Silicon-based 0.450-0.475 THz series-fed double dielectric resonator on-chip antenna array based on metamaterial properties for integrated-circuits

Alibakhshikenari, M., Virdee, B.S., See, C.H., Abd-Alhameed, Raed, Falcone, F., Limiti, E.

14 November 2019

Yes / The antenna array designed to operate over 0.450-0.475 Terahertz comprises two dielectric resonators (DRs) that are stacked vertically on top of each other and placed on the surface of the slot antenna fabricated on a silicon substrate using standard CMOS technology. The slot created in the silicon substrate is meandering and is surrounded by metallic via-wall to prevent energy dissipation. The antenna has a maximum gain of 4.5dBi and radiation efficiency of 45.7% at 0.4625 THz. The combination of slot and vias transform the antenna to a metamaterial structure that provides a relatively small antenna footprint. The proposed series-fed double DRs on-chip antenna array is useful for applications in THz integrated circuits. / Partially supported by innovation programme under grant agreement H2020-MSCA-ITN-2016 SECRET-722424 and the financial support from the UK Engineering and Physical Sciences Research Council (EPSRC) under grant EP/E0/22936/1.

Dielectric resonator antennas

System-on-chip

Antenna arrays

Dielectrics

Silicon

Slot antennas

Substrates

Mapping Substrate Use Across A Permafrost Thaw Gradient

Fofana, Aminata

January 2021

No description available.

Environmental Science

Climate Change

A Study of the Chemical Cleavage of Benzylic-Silicon Bonds

Kavalakatt, Pauly

01 1900

<p> The key objective of this research was to study the rates of the chemical cleavage of benzyl-silicon bonds in small model molecules, oligomers, polymers, copolymers, and crosslinked microspheres and microgels.</p> <p> Substrate species including benzyltrimethylsilane (BTMS), p-isopropylbenzyltrimethylsilane (ISO-BTMS), oligomeric and polymeric vinylbenzyltrimethylsilane (VBTMS), and their copolymers with styrene and methyl methacrylate as well as microspheres and microgels of bis(vinylbenzyl)dimethylsilane (BVBDMS) were synthesized using Grignard reaction, free radical polymerization, and precipitation polymerization.</p> <p> Narrow dispersed microspheres were synthesized from bis(vinylbenzyl)dimethylsilane (BVBDMS) by precipitation polymerization in acetonitrile. The reactivities of para/para, meta/meta, and meta/para isomers of BVBDMS in precipitation polymerization were found to be similar and to obey first-order kinetics. Their apparent rate of polymerization is comparable with that of meta and para divinylbenzene isomers under identical polymerization conditions. FT-IR analysis of BVBDMS microspheres shows that there are only few pendant double bonds in the particles. This is likely due to the similar reactivity of isolated double bonds of BVBDMS.</p> <p> Two nucleophilic (hydroxide and fluoride ion) and one oxidative (ceric ammonium nitrate) reagents have been used to cleave the benzylic-silicon bonds of the substrates. The cleavage reactions were quantitatively monitored by 1H-NMR / 29Si-NMR or FT-IR to derive the reaction kinetic parameters. The reaction behavior of most of the substrates differed from that expected based on the Flory's principle of equal reactivity.</p> <p> Among the hydroxide ion initiated cleavage reactions, the small molecules and the oligomeric analogs obeyed first-order kinetics, but the homopolymer and the copolymers deviated from first-order kinetics. This could be due to the low concentration of hydroxide ion in the polymer matrix, arising from the exclusion of polar hydroxide ion from the hydrophobic polymer matrix. The p-isopropylbenzyltrimethylsilane exhibited a lower pseudo first-order rate than benzyltrimethylsilane. This is attributed to an electron releasing substituent effect. Methyl methacrylate can accelerate the reaction on poly(vinylbenzyltrimethylsilane-co-methyl methacrylate) by increasing the overall copolymer polarity. The reverse is true for the corresponding styrene copolymers owing to the steric hindrance offered by the phenyl ring of styrene, and the enhanced hydrophobic repulsion against the access of hydroxide ion into the polymer matrix. An electrophilically assisted process was proposed as a principal reaction mechanism for this cleavage reaction. It was found that the only nucleophile attacking on silicon would be the hydroxide ion in KOH/EtOH/THF promoted reactions.</p> <p> Fluoride ion initiated cleavage reactions of substrates containing benzylic-silicon bonds were found to follow first-order kinetics. The reaction on small molecules was not studied due to their very rapid reaction at room temperature. The homopolymer of vinylbenzyltrimethylsilane exhibited a higher rate of reaction than the corresponding oligomer. However, the change in the reaction rate within a copolymer series, differing in molecular weight and composition, was not significant. Poly(VBTMS-co-MMA) exhibited a rate higher than that of styrene copolymers for polarity or steric reasons.</p> <p> Oxidative cleavage of benzylic-silicon bond by ceric ammonium nitrate (CAN) was found to obey first-order kinetics at 1:3 substrate to cerium(IV) ratio, and did not show any deviation in reaction order even at higher CAN concentration. The electron releasing isopropyl group reduces the oxidation potential of p-isopropylbenzyltrimethylsilane (ISO-BTMS), resulting in an enhanced reaction rate compared to benzyltrimethylsilane (BTMS). This rate accelerating substituent effect, together with a much higher negative value (-5.4) of Hammett reaction constant p is in accordance with the radical-cation mechanism operating in ceric ammonium nitrate promoted oxidation reactions. Significant loss of silane functionality was observed in reactions with polymeric substrates. This is attributed to the benzylic radical coupling reactions. The possibility of polymer backbone cleavage is ruled out for the following reasons: A) lack of significant molecular weight reduction in the oxidation products of polymeric substrates. B) about 100 times easier breaking of benzylic-silicon bond as trimethylsilyl cation than a hydrogen from carbon as proton, and the steric congestion offered by the polymer chain favors the benzylic radical formation only at the primary carbon, not on tertiary methine (C-H) on the chain.</p> / Thesis / Master of Science (MSc)

