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82 results on '"Bosworth, Bryan T."'

1. Acoustic resonators above 100 GHz

Author

Kramer, Jack, Bosworth, Bryan T., Matto, Lezli, Jungwirth, Nicholas R., Barrera, Omar, Bergmann, Florian, Cho, Sinwoo, Chulukhadze, Vakhtang, Goorsky, Mark, Orloff, Nathan D., and Lu, Ruochen

Subjects
Physics - Applied Physics
Abstract

Piezoelectric resonators are a common building block for signal processing because of their miniature size, low insertion loss, and high quality factor. As consumer electronics push to millimeter waves frequencies, designers must increase the operating frequency of the resonator. The current state-of-the-art approach to increase the operating frequency is to decrease the thickness of the piezoelectric film to shorten the acoustic wavelength or to use higher order modes. Unfortunately, maintaining high crystal quality typically requires thicker piezoelectric layers. Thinner layers suffer from higher defect densities and increased surface damping, which degrade the electromechanical coupling and quality factor. While acoustic high order modes can also increase operating frequency, the electromechanical coupling rapidly decreases with increasing mode number. Here, we overcome these limitations by utilizing a piezoelectric stack of three layers of lithium niobate with alternating crystallographic orientations to preferentially support higher order modes and thereby enhance the electromechanical coupling without degrading the quality factor. Our approach improves the figure of merit of millimeter-wave acoustic resonators by roughly an order of magnitude greater compared to state-of-the-art piezoelectric resonators above 60 GHz. This concept of alternating crystallographic orientations facilitates a new path to develop millimeter wave resonators with high figures of merit, low insertion loss, and miniature footprints, enabling new applications in millimeter wave signal processing and computing.

Published
2025

2. Information-Dense Nonlinear Photonic Physical Unclonable Function

Author

Grubel, Brian C., Bosworth, Bryan T., Kossey, Michael R., Cooper, A. Brinton, Foster, Mark A., and Foster, Amy C.

Subjects
Physics - Optics, Computer Science - Cryptography and Security
Abstract

We present a comprehensive investigation into the complexity of a new private key storage apparatus: a novel silicon photonic physical unclonable function (PUF) based on ultrafast nonlinear optical interactions in a chaotic silicon microcavity that is both unclonable and impossible to emulate. This device provides remarkable improvements to total information content (raw cryptographic material), information density, and key generation rates over existing optical scattering PUFs and is also more easily integrated with both CMOS electronics and telecommunications hardware. Our device exploits the natural nonlinear optical behavior of silicon to neutralize commonly used attacks against PUFs and vastly enhance device complexity. We confirm this phenomenon with thorough experimental results on prototype devices and present a detailed estimate of their total information content. Our compact, micron-scale approach represents an entirely new generation of ultrafast and high information density photonic PUF devices that can be directly incorporated into integrated circuits to ensure authenticity and provide secure physical storage of private key material.

Published
2017

3. Secure Communications using Nonlinear Silicon Photonic Keys

Author

Grubel, Brian C., Bosworth, Bryan T., Kossey, Michael R., Cooper, A. Brinton, Foster, Mark A., and Foster, Amy C.

Subjects
Computer Science - Cryptography and Security, Physics - Optics
Abstract

We present a secure communication system constructed using pairs of nonlinear photonic physical unclonable functions (PUFs) that harness physical chaos in integrated silicon micro-cavities. Compared to a large, electronically stored one-time pad, our method provisions large amounts of information within the intrinsically complex nanostructure of the micro-cavities. By probing a micro-cavity with a rapid sequence of spectrally-encoded ultrafast optical pulses and measuring the lightwave responses, we experimentally demonstrate the ability to extract 2.4 Gb of key material from a single micro-cavity device. Subsequently, in a secure communications experiment with pairs of devices, we achieve bit error rates below $10^{-5}$ at code rates of up to 0.1. The PUFs' responses are never transmitted over the channel or stored in digital memory, thus enhancing security of the system. Additionally, the micro-cavity PUFs are extremely small, inexpensive, robust, and fully compatible with telecommunications infrastructure, components, and electronic fabrication. This approach can serve one-time pad or public key exchange applications where high security is required, Comment: 12 pages. Replaced with revised version

Published
2017
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4. Glass Microwave Microfluidic Devices for Broadband Characterization of Diverse Fluids

Author

Pawlik, Jacob T., Karpisz, Tomasz, Kazemipour, Yasaman, Derimow, Nicholas, Evans, Sarah R., Bosworth, Bryan T., Booth, James C., Orloff, Nathan D., Long, Christian J., and Stelson, Angela C.

Abstract

We demonstrate a glass microwave microfluidic device for determining the permittivity of a wide range of liquid chemicals from 100 MHz to 30 GHz with associated uncertainties. Conventional microwave microfluidic devices use polymer-based microfluidic layers for fluid delivery, but these polymers swell in organic solvents and are not suitable for many applications. Our device incorporates glass microfluidic channels with platinum coplanar waveguides (CPWs) to provide a solvent-resistant architecture for broadband dielectric spectroscopy. We utilize broadband scattering parameter measurements with a vector network analyzer (VNA) on a wafer probing station and multiline thru-reflect–line (mTRL) calibrations to extract the distributed circuit parameters of transmission lines and solve for fluid permittivity. In this work, we demonstrate the utility of the device by measuring the permittivity of four organic solvents difficult to measure otherwise: hexane, heptane, decane, and toluene.

