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150 results on '"Miller, Forrest"'

1. Beating bandwidth limits for large aperture broadband nano-optics

Author

Fröch, Johannes E., Chakravarthula, Praneeth K., Sun, Jipeng, Tseng, Ethan, Colburn, Shane, Zhan, Alan, Miller, Forrest, Wirth-Singh, Anna, Tanguy, Quentin A. A., Han, Zheyi, Böhringer, Karl F., Heide, Felix, and Majumdar, Arka

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Flat optics have been proposed as an attractive approach for the implementation of new imaging and sensing modalities to replace and augment refractive optics. However, chromatic aberrations impose fundamental limitations on diffractive flat optics. As such, true broadband high-quality imaging has thus far been out of reach for low f-number, large aperture, flat optics. In this work, we overcome these intrinsic fundamental limitations, achieving broadband imaging in the visible wavelength range with a flat meta-optic, co-designed with computational reconstruction. We derive the necessary conditions for a broadband, 1 cm aperture, f/2 flat optic, with a diagonal field of view of 30{\deg} and an average system MTF contrast of 30% or larger for a spatial frequency of 100 lp/mm in the visible band (> 50 % for 70 lp/mm and below). Finally, we use a coaxial, dual-aperture system to train the broadband imaging meta-optic with a learned reconstruction method operating on pair-wise captured imaging data. Fundamentally, our work challenges the entrenched belief of the inability of capturing high-quality, full-color images using a single large aperture meta-optic.

Published
2024

2. Non-volatile Phase-only Transmissive Spatial Light Modulators

Author

Fang, Zhuoran, Chen, Rui, Fröch, Johannes E., Tanguy, Quentin A. A., Khan, Asir Intisar, Wu, Xiangjin, Tara, Virat, Manna, Arnab, Sharp, David, Munley, Christopher, Miller, Forrest, Zhao, Yang, Geiger, Sarah J., Böhringer, Karl F., Reynolds, Matthew, Pop, Eric, and Majumdar, Arka

Subjects
Physics - Optics
Abstract

Free-space modulation of light is crucial for many applications, from light detection and ranging to virtual or augmented reality. Traditional means of modulating free-space light involves spatial light modulators based on liquid crystals and microelectromechanical systems, which are bulky, have large pixel areas (~10 micron x 10 micron), and require high driving voltage. Recent progress in meta-optics has shown promise to circumvent some of the limitations. By integrating active materials with sub-wavelength pixels in a meta-optic, the power consumption can be dramatically reduced while achieving a faster speed. However, these reconfiguration methods are volatile and hence require constant application of control signals, leading to phase jitter and crosstalk. Additionally, to control a large number of pixels, it is essential to implement a memory within each pixel to have a tractable number of control signals. Here, we develop a device with nonvolatile, electrically programmable, phase-only modulation of free-space infrared radiation in transmission using the low-loss phase-change material (PCM) Sb2Se3. By coupling an ultra-thin PCM layer to a high quality (Q)-factor (Q~406) diatomic metasurface, we demonstrate a phase-only modulation of ~0.25pi (~0.2pi) in simulation (experiment), ten times larger than a bare PCM layer of the same thickness. The device shows excellent endurance over 1,000 switching cycles. We then advance the device geometry, to enable independent control of 17 meta-molecules, achieving ten deterministic resonance levels with a 2pi phase shift. By independently controlling the phase delay of pixels, we further show tunable far-field beam shaping. Our work paves the way to realizing non-volatile transmissive phase-only spatial light modulators.

Published
2023

3. Rewritable Photonic Integrated Circuits Using Dielectric-assisted Phase-change Material Waveguides

Author

Miller, Forrest, Chen, Rui, Froech, Johannes E., Rarick, Hannah, Geiger, Sarah, and Majumdar, Arka

Subjects
Physics - Optics
Abstract

Photonic integrated circuits (PICs) have the potential to drastically expand the capabilities of optical communications, sensing, and quantum information science and engineering. However, PICs are commonly fabricated using selective material etching, a subtractive process. Thus, the chip's functionality cannot be substantially altered once fabricated. Here, we propose to exploit wide-bandgap non-volatile phase-change materials (PCMs) to create a rewritable PIC platform. A PCM-based PIC can be written using a nano-second pulsed laser without removing any material, akin to rewritable compact disks. The whole circuit can then be erased by heating, and a completely new circuit can be rewritten. We designed a dielectric-assisted PCM waveguide consisting of a thick dielectric layer on top of a thin layer of wide-bandgap PCMs Sb2S3 and Sb2Se3. The low-loss PCMs and our engineered waveguiding structure lead to a negligible optical loss. Furthermore, we analyzed and specified the spatio-temporal laser pulse shape to write the PCMs. Our proposed platform will enable low-cost manufacturing and have a far-reaching impact on the rapid prototyping of PICs, validation of new designs, and photonic education.

