Random network percolation models for particulate thermal interface materials

Kanuparthi, S.; Zhang, X.; Subbarayan, Ganesh; Sammakia, Bahgat; Siegmund, Thomas; Gowda, Arun; Tonapi, Sandeep

doi:10.1109/itherm.2006.1645480

Cited by 10 publications

(18 citation statements)

References 9 publications

(9 reference statements)

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“…In a subsequent study [11], we found that the earlier model [2] using a cylindrical region to approximate the thermal transport within the filler particles as being less accurate when the polydispersivity of the particulate system increases. We developed a novel semi-spherical approximation to the conductance of fillers as an alternative to the cylindrical region approximation used in reference [2].…”

Section: Random Network Model Finite Elementmentioning

confidence: 90%

“…But the classical models are often inaccurate at larger volume fractions (up to 80%) and when SDUWLFOHV DUH LQ ³QHDU SHUFRODWLRQ´ DUUDQJHPHQWV ,Q WKHLU VWXG\ D random network model (RNM [2]) was developed and applied to evaluate the effective thermal conductivity of particulate thermal interface materials. The heat transport between the filler particles ZDV DFFXUDWHO\ FDSWXUHG E\ LPSOHPHQWLQJ %DWFKHORU ¶V [6] estimate of the conductance between two spherical particles in near contact.…”

Section: Random Network Model Finite Elementmentioning

confidence: 99%

“…RNM [2] has the advantage of being able to handle random particle size variations compared to the percolation models as they are classically used [7][8][9]. In the RNM [2], the heat conductance between the spherical filler particles was approximated by cylindrical zones. The network model was used to evaluate the bulk conductivities of random microstructures.…”

Section: Random Network Model Finite Elementmentioning

confidence: 99%

“…We developed a novel semi-spherical approximation to the conductance of fillers as an alternative to the cylindrical region approximation used in reference [2]. The revised model showed a better agreement with experimental data than the model of reference [2].…”

Section: Random Network Model Finite Elementmentioning

confidence: 99%

See 3 more Smart Citations

On refining the parameters of a Random Network Model for determining the effective thermal conductivity of particulate thermal interface materials

Dan

Sammakia

Subbarayan

2010

2010 12th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems

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Predictive modeling using fundamental physical principles is critical to developing new Thermal Interface Materials (TIMs) since it can be used to quantify the effect of particle volume fraction and arrangements on the effective thermal conductivity.In our prior work, we described a Random Network Model (RNM) [2] that can efficiently capture the near-percolation transport in these particle-filled systems, taking into account the inter-particle interactions and random size distributions. The accuracy of the RNM is dependent on the parameters inherent in analytical description of thermal transport between two spherical particles, and their numerical approximation into a network model. In the present study, based on a finite element analysis, the network model is improved by developing an approximation of the critical cylindrical region between two spherical particles over which energy is transported. Taking the finite element (FE) results (generated by COMSOL TM ) as a reference, this critical parameter demonstrated a much larger effect on the thermal conductance of a single cell than other parameters (thermal conductivity ratio of fillers and matrix, ratio of radii of two neighboring particles and distance between two neighboring particles). Thirty different microstructures were generated using COMSOL TM at volume fractions of 40%, 50%, 58% and 70% respectively. Comparing RNM results with FE results and experimental data, a linear relationship of the critical parameter and the volume fraction was found that provides a more accurate prediction of the effective thermal conductivity of the particulate thermal interface material for a given volume fraction.

