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164 results on '"Dames C"'

1. Impact of size and thermal gradient on supercooling of phase change materials for thermal energy storage

Author

Lilley, D, Lau, J, Dames, C, Kaur, S, and Prasher, R

Subjects
Phase change materials, PCM, Thermal energy storage, Subcooling, Supercooling, Crystallization, Energy, Engineering, Economics
Abstract

Phase change material based thermal energy storage has many current and potential applications in the heating and cooling of buildings, battery and electronics thermal management, thermal textiles, and dry cooling of power plants. However, connecting lab scale thermal data obtained with differential scanning calorimetry (DSC) to the performance of large-scale practical systems has been a major challenge primarily due to the dependence of supercooling on the size and temperature gradient of the system. In this work we show how a phase change material's supercooling behavior can be characterized experimentally using common lab scale thermal analysis techniques. We then develop a statistics based theoretical model that uses the lab-scale data on small samples to quantitatively predict the supercooling performance for a general thermal energy storage application of any size, including also allowing for the possibility of temperature gradients. Finally, we validate the modeling methodology by comparing to experimental results for solid-solid phase change in neopentyl glycol, which shows how the model successfully predicts the changes in supercooling temperature across a large range of cooling rates (2 orders of magnitude) and volumes (3 orders of magnitude). By accounting for thermal gradients, the model avoids ~2x error incurred by lumped approximations.

Published
2021

2. Melting point depression and phase identification of sugar alcohols encapsulated in zif nanopores

Author

Dames, C, Urban, JJ, and Kang, H

Subjects
Physical Chemistry, Chemical Sciences, Engineering, Technology
Abstract

Sugar alcohols (SAs) have attractive characteristics as phase-change materials, but their relatively high melting temperature limits their application in the real world. Nanoconfinement can be a useful parameter to reduce the melting temperature to pragmatic ranges. Using molecular dynamics simulations, we investigate the phases and behaviors of encapsulated SA in ZIF-8 and ZIF-11, which cannot be experimentally observed. Based on reliable partial charges for the zeolitic imidazolate framework (ZIF) structures calculated by a density functional theory, structural analysis shows that the SA's attractive interaction with the ZIF structure frustrates the SA crystallization and also elucidates the second-order phase transition between amorphous phases. A methodology is suggested to determine the phase transition temperature of confined materials and used to quantify the melting temperature depression of the ZIF-confined SAs. We also explored the thermal conductivity of SA-in-ZIF composites. Phonon frequency analysis verifies that the presence of SA molecules enhances the heat transfer by adding heat pathways between the nanoporous structure of ZIFs.

Published
2021

3. Analysis and improvement of the hot disk transient plane source method for low thermal conductivity materials

Author

Zheng, Q, Kaur, S, Dames, C, and Prasher, RS

Subjects
physics.app-ph, cond-mat.mtrl-sci, physics.ins-det, Mechanical Engineering & Transports, Mathematical Sciences, Physical Sciences, Engineering
Abstract

The hot disk transient plane source (TPS) method is a widely used standard technique (ISO 22007–2) for characterizing the thermal properties of materials, especially the thermal conductivity, k. Despite its well-established reliability for a wide variety of common materials, the hot disk TPS method is also known to suffer from substantial systematic errors when applied to low-k thermal insulation materials, because of the discrepancies between the idealized model used for data analysis and the actual heat transfer process. Here, we present a combined numerical and experimental study of the influence of the geometry of the hot disk sensor on the measured k value of low-k materials. We demonstrate that the error is strongly affected by the finite thickness and thermal mass of the sensor's insulation layer as well as the corresponding increase of the effective heater size beyond the radius of the embedded metal heater itself. We further numerically investigate the dependence of the error on the sample thermal properties, confirming that the errors are worse in low-k samples. A simple polynomial correction function is provided based on the numerical error analysis, which converts the apparent (erroneous) result from a standard hot disk TPS measurement to a more accurate value of k. To experimentally validate the conclusions from numerical simulations, standard polyimide (Kapton) sensors are systematically optimized (thinned) by etching and used to measure low-k materials, including a standard polystyrene foam, a commercial Airloy® x56 aerogel, and a commercial Hydrophobic Silica Disk aerogel from Aerogel Technologies, LLC. The experimental results clearly demonstrate the strong influence of the sensor thickness. The k results of these samples obtained using either the optimized sensor or the pristine sensor then corrected with the corresponding polynomial correction functions are in good agreement with the values measured independently using a steady-state heat flowmeter (HFM) method: whereas the raw values measured with the pristine sensor are in error by 35% and 40% compared to the HFM reference values for the Airloy® x56 and the hydrophobic aerogel, respectively, the correction function greatly reduces those errors to

