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- Alumina; anodisation; electrodeposition; nanofabrication; nanowires; porous materials; thermoelectric devices (2)
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- BISMUTH TELLURIDE NANOWIRES; HEXAGONAL PORE ARRAYS; HIGH-ASPECT-RATIO; ACID-SOLUTION; LARGE-AREA; FABRICATION; ELECTRODEPOSITION; ANODIZATION; GROWTH; FILMS (2)
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- FIELD-EFFECT TRANSISTORS; EFFECTIVE-MASS APPROXIMATION; HIGH-PERFORMANCE; NONEQUILIBRIUM PROCESSES; SEMICONDUCTOR-DEVICES; TRANSPORT; SINGLE; NANOTRANSISTORS; EQUATION; MOSFETS (1)
- FIELD-EFFECT TRANSISTORS; RAREFIED-GAS; PHONON TRANSPORT; SURFACE INTERACTIONS; BOLTZMANN-EQUATION; SILICON NANOWIRES; PRANDTL NUMBER; HEAT-TRANSFER; BGK EQUATION; SIMULATION (1)
Articles 1 - 30 of 64
Full-Text Articles in Engineering
Frequency-Domain Simulations Of A Negative-Index Material With Embedded Gain, Yonatan Sivan, Shumin Xiao, Uday K. Chettiar, Alexander V. Kildishev, V. M. Shalaev
Frequency-Domain Simulations Of A Negative-Index Material With Embedded Gain, Yonatan Sivan, Shumin Xiao, Uday K. Chettiar, Alexander V. Kildishev, V. M. Shalaev
Birck and NCN Publications
We solve the equations governing light propagation in a negative-index material with embedded nonlinearly saturable gain material using a frequency-domain model. We show that available gain materials can lead to complete loss compensation only if they are located in the regions where the field enhancement is maximal. We study the increased enhancement of the fields in the gain composite as well as in the metal inclusions and show analytically that the effective gain is determined by the average near-field enhancement.
Manifestation Of Kohn Anomaly In 1/F Fluctuations In Metallic Carbon Nanotubes, Ju Hee Back, Cheng-Lin Tsai, Sunkook Kim, Saeed Mohammadi, Moonsub Shim
Manifestation Of Kohn Anomaly In 1/F Fluctuations In Metallic Carbon Nanotubes, Ju Hee Back, Cheng-Lin Tsai, Sunkook Kim, Saeed Mohammadi, Moonsub Shim
Birck and NCN Publications
Low-frequency noise in metallic single walled carbon nanotubes is shown to be strongly dependent on the Fermi level position and the applied electric field across the nanotube. Resonance-like enhancement observed near optical phonon energy only when the Fermi level lies near the Dirac point is correlated to Raman G-band softening and broadening. The results suggest that the competition between zone-center and zone-boundary phonon scattering is the underlying origin of the large enhancement and resonance-like behavior of 1/f noise.
Generating Integrated-Circuit Patterns Via Cutting And Stitching Of Gratings, Lin Zhao, Yi Xuan, Minghao Qi
Generating Integrated-Circuit Patterns Via Cutting And Stitching Of Gratings, Lin Zhao, Yi Xuan, Minghao Qi
Birck and NCN Publications
Integrated-circuit patterns, such as those of transistor gates, usually consist of multivertex paths whose line segments are along two orthogonal directions. Such patterns are sometimes called "Manhattan structures" and are typically designed to achieve the highest packing density with a given linewidth. Owing to their arbitrary shapes, these patterns are predominantly generated via electron-beam lithography, a serial process which is inherently slow compared to parallel processes. Moreover, throughput is further reduced with the necessity of proximity correction in electron-beam lithography. On the other hand, interference lithography is a low-cost, parallel process that can achieve small linewidths and pitches, yet the …
Thermodynamics Of Hydrogen Vacancies In Mgh2 From First-Principles Calculations And Grand-Canonical Statistical Mechanics, R Grau-Crespo, K C. Smith, Timothy Fisher, N H. De Leeuw, U V. Waghmare
Thermodynamics Of Hydrogen Vacancies In Mgh2 From First-Principles Calculations And Grand-Canonical Statistical Mechanics, R Grau-Crespo, K C. Smith, Timothy Fisher, N H. De Leeuw, U V. Waghmare
Birck and NCN Publications
Ab initio calculations and statistical mechanics are combined to elucidate the thermodynamics of H vacancies in MgH2. A general method based on a grand-canonical ensemble of defect configurations is presented to model the exchange of hydrogen between crystalline MgH2 and gas-phase H-2. We find that, even at the lowest hydrogen partial pressures at which the hydride phase is stable, MgH2 is capable of accommodating only very small concentrations of hydrogen vacancies. These vacancies are mainly isolated rather than forming clusters, contrary to what is expected from a simple energetic analysis.
