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47 results on '"Barako, Michael T."'

1. Deep Vision-Inspired Bubble Dynamics on Hybrid Nanowires with Dual Wettability

Author

Lee, Jonggyu, Suh, Youngjoon, Kuciej, Max, Simadiris, Peter, Barako, Michael T., and Won, Yoonjin

Subjects
Physics - Applied Physics
Abstract

The boiling efficacy is intrinsically tethered to trade-offs between the desire for bubble nucleation and necessity of vapor removal. The solution to these competing demands requires the separation of bubble activity and liquid delivery, often achieved through surface engineering. In this study, we independently engineer bubble nucleation and departure mechanisms through the design of heterogeneous and segmented nanowires with dual wettability with the aim of pushing the limit of structure-enhanced boiling heat transfer performances. The demonstration of separating liquid and vapor pathways outperforms state-of-the-art hierarchical nanowires, in particular, at low heat flux regimes while maintaining equal performances at high heat fluxes. A machine vision-based framework realizes the autonomous curation and extraction of hidden big data along with bubble dynamics. The combined efforts of materials design, deep learning techniques, and data-driven approach shed light on the mechanistic relationship between vapor/liquid pathways, bubble statistics, and phase change performance., Comment: Jonggyu Lee and Youngjoon Suh contributed equally to this work

Published
2022

2. Approaching the Practical Conductivity Limits of Aerosol Jet Printed Silver

Author

Rosker, Eva S., Barako, Michael T., Nguyen, Evan, DiMarzio, Don, Kisslinger, Kim, Duan, Dah-Weih, Sandhu, Rajinder, Goorsky, Mark S., and Tice, Jesse

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Previous efforts to directly write conductive metals have been narrowly focused on nanoparticle ink suspensions that require aggressive sintering (>200 {\deg}C) and result in low-density, small-grained agglomerates with electrical conductivities <25% of bulk metal. Here, we demonstrate aerosol jet printing of a reactive ink solution and characterize high-density (93%) printed silver traces having near-bulk conductivity and grain sizes greater than the electron mean free path, while only requiring a low-temperature (80 {\deg}C) treatment. We have developed a predictive electronic transport model which correlates the microstructure to the measured conductivity and identifies a strategy to approach the practical conductivity limit for printed metals. Our analysis of how grain boundaries and tortuosity contribute to electrical resistivity provides insight into the basic materials science that governs how an ink formulator or process developer might approach improving the conductivity. Transmission line measurements validate that electrical properties are preserved up to 20 GHz, which demonstrates the utility of this technique for printed RF components. This work reveals a new method of producing robust printed electronics that retain the advantages of rapid prototyping and three-dimensional fabrication while achieving the performance necessary for success within the aerospace and communications industries.

Published
2020
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3. Experimental Demonstration of Dynamic Thermal Regulation using Vanadium Dioxide Thin Films

Author

Morsy, Ahmed M., Barako, Michael T., Jankovic, Vladan, Wheeler, Virginia D., Knight, Mark W., Papadakis, Georgia T., Sweatlock, Luke A., Hon, Philip W. C., and Povinelli, Michelle L.

Subjects
Physics - Applied Physics, Physics - Optics
Abstract

We present an experimental demonstration of passive, dynamic thermal regulation in a solid-state system with temperature-dependent thermal emissivity switching. We achieve this effect using a multilayered device, comprised of a vanadium dioxide (VO2) thin film on a silicon substrate with a gold back reflector. We experimentally characterize the optical properties of the VO2 film and use the results to optimize device design. Using a calibrated, transient calorimetry experiment we directly measure the temperature fluctuations arising from a time-varying heat load. Under laboratory conditions, we find that the device regulates temperature better than a constant emissivity sample. We use the experimental results to validate our thermal model, which can be used to predict device performance under the conditions of outer space. In this limit, thermal fluctuations are halved with reference to a constant-emissivity sample.

Published
2020
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12. Optimizing the design of composite phase change materials for high thermal power density.