Published
2020

4. New approach to waste-heat energy harvesting: pyroelectric energy conversion

Author

Pandya, S, Velarde, G, Zhang, L, Wilbur, JD, Smith, A, Hanrahan, B, Dames, C, and Martin, LW

Subjects
Materials Engineering, Condensed Matter Physics, Physical Chemistry, Physical Chemistry (incl. Structural)
Abstract

Harvesting waste heat for useful purposes is an essential component of improving the efficiency of primary energy utilization. Today, approaches such as pyroelectric energy conversion are receiving renewed interest for their ability to turn wasted energy back into useful energy. From this perspective, the need for these approaches, the basic mechanisms and processes underlying their operation, and the material and device requirements behind pyroelectric energy conversion are reviewed, and the potential for advances in this area is also discussed.

Published
2019

5. Temperature dependence of secondary electron emission: A new route to nanoscale temperature measurement using scanning electron microscopy

Author

Khan, MI, Lubner, SD, Ogletree, DF, and Dames, C

Subjects
Physical Sciences, Condensed Matter Physics, Mathematical Sciences, Engineering, Applied Physics, Mathematical sciences, Physical sciences
Abstract

Scanning electron microscopy (SEM) is ubiquitous for imaging but is not generally regarded as a tool for thermal measurements. Here, the temperature dependence of secondary electron (SE) emission from a sample's surface is investigated. Spatially uniform SEM images and the net charge flowing through a sample were recorded at different temperatures to quantify the temperature dependence of SE emission and electron absorption. The measurements also demonstrated charge conservation during thermal cycling by placing the sample inside a Faraday cup to capture the emitted SEs and back-scattered electrons from the sample. The temperature dependence of SE emission was measured for four semiconducting materials (Si, GaP, InP, and GaAs) with response coefficients found to be of magnitudes ∼100-1000 ppm/K. The detection limits for temperature changes were no more than ±8 °C for 60 s acquisition time.

Published
2018

6. Efficient thermal management of Li-ion batteries with a passive interfacial thermal regulator based on a shape memory alloy

Author

Hao, M, Li, J, Park, S, Moura, S, and Dames, C

Subjects
Electrical and Electronic Engineering, Environmental Engineering
Abstract

The poor performance of lithium-ion batteries in extreme temperatures is hindering their wider adoption in the energy sector. A fundamental challenge in battery thermal management systems (BTMSs) is that hot and cold environments pose opposite requirements: thermal transmission at high temperature for battery cooling, and thermal isolation at low temperature to retain the batteries’ internally generated heat, leading to an inevitable compromise of either hot or cold performances. Here, we demonstrate a thermal regulator that adjusts its thermal conductance as a function of the temperature, just as desired for the BTMS. Without any external logic control, this thermal regulator increases battery capacity by a factor of 3 at an ambient temperature (Tambient) of −20 °C in comparison to a baseline BTMS that is always thermally conducting, while also limiting the battery temperature rise to 5 °C in a very hot environment (Tambient = 45 °C) to ensure safety. The result expands the usability of lithium-ion batteries in extreme environments and opens up new applications of thermally functional devices.

Published
2018

7. Direct Measurement of Pyroelectric and Electrocaloric Effects in Thin Films

Author

Pandya, S, Wilbur, JD, Bhatia, B, Damodaran, AR, Monachon, C, Dasgupta, A, King, WP, Dames, C, and Martin, LW

Subjects
Physical Sciences, Engineering
Abstract

An understanding of polarization-heat interactions in pyroelectric and electrocaloric thin-film materials requires that the electrothermal response is reliably characterized. While most work, particularly in electrocalorics, has relied on indirect measurement protocols, here we report a direct technique for measuring both pyroelectric and electrocaloric effects in epitaxial ferroelectric thin films. We demonstrate an electrothermal test platform where localized high-frequency (approximately 1 kHz) periodic heating and highly sensitive thin-film resistance thermometry allow the direct measurement of pyrocurrents (

Published
2017

8. Citizen Activism Can Preserve LWCF-Funded Park Resources

Author

Kozlowski, Dames C.

Subjects
United States. National Park Service. Land and Water Conservation Fund -- Powers and duties, School buildings -- Remodeling and renovation -- Laws, regulations and rules, Injunctions -- Laws, regulations and rules, Land management -- Laws, regulations and rules, Parks -- Remodeling and renovation -- Laws, regulations and rules -- United States, Government regulation, Travel, recreation and leisure
Abstract

The Land and Water Conservation Fund (LWCF) is intended to create and maintain a nationwide legacy of high-quality recreation areas and facilities and to stimulate non-federal investments in the protection [...]