Published
2025
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7. Measuring the anisotropic permittivity tensor of DyScO3 to 110 GHz

Author

Bergmann, Florian, primary, Papac, Meagan C., additional, Jungwirth, Nicholas R., additional, Bosworth, Bryan T., additional, Karpisz, Tomasz, additional, Enright, Lucas, additional, Osella, Anna, additional, Marksz, Eric J., additional, Stelson, Angela C., additional, Long, Christian J., additional, and Orloff, Nathan D., additional

Published
2023
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8. Measuring the anisotropic permittivity tensor of DyScO3 to 110 GHz.

Author

Bergmann, Florian, Papac, Meagan C., Jungwirth, Nicholas R., Bosworth, Bryan T., Karpisz, Tomasz, Enright, Lucas, Osella, Anna, Marksz, Eric J., Stelson, Angela C., Long, Christian J., and Orloff, Nathan D.

Subjects
PERMITTIVITY, COPLANAR waveguides, ORTHOGONALIZATION, THIN films, DIELECTRICS, PERMITTIVITY measurement
Abstract

DyScO3 (DSO) is an attractive substrate on which to grow epitaxial thin films with extraordinary materials physics. However, its highly anisotropic permittivity makes some measurements exceedingly difficult: For instance, its permittivity tensor has not yet been fully characterized at millimeter-wave frequencies. While there are methods to characterize anisotropic permittivity at millimeter-wave frequencies, there are very few methods those are suitable for the small lateral dimensions that DyScO3 can be grown in. To overcome this lack in the material characterization, we tested an on-wafer method based on coplanar waveguides to measure the full anisotropic permittivity tensor from 0.1 to 110 GHz. We characterized two orthogonal sets of coplanar waveguides fabricated on each of two substrates with (001) and (110) crystallographic orientations to resolve the full permittivity tensor. To validate our measurements, we compared our results to data from dc parallel plate capacitors and THz time-domain spectroscopy. Our measurements fill the need for measurements of the permittivity of DyScO3, while the methodology, more generally, enables quantitative characterization of anisotropic dielectrics. [ABSTRACT FROM AUTHOR]

Published
2023
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10. High-Gain 500-GHz InP HBT Power Amplifiers

Author

Cheron, Jerome, primary, Jones, Rob D., additional, Chamberlin, Richard A., additional, Williams, Dylan F., additional, Urteaga, Miguel E., additional, Smith, Kassiopeia A., additional, Jungwirth, Nicholas R., additional, Bosworth, Bryan T. L., additional, Long, Christian J., additional, Orloff, Nathan D., additional, Aaen, Peter H., additional, and Feldman, Ari D., additional

Published
2021
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11. Electro-optically derived millimeter-wave sources with phase and amplitude control

Author

Bosworth, Bryan T., primary, Jungwirth, Nick R., additional, Smith, Kassiopeia, additional, Cheron, Jerome, additional, Quinlan, Franklyn, additional, Woodson, Madison, additional, Morgan, Jesse, additional, Beling, Andreas, additional, Feldman, Ari, additional, Williams, Dylan, additional, Orloff, Nathan D., additional, and Long, Christian J., additional

Published
2021
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12. Three-dimensional closed-form model for potential barrier in undoped FinFETs resulting in analytical equations for [V.sub.T] and subthreshold slope

Author

Kloes, Alexander, Weidemann, Michaela, Goebel, Daniel, and Bosworth, Bryan T.

Subjects
Metal oxide semiconductor field effect transistors -- Electric properties, Metal oxide semiconductor field effect transistors -- Research, Numerical analysis -- Usage, Harmonic functions -- Usage, Business, Electronics, Electronics and electrical industries
Abstract

An analytical approach is described for calculating the three-dimensional (3-D) electrostatic potential in undoped triple-gate SOI MOS devices. The results have helped in deriving models for subthreshold slope and threshold voltage of nanoscale triple-gate FETs.

Published
2008

13. Unclonable photonic keys hardened against machine learning attacks

Author

Bosworth, Bryan T., primary, Atakhodjaev, Iskandar A., additional, Kossey, Michael R., additional, Grubel, Brian C., additional, Vresilovic, Daniel S., additional, Stroud, Jasper R., additional, MacFarlane, Neil, additional, Villalba, Jesús, additional, Dehak, Najim, additional, Cooper, A. Brinton, additional, Foster, Mark A., additional, and Foster, Amy C., additional

Published
2020
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14. Silicon Photonic Cryptographic Engines

Author

Bosworth, Bryan T., primary, Grubel, Brian C., additional, Kossey, Michael R., additional, Cooper, A. Brinton, additional, Foster, Mark A., additional, and Foster, Amy C., additional

Published
2018
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20. Silicon photonic physical unclonable function

Author

Grubel, Brian C., primary, Bosworth, Bryan T., additional, Kossey, Michael R., additional, Sun, Hongcheng, additional, Cooper, A. Brinton, additional, Foster, Mark A., additional, and Foster, Amy C., additional

Published
2017
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48. Compressive fluorescence imaging using a multi-core fiber and spatially dependent scattering

Author

Shin, Jaewook, Bosworth, Bryan T., and Foster, Mark A.

Abstract

We demonstrate imaging using a multi-core fiber with a scattering distal tip and compressed sensing signal acquisition. We illuminate objects with randomly structured speckle patterns generated by a coherent light source separately coupled through each fiber core to a ground glass diffuser at the distal end. Using the characterized speckle patterns and the total light collected from the object, we computationally recover pixelation-free object images with up to a seven times higher space-bandwidth product than the number of cores. The proposed imaging system is insensitive to bending of the fiber and extremely compact, making it suitable for minimally invasive endomicroscopy.

Published
2017

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