Author

Barako, Michael T., Lingamneni, Srilakshmi, Katz, Joseph S., Liu, Tanya, Goodson, Kenneth E., and Tice, Jesse

Subjects
*PHASE change materials, *ENERGY density, *HEAT storage, *THERMAL conductivity, *THERMAL batteries
Abstract

Phase change materials (PCMs) provide a high energy density for thermal storage systems but often suffer from limited power densities due to the low PCM thermal conductivity. Much like their electrochemical analogs, an ideal thermal energy storage medium combines the energy density of a thermal battery with the power density of a thermal capacitor. Here, we define the design rules and identify the performance limits for rationally-designed composites that combine an energy dense PCM with a thermally conductive material. Beginning with the Stefan-Neumann model, we establish the material design space using a Ragone framework and identify regimes where hybrid conductive-capacitive composites have thermal power densities exceeding that of copper and other high conductivity materials. We invoke the mathematical bounds on isotropic conductivity to optimize and define the theoretical limits for transient cooling using PCM composites. We then demonstrate the impact of power density on thermal transients using copper inverse opals infiltrated with paraffin wax to suppress the temperature rise in kW cm−2 hotspots by ∼10% compared to equivalent copper thin film heat spreaders. These design rules and performance limits illuminate a path toward the rational design of composite phase change materials capable of buffering extreme transient thermal loads. [ABSTRACT FROM AUTHOR]

Published
2018
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18. Passive Thermal Homeostasis using Vanadium Dioxide Thin Films

Author

Morsy, Ahmed M., primary, Barako, Michael T., additional, Jankovic, Vladan, additional, Wheeler, Virginia D., additional, Knight, Mark, additional, Papadakis, Georgia, additional, Sweatlock, Luke A., additional, Hon, Philip W.C., additional, and Povinelli, Michelle L., additional

Published
2020
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26. Phonon Conduction in Silicon Nanobeam Labyrinths

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Romano, Giuseppe, Kolpak, Alexie M., Park, Woosung, Ahn, Ethan C., Kodama, Takashi, Park, Joonsuk, Barako, Michael T., Sohn, Joon, Kim, Soo Jin, Cho, Jungwan, Marconnet, Amy M., Asheghi, Mehdi, Goodson, Kenneth E., Massachusetts Institute of Technology. Department of Mechanical Engineering, Romano, Giuseppe, Kolpak, Alexie M., Park, Woosung, Ahn, Ethan C., Kodama, Takashi, Park, Joonsuk, Barako, Michael T., Sohn, Joon, Kim, Soo Jin, Cho, Jungwan, Marconnet, Amy M., Asheghi, Mehdi, and Goodson, Kenneth E.

Abstract

Here we study single-crystalline silicon nanobeams having 470 nm width and 80 nm thickness cross section, where we produce tortuous thermal paths (i.e. labyrinths) by introducing slits to control the impact of the unobstructed "line-of-sight" (LOS) between the heat source and heat sink. The labyrinths range from straight nanobeams with a complete LOS along the entire length to nanobeams in which the LOS ranges from partially to entirely blocked by introducing slits, s = 95, 195, 245, 295 and 395 nm. The measured thermal conductivity of the samples decreases monotonically from ∼47 W m⁻¹ K⁻¹ for straight beam to ∼31 W m⁻¹ K⁻¹ for slit width of 395 nm. A model prediction through a combination of the Boltzmann transport equation and ab initio calculations shows an excellent agreement with the experimental data to within ∼8%. The model prediction for the most tortuous path (s = 395 nm) is reduced by ∼14% compared to a straight beam of equivalent cross section. This study suggests that LOS is an important metric for characterizing and interpreting phonon propagation in nanostructures., National Science Foundation (U.S.) (Grant 1336734), United States. Department of Energy. Office of Basic Energy Sciences (Award DE-SC0001299), United States. Department of Energy. Office of Basic Energy Sciences (Award DE-FG02-09ER46577)

Published
2018

31. Phonon Conduction in Silicon Nanobeam Labyrinths

Author

Park, Woosung, primary, Romano, Giuseppe, additional, Ahn, Ethan C., additional, Kodama, Takashi, additional, Park, Joonsuk, additional, Barako, Michael T., additional, Sohn, Joon, additional, Kim, Soo Jin, additional, Cho, Jungwan, additional, Marconnet, Amy M., additional, Asheghi, Mehdi, additional, Kolpak, Alexie M., additional, and Goodson, Kenneth E., additional

Published
2017
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40. High heat flux two-phase cooling of electronics with integrated diamond/porous copper heat sinks and microfluidic coolant supply.

