The Effect of Polydispersivity on the Thermal Conductivity of Particulate Thermal Interface Materials

Kanuparthi, S.; Subbarayan, Ganesh; Siegmund, Thomas; Sammakia, Bahgat

doi:10.1109/tcapt.2008.2010502

Cited by 10 publications

(3 citation statements)

References 27 publications

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“…The thermal conductivity of composites containing inclusions of same properties and various dimensions (filler size polydispersity) exhibits an opposite trend. 75 As the volume fraction of inclusions, the mean inclusion size, the thermal conductivity of inclusions, and of the matrix are kept constant, but the inclusion size is sampled from a distribution function of increasing variance, the thermal conductivity of the composite increases.…”

Section: Structural and Composition Fluctuations: Engineeredmentioning

confidence: 99%

Stochasticity in materials structure, properties, and processing—A review

Hull

Keblinski

Lewis

et al. 2018

Applied Physics Reviews

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We review the concept of stochasticity—i.e., unpredictable or uncontrolled fluctuations in structure, chemistry, or kinetic processes—in materials. We first define six broad classes of stochasticity: equilibrium (thermodynamic) fluctuations; structural/compositional fluctuations; kinetic fluctuations; frustration and degeneracy; imprecision in measurements; and stochasticity in modeling and simulation. In this review, we focus on the first four classes that are inherent to materials phenomena. We next develop a mathematical framework for describing materials stochasticity and then show how it can be broadly applied to these four materials-related stochastic classes. In subsequent sections, we describe structural and compositional fluctuations at small length scales that modify material properties and behavior at larger length scales; systems with engineered fluctuations, concentrating primarily on composite materials; systems in which stochasticity is developed through nucleation and kinetic phenomena; and configurations in which constraints in a given system prevent it from attaining its ground state and cause it to attain several, equally likely (degenerate) states. We next describe how stochasticity in these processes results in variations in physical properties and how these variations are then accentuated by—or amplify—stochasticity in processing and manufacturing procedures. In summary, the origins of materials stochasticity, the degree to which it can be predicted and/or controlled, and the possibility of using stochastic descriptions of materials structure, properties, and processing as a new degree of freedom in materials design are described.

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Section: Structural and Composition Fluctuations: Engineeredmentioning

confidence: 99%

Stochasticity in materials structure, properties, and processing—A review

Hull

Keblinski

Lewis

et al. 2018

Applied Physics Reviews

View full text Add to dashboard Cite

show abstract

“…The discretization in finite element approaches may be thought of as resulting in a conductance network between the nodes. Conductance networks have been constructed to study near-percolation thermal transport behavior of TIMs [18,6]. Flow resistances are commonly used when modeling flow through pipes in fluid systems, as well.…”

Section: A Resistance Network Model For Analyzing Complex Channel Geomentioning

confidence: 99%

“…Alumina and other ceramic materials, in addition to metallic particles such as silver, are common choices for the particles, while silicone and other similar materials are common choices for the grease matrix. The particles are typically present in the fluid at loading volume fractions of 30-60% [6], enabling a considerable improvement of the bulk thermal conductivity of the TIM-often an order of magnitude improvement or more.…”

Section: Introductionmentioning

confidence: 99%

Topological design of channels for squeeze flow optimization of thermal interface materials

Bajaj

Subbarayan

Garimella

2012

International Journal of Heat and Mass Transfer

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Performance of thermal interface materials (TIMs) used between a microelectronic device and its associated heat spreader is largely dependent on the bulk thermal conductivity of the TIM, but the bond-line thickness (BLT) of the applied material as well as the interfacial contact resistances are also significant contributors to overall performance. Hierarchically Nested Channels (HNCs), created by modifying the surface topology of the chip or the heatsink with hierarchical arrangements of microchannels in order to improve flow, have been proposed to reduce both the required squeezing force and the final BLT at the interfaces. In the present work, a topological optimization framework that enables the design of channel arrangements is developed. The framework is based on a resistance network approximation to Newtonian squeeze flow. The approximation, validated against finite element (FE) solutions, allows efficient, design-oriented solutions for squeeze flow in complex geometries. A comprehensive design sensitivity analysis exploiting the resistance network approximation is also developed and implemented. The resistance approximation and the sensitivity analysis is used to build an automated optimal channel design framework. A Pareto optimal problem formulation for the design of channels is posed and the optimal solution is demonstrated using the framework.

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Statistical Description of Composite Materials

Buryachenko¹

2012

Local and Nonlocal Micromechanics of Heterogeneous Materials

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The Effect of Polydispersivity on the Thermal Conductivity of Particulate Thermal Interface Materials

Cited by 10 publications

References 27 publications

Stochasticity in materials structure, properties, and processing—A review

Stochasticity in materials structure, properties, and processing—A review

Topological design of channels for squeeze flow optimization of thermal interface materials

Statistical Description of Composite Materials

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