Observation Of Quantum-Hall Effect In Gated Epitaxial Graphene Grown On Sic (0001), T Shen, J J. Gu, M Xu, Michael Bolen, Michael A. Capano, L Engel, P. D. Ye
Observation Of Quantum-Hall Effect In Gated Epitaxial Graphene Grown On Sic (0001), T Shen, J J. Gu, M Xu, Michael Bolen, Michael A. Capano, L Engel, P. D. Ye
Birck and NCN Publications
Epitaxial graphene films examined were formed on the Si-face of semi-insulating 4H-SiC substrates by a high temperature sublimation process. A high-k gate stack on the epitaxial graphene was realized by inserting a fully oxidized nanometer thin aluminum film as a seeding layer, followed by an atomic-layer deposition process. The electrical properties of epitaxial graphene films are retained after gate stack formation without significant degradation. At low temperatures, the quantum-Hall effect in Hall resistance is observed along with pronounced Shubnikov-de Haas oscillations in diagonal magnetoresistance of gated epitaxial graphene on SiC (0001).
Determination Of Size Effects During The Phase Transition Of A Nanoscale Au-Si Eutectic, B J. Kim, J Tersoff, C-Y Wen, M C. Reuter, E A. Stach, F M. Ross
Determination Of Size Effects During The Phase Transition Of A Nanoscale Au-Si Eutectic, B J. Kim, J Tersoff, C-Y Wen, M C. Reuter, E A. Stach, F M. Ross
Birck and NCN Publications
The phase diagram of a nanoscale system can be substantially different than in the bulk, but quantitative measurements have proven elusive. Here we use in situ microscopy to observe a phase transition in a nanoscale system, together with a simple quantitative model to extract the size effects from these measurements. We expose a Au particle to disilane gas, and observe the transition from a two-phase Au þ AuSi system to single-phase AuSi. Size effects are evident in the nonlinear disappearance of the solid Au. Our analysis shows a substantial shift in the liquidus line, and a discontinuous change in the …
Gate-Induced G-Factor Control And Dimensional Transition For Donors In Multivalley Semiconductors, Rajib Rahman, Seung H. Park, Timothy B. Boykin, Gerhard Klimeck, Sven Rogge, Lloyd Cl Hollenberg
Gate-Induced G-Factor Control And Dimensional Transition For Donors In Multivalley Semiconductors, Rajib Rahman, Seung H. Park, Timothy B. Boykin, Gerhard Klimeck, Sven Rogge, Lloyd Cl Hollenberg
Birck and NCN Publications
The dependence of the g factors of semiconductor donors on applied electric and magnetic fields is of immense importance in spin-based quantum computation and in semiconductor spintronics. The donor g-factor Stark shift is sensitive to the orientation of the electric and magnetic fields and is strongly influenced by the band-structure and spin-orbit interactions of the host. Using a multimillion atom tight-binding framework, the spin-orbit Stark parameters are computed for donors in multivalley semiconductors, silicon, and germanium. Comparison with limited experimental data shows good agreement for a donor in silicon. Results for gate-induced transition from three-dimensional to two-dimensional wave-function confinement show …
Atomistic Full-Band Simulations Of Silicon Nanowire Transistors: Effects Of Electron-Phonon Scattering, Mathieu Luisier, Gerhard Klimeck
Atomistic Full-Band Simulations Of Silicon Nanowire Transistors: Effects Of Electron-Phonon Scattering, Mathieu Luisier, Gerhard Klimeck
Birck and NCN Publications
An atomistic full-band quantum transport simulator has been developed to study three-dimensional Si nanowire field-effect transistors in the presence of electron-phonon scattering. The nonequilibrium Green's function (NEGF) formalism is solved in a nearest-neighbor sp(3)d(5)s* tight-binding basis. The scattering self-energies are derived in the self-consistent Born approximation to inelastically couple the full electron and phonon energy spectra. The band dispersion and the eigenmodes of the confined phonons are calculated using a dynamical matrix that includes the bond and the angle deformations of the nanowires. The optimization of the numerical algorithms and the parallelization of the NEGF scheme enable the investigation of …