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Section: Random Network Model Finite Elementmentioning

confidence: 90%

Section: Random Network Model Finite Elementmentioning

confidence: 99%

Section: Random Network Model Finite Elementmentioning

confidence: 99%

Section: Random Network Model Finite Elementmentioning

confidence: 99%

See 2 more Smart Citations

On refining the parameters of a Random Network Model for determining the effective thermal conductivity of particulate thermal interface materials

Dan

Sammakia

Subbarayan

2010

2010 12th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems

Self Cite

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show abstract

“…The goal of the present paper is to study the effect of polydispersivity on the effective thermal transport in polymeric composites using a computationally efficient random network model developed earlier by the authors [20,21]. The network model was demonstrated in our prior work to capture accurately (for composites with a very high contrast in the constituent thermal conductivities) the effect of random spatial distribution of the particles as well the constituent thermal conductivities on the effective thermal conductivity of the composite.…”

Section: Introductionmentioning

confidence: 99%

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

Kanuparthi

Subbarayan

Siegmund

et al. 2009

IEEE Trans. Comp. Packag. Technol.

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A critical need in developing thermal interface materials (TIMs) is an understanding of the effect of particle/matrix conductivities, volume loading of the particles, the size distribution, and the random arrangement of the particles in the matrix on the homogenized thermal conductivity. Commonly, TIM systems contain random spatial distributions of particles of a polydisperse (usually bimodal) nature. A detailed analysis of the microstructural characteristics that influence the effective thermal conductivity of TIMs is the goal of this paper. Random microstructural arrangements consisting of lognormal size-distributions of alumina particles in silicone matrix were generated using a drop-fall-shake algorithm. The generated microstructures were statistically characterized using the matrix-exclusion probability function. The filler particle volume loading was varied over a range of 40-55 %. For a given filler volume loading, the effect of polydispersivity in the microstructures was captured by varying the standard deviation(s) of the filler particle size distribution function. For each particle arrangement, the effective thermal conductivity of the microstructures was evaluated through numerical simulations using a network model previously developed by the authors. Counter to expectation, increased polydispersivity was observed to increase the effective conductivity up to a volume loading of 50%. However, at a volume loading of 55%, beyond a limiting standard deviation of 0.9, the effective thermal conductivity decreased with increased standard deviation suggesting that the observed effects are a trade-off between resistance to transport through the particles versus transport through the inter-particle matrix gap in a percolation chain.

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Optimization of Effective Thermal Conductivity of Thermal Interface Materials Based on the Genetic Algorithm-Driven Random Thermal Network Model

Liang

et al. 2021

ACS Appl. Mater. Interfaces

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Polymer-based thermal interface materials (TIMs) are indispensable for reducing the thermal contact resistance of high-power electronic devices. Owing to the low thermal conductivity of polymers, adding multiscale dispersed particles with high thermal conductivity is a common approach to enhance the effective thermal conductivity. However, optimizing multiscale particle matching, including particle size distribution and volume fraction, for improving the effective thermal conductivity has not been achieved. In this study, three kinds of filler-loaded samples were prepared, and the effective thermal conductivity and average particle size of the samples were tested. The finite element model (FEM) and the random thermal network model (RTNM) were applied to predict the effective thermal conductivity of TIMs. Compared with the FEM, the RTNM achieves higher accuracy with an error less than 5% and higher computational efficiency in predicting the effective thermal conductivity of TIMs. Combining the abovementioned advantages, we designed a set of procedures for an RTNM driven by the genetic algorithm (GA). The procedure can find multiscale particle-matching ways to achieve the maximum effective thermal conductivity under a given filler load. The results show that the samples with 40 vol %, 50 vol %, and 60 vol % filler loading have similar particle size distribution and volume fractions when the effective thermal conductivity reaches the highest. It should be emphasized that the optimized effective thermal conductivity can be improved obviously with the increase in the volume fraction of the filler loading. The high efficiency and accuracy of the procedure show great potential for the future design of high-efficiency TIMs.

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Random network percolation models for particulate thermal interface materials

Cited by 10 publications

References 9 publications

On refining the parameters of a Random Network Model for determining the effective thermal conductivity of particulate thermal interface materials

On refining the parameters of a Random Network Model for determining the effective thermal conductivity of particulate thermal interface materials

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

Optimization of Effective Thermal Conductivity of Thermal Interface Materials Based on the Genetic Algorithm-Driven Random Thermal Network Model

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