Published
2020

9. Thermal conductivity and management in laser gain materials: A nano/microstructural perspective.

Author

Wu, X., Tang, L., Hardin, C. L., Dames, C., Kodera, Y., and Garay, J. E.

Subjects
SOLID-state lasers, THERMAL conductivity, ACTIVE medium, LASERS, SINGLE crystals, TRANSPARENT ceramics
Abstract

Heat generation and thermally induced failure has been a major challenge for high-power applications in solid state lasers. Improvements in the solid state laser ceramic fabrication process offer improved mechanical toughness and comparable thermal conductivity compared to single crystal counterparts. Equally enticing is the possibility of using materials with intrinsically superior thermal/mechanical properties that are not viable in the single crystal form. Here, we review the nano/microstructural effects on optical, thermal, and mechanical properties of polycrystalline ceramics, recent developments in a variety of commonly used crystalline laser materials, and potential future directions for more robust laser gain materials for high-power applications. It is argued that the engineering microstructure with both optical and thermal performances in mind might offer breakthrough improvements in laser gain media. [ABSTRACT FROM AUTHOR]

Published
2022
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11. A non-volatile thermal switch for building energy savings

Author

Miao, R, Miao, R, Kishore, R, Kaur, S, Prasher, R, Dames, C, Miao, R, Miao, R, Kishore, R, Kaur, S, Prasher, R, and Dames, C

Abstract

Compared with traditional static insulation, a thermally switchable building envelope could reduce annual heating and cooling loads by intermittently coupling to the outside environment when beneficial. Here, we demonstrate a voltage-actuated, contact/non-contact thermal switch that meets the unique challenges of this application. The switch is non-volatile, consuming electricity only briefly while switching and none to hold steady state. The switch ratio is 12, the off state has a low effective thermal conductivity of 0.045Wm-1K-1, comparable to fiberglass insulation, and the performance is stable over 1,000 switching cycles. Numerical simulations using real-world climate data show that combining this thermal switch with a thermal storage layer in a building envelope can yield annual energy savings of 9%–55% (heating) and 17%–76% (air conditioning), depending on the climate zone. The greatest benefits are realized when the exterior temperature crosses well above and below the desired interior temperature within a single 24 h period.

Published
2022

12. Dynamic tunability of phase-change material transition temperatures using ions for thermal energy storage

Author

Lau, J, Lau, J, Papp, JK, Lilley, D, Khomein, P, Kaur, S, Dames, C, Liu, G, Prasher, R, Lau, J, Lau, J, Papp, JK, Lilley, D, Khomein, P, Kaur, S, Dames, C, Liu, G, and Prasher, R

Abstract

Thermal energy storage (TES) based on phase-change materials (PCMs) has many current and potential applications, such as climate control in buildings, thermal management for batteries and electronics, thermal textiles, and transportation of pharmaceuticals. Despite its promise, the adoption of TES has been limited, in part due to limited tunability of the transition temperature, which hinders TES performance for varying use temperatures. Transition temperature tuning of a material using an external stimulus, such as pressure or an electric field, typically requires very large stimuli. To circumvent this problem, here, we report on the dynamic transition temperature tunability of a PCM using ions. We achieve a transition temperature tunability up to 6°C in polyethylene glycol (PEG) by using the salt lithium oxalatodifluoroborate at a low voltage of 2.5 V, which may enable simpler and safer devices/system designs. We also explain the thermal properties of the salt/PCM solution using the Flory-Huggins theory.

Published
2021

14. Theoretical phonon thermal conductivity of Si/Ge superlattice nanowires

Author

Dames, C. and Chen, G.

Subjects
Germanium -- Thermal properties, Silicon -- Thermal properties, Superlattices as materials -- Thermal properties, Phonons -- Thermal properties, Physics
Abstract

An incoherent particle model is developed to calculate the phonon thermal conductivity of superlattice nanowires. The findings show that compared to a conventional superlattice, calculations show that the additional sidewall scattering in superlattice nanowire can reduce the thermal conductivity by a factor of 2 or more.