Orbital Stark Effect And Quantum Confinement Transition Of Donors In Silicon, Rajib Rahman, G P. Lansbergen, Seung H. Park, J Verduijn, Gerhard Klimeck, S Rogge, Lloyd Cl Hollenberg
Orbital Stark Effect And Quantum Confinement Transition Of Donors In Silicon, Rajib Rahman, G P. Lansbergen, Seung H. Park, J Verduijn, Gerhard Klimeck, S Rogge, Lloyd Cl Hollenberg
Birck and NCN Publications
Adiabatic shuttling of single impurity bound electrons to gate-induced surface states in semiconductors has attracted much attention in recent times, mostly in the context of solid-state quantum computer architecture. A recent transport spectroscopy experiment for the first time was able to probe the Stark shifted spectrum of a single donor in silicon buried close to a gate. Here, we present the full theoretical model involving large-scale quantum mechanical simulations that was used to compute the Stark shifted donor states in order to interpret the experimental data. Use of atomistic tight-binding technique on a domain of over a million atoms helped …
Orbital Stark Effect And Quantum Confinement Transition Of Donors In Silicon, Rajib Rahman, G P. Lansbergen, Seung H. Park, J Verduijn, Gerhard Klimeck, S Rogge, Lloyd Cl Hollenberg
Orbital Stark Effect And Quantum Confinement Transition Of Donors In Silicon, Rajib Rahman, G P. Lansbergen, Seung H. Park, J Verduijn, Gerhard Klimeck, S Rogge, Lloyd Cl Hollenberg
Birck and NCN Publications
Adiabatic shuttling of single impurity bound electrons to gate-induced surface states in semiconductors has attracted much attention in recent times, mostly in the context of solid-state quantum computer architecture. A recent transport spectroscopy experiment for the first time was able to probe the Stark shifted spectrum of a single donor in silicon buried close to a gate. Here, we present the full theoretical model involving large-scale quantum mechanical simulations that was used to compute the Stark shifted donor states in order to interpret the experimental data. Use of atomistic tight-binding technique on a domain of over a million atoms helped …
Gate-Induced G-Factor Control And Dimensional Transition For Donors In Multivalley Semiconductors, Rajib Rahman, Seung H. Park, Timothy B. Boykin, Gerhard Klimeck, Sven Rogge, Lloyd Cl Hollenberg
Gate-Induced G-Factor Control And Dimensional Transition For Donors In Multivalley Semiconductors, Rajib Rahman, Seung H. Park, Timothy B. Boykin, Gerhard Klimeck, Sven Rogge, Lloyd Cl Hollenberg
Birck and NCN Publications
The dependence of the g factors of semiconductor donors on applied electric and magnetic fields is of immense importance in spin-based quantum computation and in semiconductor spintronics. The donor g-factor Stark shift is sensitive to the orientation of the electric and magnetic fields and is strongly influenced by the band-structure and spin-orbit interactions of the host. Using a multimillion atom tight-binding framework, the spin-orbit Stark parameters are computed for donors in multivalley semiconductors, silicon, and germanium. Comparison with limited experimental data shows good agreement for a donor in silicon. Results for gate-induced transition from three-dimensional to two-dimensional wave-function confinement show …
Impact Of Sacrificial Layer Type On Thin-Film Metal Residual Stress, Anurag Garg, Joshua A. Small, Xiaoguang Liu, Ajit Mahapatro, Dimitrios Peroulis
