has a negative refractive index. Such a material property allows for the invention of lenses that beat the diffraction limit, applicable to subwavelength imaging. Lastly, non-local extensions to plasmonics are theoretically worked into expressions for superconductivity, creating a resonant anti-shielding effect, in composite topological crystal/superconductor layered arrangements. Applying this to known topics, like Bi2Se3 and MgB2, shows significant boost to electron pairing and thus rises in superconducting critical temperature. Central to all the systems and effects explored are the modifications made to the dielectric function of each effective medium. Supported by electromagnetic simulations and theoretical efforts, the listed engineered materials transform the dielectric environment purposefully to originate the mentioned exotic optical phenomena. / Thesis (PhD) — Boston College, 2023. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Physics.

dielectric

electromagnetic

metamaterials

plasmonics

simulation

superconductivity

Steam, Dielectric Heating and Copper Sulfate Treatment of Inshell Pecans

Patel, Mandar Ranchhod

09 August 2008

Water and a copper sulfate (CSL) solution at 27, 57 and 88°C; steam pasteurization and dielectric heating were analyzed on their effect in reducing microbial load (APC) and Salmonella Typhimurium on inshell pecans (Carya illinoinensis). The CSL solution (more effective than water alone) reduced APC by 1.5 (300 s), 2 (60 s) and 4.0 (60 s) log CFU/g at 27, 57 and 88°C, respectively; and Salmonella by 3.0 log at 27°C in 60 s. Steam reduced APC by 3.7 log in 180 s and Salmonella by 4.0 log CFU/g in 30 s. Dielectric treatment reduced APC by 3.0 log and Salmonella by 4.5 log CFU/g in 60 s. Most treatments had no effect on the pecan shell or the nut quality, except for dielectric heating, which gave a slight "roasted" or "burnt" flavor to the nuts. This study showed that a proper antimicrobial-hot water treatment, steam or dielectric heating will be effective in "pasteurizing" pecans, resulting in a safe and wholesome product.

dielectric heating

pasteurization

antimicrobial

Salmonella

Pecans

Dielectric investigation of double glass transitions in polymers

Akins, Robert Benjamin

January 1991

No description available.

Electro-optical effects of liquid crystals with dielectric dispersion

Wonderly, Hugh Alan

02 December 2010

No description available.

Physics

dielectric dispersion

flexoelectric effect

liquid crystal

Dynamics of biomolecules: Dielectric spectrum of DNA and assembly of peptide fibrils

Agnihotri, Mithila V., agnihotri

14 June 2018

No description available.

Biophysics

DNA

dielectric

molecular dynamics

tau

PHF6

DESIGN OF A NOVEL SAPPHIRE BASED DIELECTRIC RESONATOR TO MEASURE THE SURFACE RESISTANCE OF HIGH TEMP SUPER CONDUCTORS

MISHRA, AWANISH KUMAR

04 September 2003

No description available.

HTSC

dielectric resonator

surface resistance

ovalue

temode

Advancing the Frontiers of Low Voltage Electrowetting on Dielectrics through a Complete Understanding of Three Phases System Interactions

Chevalliot, St¿¿¿¿phanie

27 September 2012

No description available.

Materials Science

Electrowetting

Saturation

Dielectric

Parylene

Optical Memory Device Structure Using Vertical Interference From Digital Thin Films

Chi, Robert Chih-Jen

11 October 2001

No description available.

optical memory

interference

dielectric

thin film

milling

Study of Optimal Deposition Conditions for an Inductively Coupled Plasma Chemical Vapour Deposition (ICP-CVD) System

Zhang, Haiqiang

12 1900

<p> High-density plasma technology is becoming increasingly attractive for the deposition of dielectric films such as silicon dioxide, silicon nitride and silicon oxynitride. In particular, inductively coupled plasma chemical vapor deposition (ICP-CVD) offers several technological advantages for low temperature processing over other plasma-enhanced chemical vapor deposition (PECVD), such as higher plasma density, lower hydrogen content films, and lower cost. A new ICP-CVD system has been set up at McMaster University. </p> <p> The project focused on the calibration of this system and the establishment of its performance characteristics. A combination of 0 2/ Ar/SiH4 gases was used to deposit Si02 thin films on single-crystal Si wafers under various conditions. Substrate temperatures were calibrated from 200 to 400°C, and were found to linearly relate to heater temperatures. Calibration of the minimum reflected power showed that the ICP source is efficient to generate a stable plasma for 02, N2 and Ar gases within a wide range of flow rates from 3 to 1 OOsccm, while the reflected power remains below 10 Watts. Uniformity was found to be sensitive to many factors. Under optimal conditions, uniformity could be controlled better than 1% with a good shape of thickness distribution. The refractive indexes of the deposited films were measured with ellipsometry and showed an inverse relation with the ratio of oxygen to silane flow rate. </p> / Thesis / Master of Applied Science (MASc)

deposition

plasma

chemical vapour

dielectric films