Published
2004

18. Pyroelectric energy conversion with large energy and power density in relaxor ferroelectric thin films

Author

Pandya, S, Wilbur, J, Kim, J, Gao, R, Dasgupta, A, Dames, C, and Martin, LW

Subjects
Affordable and Clean Energy, Nanoscience & Nanotechnology
Abstract

© 2018 The Author(s). The need for efficient energy utilization is driving research into ways to harvest ubiquitous waste heat. Here, we explore pyroelectric energy conversion from low-grade thermal sources that exploits strong field- and temperature-induced polarization susceptibilities in the relaxor ferroelectric 0.68Pb(Mg1/3Nb2/3)O3-0.32PbTiO3. Electric-field-driven enhancement of the pyroelectric response (as large as -550 μC m-2K-1) and suppression of the dielectric response (by 72%) yield substantial figures of merit for pyroelectric energy conversion. Field- and temperature-dependent pyroelectric measurements highlight the role of polarization rotation and field-induced polarization in mediating these effects. Solid-state, thin-film devices that convert low-grade heat into electrical energy are demonstrated using pyroelectric Ericsson cycles, and optimized to yield maximum energy density, power density and efficiency of 1.06 J cm-3, 526 W cm-3and 19% of Carnot, respectively; the highest values reported to date and equivalent to the performance of a thermoelectric with an effective ZT ≈ 1.16 for a temperature change of 10 K. Our findings suggest that pyroelectric devices may be competitive with thermoelectric devices for low-grade thermal harvesting.

Published
2018

23. Solid-state thermal rectification with existing bulk materials

Author

Dames, C.

Subjects
Fourier analysis -- Usage, Electric current rectifiers -- Design and construction, Rectifier instruments -- Design and construction, Diodes -- Evaluation, Perturbation (Mathematics) -- Analysis, Engineering and manufacturing industries, Science and technology
Published
2009

24. Report on 6th US-Japan Joint Seminar on Nanoscale Transport PhenomenaScience and Engineering

Author

Borca-Tasciuc, T, Cahill, DG, Chen, G, Cronin, SB, Daiguji, H, Dames, C, Fushinobu, K, Inoue, T, Majumdar, A, Maruyama, S, Miyazaki, K, Matsumoto, M, Norris, PM, Shi, L, Shibahara, M, Shannon, M, Shiomi, J, Taguchi, Y, Takahashi, K, Tsuruta, T, Volz, SG, Wang, E, Xu, XF, Yang, B, and Yang, RG

Subjects
lightmatter interactions, energy conversion, solid-liquid interface, nanotechnology, heat transfer, transport in nanostructures
Published
2008

32. Report on 6th US-Japan Joint Seminar on Nanoscale Transport PhenomenaScience and Engineering

Author

10229578, Borca-Tasciuc, T, Cahill, DG, Chen, G, Cronin, SB, Daiguji, H, Dames, C, Fushinobu, K, Inoue, T, Majumdar, A, Maruyama, S, Miyazaki, K, Matsumoto, M, Norris, PM, Shi, L, Shibahara, M, Shannon, M, Shiomi, J, Taguchi, Y, Takahashi, K, Tsuruta, T, Volz, SG, Wang, E, Xu, XF, Yang, B, Yang, RG, 10229578, Borca-Tasciuc, T, Cahill, DG, Chen, G, Cronin, SB, Daiguji, H, Dames, C, Fushinobu, K, Inoue, T, Majumdar, A, Maruyama, S, Miyazaki, K, Matsumoto, M, Norris, PM, Shi, L, Shibahara, M, Shannon, M, Shiomi, J, Taguchi, Y, Takahashi, K, Tsuruta, T, Volz, SG, Wang, E, Xu, XF, Yang, B, and Yang, RG

Published
2008

35. Report on the Seventh U.S.–Japan Joint Seminar on Nanoscale Transport Phenomena—Science and Engineering

Author

Cola, B. A., primary, Daiguji, H., additional, Dames, C., additional, Fang, N., additional, Fushinobu, K., additional, Inoue, S., additional, Kikugawa, G., additional, Kohno, M., additional, Kumar, S., additional, Li, D. Y., additional, Lukes, J. R., additional, Malen, J. A., additional, McGaughey, A. J. H., additional, Nakabeppu, O., additional, Pipe, K., additional, Reddy, P., additional, Shen, S., additional, Shi, L., additional, Shibahara, M., additional, Taguchi, Y., additional, Takahashi, K., additional, Yamamoto, T., additional, and Zolotoukhina, T., additional

Published
2013
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40. Report on 6th U.S.–Japan Joint Seminar on Nanoscale Transport Phenomena—Science and Engineering

Author

Borca-Tasciuc, T., primary, Cahill, D.G., additional, Chen, G., additional, Cronin, S.B., additional, Daiguji, H., additional, Dames, C., additional, Fushinobu, K., additional, Inoue, T., additional, Majumdar, A., additional, Maruyama, S., additional, Miyazaki, K., additional, Matsumoto, M., additional, Norris, P.M., additional, Shi, L., additional, Shibahara, M., additional, Shannon, M., additional, Shiomi, J., additional, Taguchi, Y., additional, Takahashi, K., additional, Tsuruta, T., additional, Volz, S.G., additional, Wang, E., additional, Xu, X.F., additional, Yang, B., additional, and Yang, R.G., additional

Published
2008
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