Impact Of Sacrificial Layer Type On Thin-Film Metal Residual Stress, Anurag Garg, Joshua A. Small, Xiaoguang Liu, Ajit Mahapatro, Dimitrios Peroulis
Birck and NCN Publications
In this paper we study the impact of two sacrificial layers on the final residual stress of thin gold films. In particular, we comapre a typical photoresist layer (Shipley SC1827) to single-crystalline silicon. We fabricate and measure cantilever beams on both sacrificial layers and study their residual stresses by analyzing the final displacement profile of the released beams. All samples were fabricated at the same time and under identical conditions. The study clearly shows that the induced stress on thin films is dependent on the sacrificial layer. The gold film deposited over the single-crystalline silicon shows nearly zero gradient stress …
Molecular Dynamics Simulations Of Lattice Thermal Conductivity Of Bismuth Telluride Using Two-Body Interatomic Potentials, Bo Qiu, X Ruan
Molecular Dynamics Simulations Of Lattice Thermal Conductivity Of Bismuth Telluride Using Two-Body Interatomic Potentials, Bo Qiu, X Ruan
Birck and NCN Publications
Two-body interatomic potentials in the Morse potential form have been developed for bismuth telluride, and the potentials are used in molecular dynamics simulations to predict the thermal conductivity. The density-functional theory with local-density approximations is first used to calculate the total energies for many artificially distorted Bi2Te3 configurations to produce the energy surface. Then by fitting to this energy surface and other experimental data, the Morse potential form is parameterized. The fitted empirical interatomic potentials are shown to reproduce the elastic and phonon data well. Molecular dynamics simulations are then performed to predict the thermal conductivity of bulk Bi2Te3 at …
Determination Of Size Effects During The Phase Transition Of A Nanoscale Au-Si Eutectic, B J. Kim, J Tersoff, C Y. Wen, M C. Reuter, E A. Stach, F M. Ross
Determination Of Size Effects During The Phase Transition Of A Nanoscale Au-Si Eutectic, B J. Kim, J Tersoff, C Y. Wen, M C. Reuter, E A. Stach, F M. Ross
Birck and NCN Publications
The phase diagram of a nanoscale system can be substantially different than in the bulk, but quantitative measurements have proven elusive. Here we use in situ microscopy to observe a phase transition in a nanoscale system, together with a simple quantitative model to extract the size effects from these measurements. We expose a Au particle to disilane gas, and observe the transition from a two-phase Au + AuSi system to single-phase AuSi. Size effects are evident in the nonlinear disappearance of the solid Au. Our analysis shows a substantial shift in the liquidus line, and a discontinuous change in the …
Observation Of Quantum-Hall Effect In Gated Epitaxial Graphene Grown On Sic (0001), T Shen, J J. Gu, Y Q. Wu, M L. Bolen, Michael A. Capano, L W. Engel, P. D. Ye
Observation Of Quantum-Hall Effect In Gated Epitaxial Graphene Grown On Sic (0001), T Shen, J J. Gu, Y Q. Wu, M L. Bolen, Michael A. Capano, L W. Engel, P. D. Ye
Birck and NCN Publications
Epitaxial graphene films examined were formed on the Si-face of semi-insulating 4H-SiC substrates by a high temperature sublimation process. A high-k gate stack on the epitaxial graphene was realized by inserting a fully oxidized nanometer thin aluminum film as a seeding layer, followed by an atomic-layer deposition process. The electrical properties of epitaxial graphene films are retained after gate stack formation without significant degradation. At low temperatures, the quantum-Hall effect in Hall resistance is observed along with pronounced Shubnikov-de Haas oscillations in diagonal magnetoresistance of gated epitaxial graphene on SiC (0001).