Author

Palko, James W., Hyoungsoon Lee, Agonafer, Damena D., Zhang, Chi, Ki Wook Jung, Moss, Jess, Wilbur, Joshua D., Dusseault, Tom J., Barako, Michael T., Houshmand, Farzad, Rong, Guoguang, Maitra, Tanmoy, Gorle, Catherine, Won, Yoonjin, Rockosi, Derrick, Mykyta, Ihor, Resler, Dan, Altman, David, Asheghi, Mehdi, and Santiago, Juan G.

Published
2016
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45. Effect of thermal cycling on commercial thermoelectric modules.

Author

Woosung Park, Barako, Michael T., Marconnet, Amy M., Asheghi, Mehdi, and Goodson, Kenneth E.

Abstract

The large temperature gradients experienced by thermoelectric modules induce significant thermal stresses which eventually lead to device failure. The impact of thermal cycling on a commercial thermoelectric module is investigated through characterization of the electrical properties. In this work, we measure the evolution of the thermoelectric and electrical properties with thermal cycling. One side of the thermoelectric module is cycled between 30oC and 160°C every 3 minutes while the other side is held at ∼20°C. The thermoelectric figure of merit, ZTET̄, and electrical resistivity are measured after every 1000 cycles. The measured ZTET̄ value is compared using both a modified Harman method and an electrical measurement technique analyzed with an electrical circuit model. In addition, the change in output power and resistivity with cycling are reported. This study provides insight into characterization methods for thermoelectric modules and quantifies reliability characteristics of thermoelectric modules. [ABSTRACT FROM PUBLISHER]

Published
2012
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46. A reliability study with infrared imaging of thermoelectric modules under thermal cycling.

Author

Barako, Michael T., Woosung Park, Marconnet, Amy M., Asheghi, Mehdi, and Goodson, Kenneth E.

Abstract

Thermoelectric (TE) modules undergo performance degradation and mechanical failure due to thermal cycling. In the present study, TE modules are subjected to thermal cycling, and the thermoelectric performance is evaluated at periodic intervals. Both the thermoelectric figure of merit, ZT, and the individual components of ZT are measured at each interval. The thermopower and thermal conductivity are measured using steady state infrared microscopy, and the electrical conductivity and ZT are evaluated using a variation of the Harman technique. These properties are tracked over many cycles until device failure. Critical failure occurred after 45,000 thermal cycles, and the mechanical failure of the TE module is analyzed using high-resolution infrared microscopy and scanning electron microscopy. These results quantify the effect of thermal cycling on a commercial TE module performance and provide insight into the packaging of a complete TE module for reliable operation. [ABSTRACT FROM PUBLISHER]

Published
2012
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47. Nanoscale conformable coatings for enhanced thermal conduction of carbon nanotube films.

Author

Marconnet, Amy M., Motoyama, Munekazu, Barako, Michael T., Yuan Gao, Pozder, Scott, Fowler, Burt, Ramakrishna, Koneru, Mortland, Glenn, Asheghi, Mehdi, and Goodson, Kenneth E.

Abstract

Vertically aligned carbon nanotube (CNT) arrays can provide the required combination of high thermal conductivity and mechanical compliance for thermal interface applications. Much work in the last 15 years has focused on improving the quality and intrinsic thermal conductivity of the nanotube arrays. Currently the thermal interface resistance between nanotube arrays and surrounding materials limits the overall thermal performance. To reduce this interface resistance, we propose coating the nanotube film with a continuous layer of metal. In this work, we electroplate 1 to 20 µm-thick continuous copper films directly on the carbon nanotube array. We measure the thermal conductivity of CNT arrays after electroplating using cross-sectional infrared microscopy. For low volume fraction, vertically-aligned carbon nanotubes arrays with copper electroplating (0.5 vol. %), the film thermal conductivity is nearly 3 W/m/K. These results demonstrate the feasibility of the electroplating method to coat CNT films. [ABSTRACT FROM PUBLISHER]

Published
2012
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