Directed Assembly of Block Copolymer Films Via Surface Energy Tunable Elastomers

Hayirlioglu, Arzu

January 2014

No description available.

Polymers

Block copolymer

elastomers

PDMS

PS-PMMA

orientation, flexible substrates

dewetting

<p>FISH COMMUNITY STRUCTURE, SUBSTRATE PARTICLE SIZE, AND PHYSICAL HABITAT: AN ANALYSIS OF REFERENCE STREAMS IN THE WESTERN ALLEGHENY PLATEAU ECOREGION OF SOUTHEAST OHIO</p>

Hughes, Ian Matthew

01 September 2006

No description available.

Reference sites

Stream substrates

Fish community structure

Physical habitat

Guilds

Correlations

IBI

QHEI

Index

Metrics

Residual stress in gallium nitride films grown on silicon substrates by metalorganic chemical vapor deposition

Fu, Yankun

January 2000

No description available.

Engineering, Chemical

Residual stress

gallium nitride films

silicon substrates

metalorganic deposition

chemical vapor deposition

Use Of Near-Zero Leachate Irrigation Systems For Container Production Of Woody Ornamental Plants

Sammons, Jonathan D.

January 2008

No description available.

Horticulture

Leachate

Controlled Release Fertilizers

Run-off

Taxodium

Baldcypress

Container Production

Container Substrates

Container Capcity

Electronic Defects of III-V Compound Semiconductor Materials Grown on Metamorphic SiGe Substrates for Photovoltaic Applications

Gonzalez, Maria -, -

29 September 2009

No description available.

Materials Science

GaAs

InGaP

solar cell

space photovoltaics

metamorphic

SiGe substrates

Comparison of the Colors of Dental Porcelain using Conventional and Press-on-Metal Ceramic Technologies for Four Substrate Metals

Khmaj, Abdulfatah B.EM

27 June 2012

No description available.

Dental Care

Dentistry

Materials Science

dental porcelain

color

metal substrates

press-on-metal porcelain application

Multifunctional and Moisture Tolerant Zinc-Based Mono- and Bi-metallic Metal-Organic Framework (MOF) thin films

Agbata, Emmanuel

16 April 2024

Many applications of metal-organic frameworks (MOFs) are highly dependent on their structures. The type and consistency of structure inform their properties. Zinc-based MOFs are applicable in different fields because of the low toxicity of zinc materials and are therefore also useful for catalysis. While MOF-5, a zinc-based MOF with carboxylate linkers is moisture intolerant, a variant of this is moisture tolerant. The introduction of a nitrogen-based linker in the zinc MOF which renders the structure moisture-tolerant. This material has not been explored as much, despite its multifunctional properties. Furthermore, the growth of Zn-based bimetallics of this MOF has not yet been explored. In this work, I studied the synthesis of this zinc-based moisture-tolerant MOF-5 as a thin film using a simple, fast, and cost-effective layer-by-layer wet synthesis method on different substrate surfaces. I successfully synthesized a series of bimetallics of this MOF as thin films on an untreated silicon wafer substrate. The successful synthesis of these materials was confirmed using X-ray photoelectron spectroscopy, X-ray diffraction, and Raman spectroscopy techniques. Additionally, some software data analysis tools were used for the characterization of the surface of the thin films to quantify the chemical composition. Future applications of these materials will be as sorbent materials for the capture of CO2 and its subsequent conversion to CO which is a synthesis gas for different useful materials like fuel and other chemical materials.

Metal-organic frameworks (MOFs)

thin films

bimetallics

dopant

crystallites

substrates

moisture-tolerant

Physical Sciences and Mathematics