Molecular Dynamics Simulations Of Lattice Thermal Conductivity Of Bismuth Telluride Using Two-Body Interatomic Potentials, Bo Qiu, X Ruan
Molecular Dynamics Simulations Of Lattice Thermal Conductivity Of Bismuth Telluride Using Two-Body Interatomic Potentials, Bo Qiu, X Ruan
Birck and NCN Publications
Two-body interatomic potentials in the Morse potential form have been developed for bismuth telluride, and the potentials are used in molecular dynamics simulations to predict the thermal conductivity. The density-functional theory with local-density approximations is first used to calculate the total energies for many artificially distorted Bi2Te3 configurations to produce the energy surface. Then by fitting to this energy surface and other experimental data, the Morse potential form is parameterized. The fitted empirical interatomic potentials are shown to reproduce the elastic and phonon data well. Molecular dynamics simulations are then performed to predict the thermal conductivity of bulk Bi2Te3 at …
Sers In Salt Wells, G. V. Pavan Kumar, Joseph Irudayaraj
Sers In Salt Wells, G. V. Pavan Kumar, Joseph Irudayaraj
Birck and NCN Publications
We report herein a simple, inexpensive fabrication methodology of salt microwells, and define the utility of the latter as nanoparticle containers for highly sensitive surface-enhanced Raman scattering (SERS) studies. AFM characterization of Ag and Au loaded salt microwells reveal the ability to contain favorable nanostructures such as nanoparticle dimers, which can significantly enhance the Raman intensity of molecules. By performing diffraction-limited confocal Raman microscopy on salt microwells, we show high sensitivity and fidelity in the detection of dyes, peptides, and proteins, as a proof of our concept. The SERS limit of detection (accumulation time of 1 s) for rhodamine B …
Mapping Donor Electron Wave Function Deformations At A Sub-Bohr Orbit Resolution, Seung Park, Rajib Rahman, Gerhard Klimeck, Lloyd Cl Hollenberg
Mapping Donor Electron Wave Function Deformations At A Sub-Bohr Orbit Resolution, Seung Park, Rajib Rahman, Gerhard Klimeck, Lloyd Cl Hollenberg
Birck and NCN Publications
Quantum wave function engineering of dopant-based Si nanostructures reveals new physics in the solid state, and is expected to play a vital role in future nanoelectronics. Central to any fundamental understanding or application is the ability to accurately characterize the deformation of the electron wave functions in these atom-based structures through electric and magnetic field control. We present a method for mapping the subtle changes that occur in the electron wave function through the measurement of the hyperfine tensor probed by Si-29 impurities. We calculate Stark parameters for six shells around the donor. Our results show that detecting the donor …
Optically Induced Electrokinetic Patterning And Manipulation Of Particles, Stuart J. Williams, Aloke Kumar, Steven Wereley
Optically Induced Electrokinetic Patterning And Manipulation Of Particles, Stuart J. Williams, Aloke Kumar, Steven Wereley
Birck and NCN Publications
The ability to easily and dynamically control fluid mo- tion as well as manipulate particles in suspension is impor- tant for the development and characterization of a variety of lab-on-a-chip processes. Recently, we have introduced an op- tically induced electrokinetic technique termed rapid electro- kinetic patterning (REP) that can rapidly concentrate, trans- late, and pattern colloids of many different sizes and compositions. We have tested polystyrene, latex, and silica beads in sizes ranging from 49 nm to 3.0 um.1,2
Graphene Formation Mechanisms On 4h-Sic(0001), Michael Bolen, Sara E. Harrison, Laura B. Biedermann, Michael A. Capano
Graphene Formation Mechanisms On 4h-Sic(0001), Michael Bolen, Sara E. Harrison, Laura B. Biedermann, Michael A. Capano
Birck and NCN Publications
Graphene is created through thermal decomposition of the Si face of 4H-SiC in high-vacuum. Growth temperature and time are varied independently to gain a better understanding of how surface features and morphology affect graphene formation. Growth mechanisms of graphene are studied by ex situ atomic force microscopy (AFM) and scanning tunneling microscopy (STM). On the route toward a continuous graphene film, various growth features, such as macroscale step bunching, terrace pits, and fingers, are found and analyzed. Topographic and phase AFM analysis demonstrates how surface morphology changes with experimental conditions. Step-bunched terraces and terrace pits show a strong preference for …
Graphene Formation Mechanisms On 4h-Sic(0001), Michael Bolen, Sara E. Harrison, Laura Biedermann, Michael A. Capano
Graphene Formation Mechanisms On 4h-Sic(0001), Michael Bolen, Sara E. Harrison, Laura Biedermann, Michael A. Capano
Birck and NCN Publications
Graphene is created through thermal decomposition of the Si face of 4H-SiC in high-vacuum. Growth temperature and time are varied independently to gain a better understanding of how surface features and morphology affect graphene formation. Growth mechanisms of graphene are studied by ex situ atomic force microscopy (AFM) and scanning tunneling microscopy (STM). On the route toward a continuous graphene film, various growth features, such as macroscale step bunching, terrace pits, and fingers, are found and analyzed. Topographic and phase AFM analysis demonstrates how surface morphology changes with experimental conditions. Step-bunched terraces and terrace pits show a strong preference for …
Self-Supporting Nanowire Arrays Templated In Sacrificial Branched Porous Anodic Alumina For Thermoelectric Devices, Kalapi G. Biswas, Hatem El Matbouly, Vijay Rawat, Jeremy L. Schroeder, Timothy D. Sands
Self-Supporting Nanowire Arrays Templated In Sacrificial Branched Porous Anodic Alumina For Thermoelectric Devices, Kalapi G. Biswas, Hatem El Matbouly, Vijay Rawat, Jeremy L. Schroeder, Timothy D. Sands
Birck and NCN Publications
Templated synthesis of thermoelectric nanowires in porous anodic alumina (PAA) have potential for enhanced performance relative to bulk materials. A significant challenge is the template material, which can serve as a thermal shunt. In this work, an approach for creating a branched PAA template is described. The process utilizes localized self-heating to destabilize the planar anodization front, yielding branched and interconnected pores growing at a rate of 300 mu m/h. The template is selectively etched after electrodeposition of desired materials, yielding self-supporting nanowire arrays with thicknesses up to about 300 mu m, thereby eliminating the thermal shunt through the template.
