Intrinsic thermal interfacial resistance measurement in bonded metal–polymer foils

Rajagopal, Manjunath C.; Man, Timothy; Agrawal, Adreet; Kuntumalla, Gowtham; Sinha, Sanjiv

doi:10.1063/5.0012404

Cited by 7 publications

(7 citation statements)

References 61 publications

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“…Besides its invulnerability to radiation heat loss and its fast response, the 3ω method is also very reliable when working at microscopic scales. Rajagopal et al 154 proposed an improved method based on bonded metal-polymer interfaces. Using a more comprehensive test section to reduce fabrication complexities, a higher amperage can be applied to reduce systematic errors.…”

Section: Transient Techniquesmentioning

confidence: 99%

Advances in thermal contact resistance studies

Murwamadala

Veeredhi

2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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The demand for accurate Thermal Contact Resistance analysis and prediction continues to increase with the advancement of technology. In applications such as manufacturing, it is beneficial to understand the Thermal Contact resistance between the workpiece and tool, or between the tool and debris or shavings to accurately predict the tool wear rate. It is essential to understand and analyze this parameter in aerospace, nuclear power generation, supercar braking systems, and similar applications where close tolerances are used. The continued technological advancements indicate further opportunities for research in Thermal Contact Resistance. This article surveys and summarizes industrial applications’ as well as experimental and theoretical studies. In addition recent advances in both experimental methods and predictive studies are also comprehensively summarized and highlight the trends and future needs of studies in Thermal Contact Resistance, these included recent advances in transient and steady state experimental methods. There is a clear need for optimization, versatility, and economical improvement of these methods. Moreover, the rise in advanced metrological technologies, instrumentation, and thermal measurement systems.

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Section: Transient Techniquesmentioning

confidence: 99%

Advances in thermal contact resistance studies

Murwamadala

Veeredhi

2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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“…On the other hand, continuum models such as finite element methods (FEM) approximate the temperature discontinuity across dissimilar interfaces using the interfacial resistance as an input parameter [48], [54]. Typically, the thermal interfacial resistances are either measured experimentally [33], [54] or calculated from MD simulations [48], [53]. MD based simulations are usually limited to confined domains of few nm 2 -μm 2 and are also limited by the computational capacity to be able to model an entire cell.…”

Section: Cellular Heat Diffusion Modelmentioning

confidence: 99%

“…(4)) using Figure 2. We use finite element simulations that were validated for interfacial resistance modeling in our previous work [40], [54], [61] and for modeling transients in the supplementary material. A nominal volumetric heat of 2.5 nW is assumed to be released per cell, which corresponds to a typical cell metabolism rate [41], [62].…”

Section: Revisiting the Effective Thermal Conductivity Approximationmentioning

confidence: 99%

Cellular Thermometry Considerations for Probing Biochemical Pathways

Rajagopal

Sinha

2021

Cell Biochem Biophys

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Temperature is a fundamental thermodynamic property that can serve as a probe of biochemical reactions. Extracellular thermometry has previously been used to probe cancer metabolism and thermoregulation, with measured temperature changes of ~1-2 K in tissues, consistent with theoretical predictions. In contrast, previous intracellular thermometry studies remain disputed due to reports of >1 K intracellular temperature rises over 5 min or more that are inconsistent with theory. Thus, the origins of such anomalous temperature rises remain unclear. An improved quantitative understanding of intracellular thermometry is necessary to provide a clearer perspective for future measurements. Here, we develop a generalizable framework for modeling cellular heat diffusion over a range of subcellular-to-tissue length scales. Our model shows that local intracellular temperature changes reach measurable limits (> 0.1 K) only when exogenously stimulated. On the other hand, extracellular temperatures can be measurable (> 0.1 K) in tissues even from endogenous biochemical pathways. Using these insights, we provide a comprehensive approach to choosing an appropriate cellular thermometry technique by analyzing thermogenic reactions of different heat rates and time constants across length scales ranging from sub-cellular to tissues. Our work provides clarity on cellular heat diffusion modeling and on the required thermometry approach for probing thermogenic biochemical pathways.

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“…More recently, the RNM was extended to evaluate the effective elastic modulus of particulate systems. 45 While interfacial resistance can have a significant influence on the effective conductance in particle systems, [46][47][48][49][50] experimentally validated RNM simulations by Kanuparthi et al 1 demonstrated that spatial arrangement of particles play a very significant role in transport of heat in high contrast composites. The overall effective thermal conductivity can be accurately described if an appropriate statistical distribution of filler-matrix gap is captured.…”

Section: Introductionmentioning

confidence: 99%

A procedure for efficient generation and behavioral evaluation of ultra‐packed ellipsoidal particle systems

Liao

Achar

Subbarayan

2022

Numerical Meth Engineering

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Many engineering applications demand ultra-packing of particles into a matrix.In general, efficiently simulating the random close packing of non-spherical particles, and with 60% or greater volume loading remains a challenge. In this article, we describe an efficient procedure that achieves ultra-packing of ellipsoidal particle systems of the order of 10 4 -10 6 particles on a desktop computer. A significant challenge to ellipsoidal particle packing problem is particle-particle contact detection. We describe an algebraic intersection detection method for ellipsoidal particles and couple it with a heuristic constructive algorithm to generate densely packed microstructures with ellipsoidal fillers. The effective behavior of the generated microstructures is then numerically estimated using an efficient random-network model that is valid for high-contrast particulate composites in near percolation arrangement. Finally, the algorithms are applied to evaluate the effective thermal conductivity of ellipsoidal particle filled composites used as thermal interface materials. Simulations of lognormally distributed particle systems with varying aspect ratios of ellipsoidal fillers are systematically carried out to draw conclusions on impact of particle shapes.

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Intrinsic thermal interfacial resistance measurement in bonded metal–polymer foils

Cited by 7 publications

References 61 publications

Advances in thermal contact resistance studies

Advances in thermal contact resistance studies

Cellular Thermometry Considerations for Probing Biochemical Pathways

A procedure for efficient generation and behavioral evaluation of ultra‐packed ellipsoidal particle systems

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