Published
2023
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4. Non-volatile electrically programmable integrated photonics with a 5-bit operation

Author

Chen, Rui, Fang, Zhuoran, Perez, Christopher, Miller, Forrest, Kumari, Khushboo, Saxena, Abhi, Zheng, Jiajiu, Geiger, Sarah J., Goodson, Kenneth E., and Majumdar, Arka

Subjects
Physics - Optics, Condensed Matter - Materials Science
Abstract

Scalable programmable photonic integrated circuits (PICs) can potentially transform the current state of classical and quantum optical information processing. However, traditional means of programming, including thermo-optic, free carrier dispersion, and Pockels effect result in either large device footprints or high static energy consumptions, significantly limiting their scalability. While chalcogenide-based non-volatile phase-change materials (PCMs) could mitigate these problems thanks to their strong index modulation and zero static power consumption, they often suffer from large absorptive loss, low cyclability, and lack of multilevel operation. Here, we report a wide-bandgap PCM antimony sulfide (Sb2S3)-clad silicon photonic platform simultaneously achieving low loss, high cyclability, and 5-bit operation. We switch Sb2S3 via an on-chip silicon PIN diode heater and demonstrate components with low insertion loss (<1.0 dB), high extinction ratio (>10 dB), and high endurance (>1,600 switching events). Remarkably, we find that Sb2S3 can be programmed into fine intermediate states by applying identical and thermally isolated pulses, providing a unique approach to controllable multilevel operation. Through dynamic pulse control, we achieve on-demand and accurate 5-bit (32 levels) operations, rendering 0.50 +- 0.16 dB contrast per step. Using this multilevel behavior, we further trim random phase error in a balanced Mach-Zehnder interferometer. Our work opens an attractive pathway toward non-volatile large-scale programmable PICs with low-loss and on-demand multi-bit operations., Comment: 22 pages, 6 figures in main text

Published
2023
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25. Fracture toughness and fatigue crack propagation rate of short fiber reinforced epoxy composites for analogue cortical bone

Author

Chong, Alexander C.M., Miller, Forrest, Buxton, McKee, and Friis, Elizabeth A.

Subjects
Fatigue testing machines -- Measurement, Compact bone -- Physiological aspects, Fibrous composites -- Mechanical properties, Materials -- Fatigue, Materials -- Measurement, Engineering and manufacturing industries, Science and technology
Abstract

Third-generation mechanical analogue bone models and synthetic analogue cortical bone materials manufactured by Pacific Research Laboratories, Inc. (PRL) are popular tools for use in mechanical testing of various orthopedic implants and biomaterials. A major issue with these models is that the current third-generation epoxy-short fiberglass based composite used as the cortical bone substitute is prone to crack formation and failure in fatigue or repeated quasistatic loading of the model. The purpose of the present study was to compare the tensile and fracture mechanics properties of the current baseline (established PRL 'third-generation' E-glass-fiber-epoxy) composite analogue for cortical bone to a new composite material formulation proposed for use as an enhanced fourth-generation cortical bone analogue material. Standard tensile, plane strain fracture toughness, and fatigue crack propagation rate tests were performed on both the thirdand fourth-generation composite material formulations using standard ASTM test techniques. Injection molding techniques were used to create random fiber orientation in all test specimens. Standard dog-bone style tensile specimens were tested to obtain ultimate tensile strength and stiffness. Compact tension fracture toughness specimens were utilized to determine plane strain fracture toughness values. Reduced thickness compact tension specimens were also used to determine fatigue crack propagation rate behavior for the two material groups. Literature values for the same parameters for human cortical bone were compared to results from the third- and fourth-generation cortical analogue bone materials. Tensile properties of the fourth-generation material were closer to that of average human cortical bone than the third-generation material. Fracture toughness was significantly increased by 48% in the fourth-generation composite as compared to the third-generation analogue bone. The threshold stress intensity to propagate the crack was much higher for the fourth-generation material than for the third-generation composite. Even at the higher stress intensity threshold, the fatigue crack propagation rate was significantly decreased in the fourth-generation composite compared to the thirdgeneration composite. These results indicate that the bone analogue models made from the fourth-generation analogue cortical bone material may exhibit better performance in fracture and longer fatigue lives than similar models made of third-generation analogue cortical bone material. Further fatigue testing of the new composite material in clinically relevant use of bone models is still required for verification of these results. Biomechanical test models using the superior fourth-generation cortical analogue material are currently in development. [DOI: 10.1115/1.2746369] Keywords: composite, cortical bone, fracture toughness, fatigue

Published
2007

27. Sensitivity to acute methadone dose changes in maintenance patients

Author

Robles, Elias, Gilmore-Thomas, Karen K., Miller, Forrest B., and McMillan, Donald E.

Subjects
Methadone maintenance -- Research, Health
Abstract

This study assessed whether methadone patients can identify acute dose changes in their maintenance dose, and explored the relationships between self-reported drug effects and real or perceived dose changes. Four times each week patients (N = 10) unpredictably received either 80%, 90%, 100%, 110% or 120% of their usual daily dose (50-100 mg). Approximately 24 hr later they indicated which dose they had received on the previous day, and rated the previous day's dose in terms of good effects, bad effects, and change in medication taste. Correct estimation of the doses received was always at the levels expected by chance alone. Furthermore, this sample of patients could not detect dose-related changes in medication taste. However, self-reports of good effects were significantly higher when patients believed that they had received a dose increment, and ratings of bad effects were higher when patients believed that they had received a dose decrement. Keywords: Methadone maintenance; Dosing; Drug discrimination; Opiates; Withdrawal

Published
2002

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