Thermionic Emission Energy Distribution From Nanocrystalline Diamond Films For Direct Thermal-Electrical Energy Conversion Applications, Kishore Uppireddi, Tyler Westover, Timothy Fisher, Brad H. Weiner, Gerardo Morell
Thermionic Emission Energy Distribution From Nanocrystalline Diamond Films For Direct Thermal-Electrical Energy Conversion Applications, Kishore Uppireddi, Tyler Westover, Timothy Fisher, Brad H. Weiner, Gerardo Morell
Birck and NCN Publications
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum and solid-state thermionic emission devices is one of the potentially efficient pathways for converting thermal energy directly into electrical power. The realization of practical of thermionic energy conversion devices strongly depends on achieving low work function materials, which is thus far a limiting factor. In an attempt to develop a new low work function thermionic material, this work reports thermionic emission energy distributions (TEEDs) from nanocrystalline diamond (NCD) films in the temperature range from 700 to 900 degrees C that reveal a consistent effective work function …
Thermionic Emission Energy Distribution From Nanocrystalline Diamond Films For Direct Thermal-Electrical Energy Conversion Applications, Kishore Uppireddi, Tyler Westover, Timothy Fisher, Brad Weiner, Gerardo Morell
Thermionic Emission Energy Distribution From Nanocrystalline Diamond Films For Direct Thermal-Electrical Energy Conversion Applications, Kishore Uppireddi, Tyler Westover, Timothy Fisher, Brad Weiner, Gerardo Morell
Birck and NCN Publications
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum and solid-state thermionic emission devices is one of the potentially efficient pathways for converting thermal energy directly into electrical power. The realization of practical of thermionic energy conversion devices strongly depends on achieving low work function materials, which is thus far a limiting factor. In an attempt to develop a new low work function thermionic material, this work reports thermionic emission energy distributions (TEEDs) from nanocrystalline diamond (NCD) films in the temperature range from 700 to 900 °C that reveal a consistent effective work function of …
Stable And Reproducible Electronic Conduction Through Dna Molecular Junctions, Ajit K. Mahapatro, Gil Lee, Kyung J. Jeong, David B. Janes
Stable And Reproducible Electronic Conduction Through Dna Molecular Junctions, Ajit K. Mahapatro, Gil Lee, Kyung J. Jeong, David B. Janes
Birck and NCN Publications
This letter presents the observation of stable and reproducible electronic conduction through double stranded (ds) DNA molecules in a nominally dry state. Stable conduction was realized by immobilizing 15 base-pair guanine:cytosine rich dsDNA within gold nanogap junctions, stabilizing the dsDNA with a polycation, and characterizing in nitrogen. In air, the current levels decrease with successive voltage scans likely due to oxidation of the guanine bases under bias. In nitrogen, reproducible current-voltage traces are observed and the current levels at specific bias points are stable with time. The stability allows comprehensive electrical studies and could enable conductance-based DNA sensors.
Self-Supporting Nanowire Arrays Templated In Sacrificial Branched Porous Anodic Alumina For Thermoelectric Devices, Kalapi G. Biswas, Hatem El Matbouly, Vijay Rawat, Jeremy L. Schroeder, Timothy D. Sands
Self-Supporting Nanowire Arrays Templated In Sacrificial Branched Porous Anodic Alumina For Thermoelectric Devices, Kalapi G. Biswas, Hatem El Matbouly, Vijay Rawat, Jeremy L. Schroeder, Timothy D. Sands
Birck and NCN Publications
Templated synthesis of thermoelectric nanowires in porous anodic alumina (PAA) have potential for enhanced performance relative to bulk materials. A significant challenge is the template material, which can serve as a thermal shunt. In this work, an approach for creating a branched PAA template is described. The process utilizes localized self-heating to destabilize the planar anodization front, yielding branched and interconnected pores growing at a rate of 300 mu m/h. The template is selectively etched after electrodeposition of desired materials, yielding self-supporting nanowire arrays with thicknesses up to about 300 mu m, thereby eliminating the thermal shunt through the template.
Strain Relaxation In Si/Ge/Si Nanoscale Bars From Molecular Dynamics Simulations, Yumi Park, Hasan Atkulga, Ananth Y. Grama, Alejandro Strachan
Strain Relaxation In Si/Ge/Si Nanoscale Bars From Molecular Dynamics Simulations, Yumi Park, Hasan Atkulga, Ananth Y. Grama, Alejandro Strachan
Birck and NCN Publications
We use molecular dynamics (MD) with the reactive interatomic potential ReaxFF to characterize the local strains of epitaxial Si/Ge/Si nanoscale bars as a function of their width and height. While the longitudinal strain (along the bars length) is independent of geometry, surface relaxation leads to transverse strain relaxation in the Ge section. This strain relaxation increases with increasing height of the Ge section and reduction in its width and is complete (i.e., zero transverse strain) for roughly square cross sections of Ge leading to a uniaxial strain state. Such strain state is desirable in some microelectronics applications. From the MD …
Strain Relaxation In Si/Ge/Si Nanoscale Bars From Molecular Dynamics Simulations, Yumi Park, Hasan Metin Atkulga, Ananth Y. Grama, Alejandro Strachan
Strain Relaxation In Si/Ge/Si Nanoscale Bars From Molecular Dynamics Simulations, Yumi Park, Hasan Metin Atkulga, Ananth Y. Grama, Alejandro Strachan
Birck and NCN Publications
We use molecular dynamics (MD) with the reactive interatomic potential ReaxFF to characterize the local strains of epitaxial Si/Ge/Si nanoscale bars as a function of their width and height. While the longitudinal strain (along the bars length) is independent of geometry, surface relaxation leads to transverse strain relaxation in the Ge section. This strain relaxation increases with increasing height of the Ge section and reduction in its width and is complete (i.e., zero transverse strain) for roughly square cross sections of Ge leading to a uniaxial strain state. Such strain state is desirable in some microelectronics applications. From the MD …
Modeling Of Subcontinuum Thermal Transport Across Semiconductor-Gas Interfaces, Druv Singh, Xiaohui Guo, Alina Alexeenko, Jayathi Y. Murthy, Timothy Fisher
Modeling Of Subcontinuum Thermal Transport Across Semiconductor-Gas Interfaces, Druv Singh, Xiaohui Guo, Alina Alexeenko, Jayathi Y. Murthy, Timothy Fisher
Birck and NCN Publications
A physically rigorous computational algorithm is developed and applied to calculate subcontinuum thermal transport in structures containing semiconductor-gas interfaces. The solution is based on a finite volume discretization of the Boltzmann equation for gas molecules (in the gas phase) and phonons (in the semiconductor). A partial equilibrium is assumed between gas molecules and phonons at the interface of the two media, and the degree of this equilibrium is determined by the accommodation coefficients of gas molecules and phonons on either side of the interface. Energy balance is imposed to obtain a value of the interface temperature. The classic problem of …
Tunable Magnetic Response Of Metamaterials, Shumin Xiao, Uday K. Chettiar, Alexander V. Kildishev, V. Drachev, I C. Khoo, V. M. Shalaev
Tunable Magnetic Response Of Metamaterials, Shumin Xiao, Uday K. Chettiar, Alexander V. Kildishev, V. Drachev, I C. Khoo, V. M. Shalaev
Birck and NCN Publications
We demonstrate a thermally tunable optical metamaterial with negative permeability working in the visible range. By covering coupled metallic nanostrips with aligned nematic liquid crystals (NLCs), the magnetic response wavelength of the metamaterial is effectively tuned through control of the ambient temperature, changing the refractive index of LC via phase transitions. By increasing the ambient temperature from 20 to 50 degrees C, the magnetic response wavelength shifts from 650 to 632 nm. Numerical simulations confirm our tests and match the experimental observations well.