Development of a reduced model of formation reactions in Zr-Al nanolaminates

Vohra, Manav; Winokur, Justin; Overdeep, Kyle R.; Marcello, Paul; Weihs, Timothy P.; Knio, Omar M.

doi:10.1063/1.4903816

Cited by 13 publications

(14 citation statements)

References 52 publications

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“…The predictions reveal that the peak of the distribution shifts towards lower velocities as λ increases. This is consistent with previous experimental, analytical and computational results [1,20,29,69], which indicate that the front velocity decreases with bilayer thickness, as long as the latter is sufficiently larger than the thickness of the premixed layer. The spread in the distributions, as quantified by the standard deviation, σ, is also observed to decrease with λ.…”

Section: Self-propagating Reactionssupporting

confidence: 92%

“…The four-dimensional polynomial basis of the resulting surrogate was found to be of the order: 3, 2, 2 and 2 along ξ 1 , ξ 2 , ξ 3 and ξ 4 respectively. The reaction time t r has been observed to increases monotonically toward T r when T r falls in the range of temperatures extending from ignition threshold to the melting point of Al, and t r also exhibits a smooth dependence on diffusivity parameters [1]. We thus expect the PC expansion of t r to converge rapidly, and a low-order expansion would be sufficient.…”

Section: Homogeneous Ignitionmentioning

confidence: 94%

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mentioning

confidence: 99%

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Design analysis for optimal calibration of diffusivity in reactive multilayers

Vohra

Huan

Weihs

et al. 2017

Combustion Theory and Modelling

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Calibration of the uncertain Arrhenius diffusion parameters for quantifying mixing rates in Zr-Al nanolaminate foils was performed in a Bayesian setting [1]. The parameters were inferred in a low temperature regime characterized by homogeneous ignition and a high temperature regime characterized by self-propagating reactions in the multilayers. In this work, we extend the analysis to find optimal experimental designs that would provide the best data for inference. We employ a rigorous framework that quantifies the expected information gain in an experiment, and find the optimal design conditions using numerical techniques of Monte Carlo, sparse quadrature, and polynomial chaos surrogates. For the low temperature regime, we find the optimal foil heating rate and pulse duration, and confirm through simulation that the optimal design indeed leads to sharper posterior distributions of the diffusion parameters. For the high temperature regime, we demonstrate potential for increase in the expected information gain of the posteriors by increasing sample size and reducing uncertainty in measurements. Moreover, posterior marginals are also produced to verify favorable experimental scenarios for this regime. † Corresponding Author

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Section: Self-propagating Reactionssupporting

confidence: 92%

Section: Homogeneous Ignitionmentioning

confidence: 94%

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Design analysis for optimal calibration of diffusivity in reactive multilayers

Vohra

Huan

Weihs

et al. 2017

Combustion Theory and Modelling

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“…Availability of a surrogate model typically enables efficient computation of Sobol' indices [11][12][13][14][15]. This has enabled performing global sensitivity analysis on a wide range of applications including in ocean modeling [16,17], geosciences [18][19][20], and chemical kinetics [21][22][23] to name a few.…”

Section: Introductionmentioning

confidence: 99%

Sensitivity-Driven Adaptive Construction of Reduced-space Surrogates

et al. 2018

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We develop a systematic approach for surrogate model construction in reduced input parameter spaces. A sparse set of model evaluations in the original input space is used to approximate derivative based global sensitivity measures (DGSMs) for individual uncertain inputs of the model. An iterative screening procedure is developed that exploits DGSM estimates in order to identify the unimportant inputs. The screening procedure forms an integral part of an overall framework for adaptive construction of a surrogate in the reduced space. The framework is tested for computational efficiency through an initial implementation in simple test cases such as the classic Borehole function, and a semilinear elliptic PDE with a random source term. The framework is then deployed for a realistic application from chemical kinetics, where we study the ignition delay in an H 2 /O 2 reaction mechanism with 19 uncertain rate constants. It is observed that significant computational gains can be attained by constructing accurate low-dimensional surrogates using the proposed framework.

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“…Essentially, it is a truncated expansion with polynomial basis functions that converges in a least-squares sense. For an accurate PC representation, the output should vary smoothly with respect to the uncertain inputs [24] and must be L-2 integrable:…”

Section: Polynomial Chaos Response Surfacementioning

confidence: 99%

Uncertainty quantification in non-equilibrium molecular dynamics simulations of thermal transport

Vohra

Nobakht

Shin

et al. 2018

International Journal of Heat and Mass Transfer

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Bulk thermal conductivity estimates based on predictions from non-equilibrium molecular dynamics (NEMD) using the so-called direct method are known to be severely underpredicted since finite simulation length-scales are unable to mimic bulk transport. Moreover, subjecting the system to a temperature gradient by means of thermostatting tends to impact phonon transport adversely. Additionally, NEMD predictions are tightly coupled with the choice of the inter-atomic potential and the underlying values associated with its parameters. In the case of silicon (Si), nominal estimates of the Stillinger-Weber (SW) potential parameters are largely based on a constrained regression approach aimed at agreement with experimental data while ensuring structural stability. However, this approach has its shortcomings and it may not be ideal to use the same set of parameters to study a wide variety of Si-based systems subjected to different thermodynamic conditions. In this study, NEMD simulations are performed on a Si bar to investigate the impact of bar-length, and the applied thermal gradient on the discrepancy between predictions and the available measurement for bulk thermal conductivity at 300 K by constructing statistical response surfaces at different temperatures. The approach helps quantify the discrepancy, observed to be largely dependent on the system-size, with minimal computational effort. A computationally efficient approach based on derivative-based sensitivity measures to construct a reduced-order polynomial chaos surrogate for NEMD predictions is also presented. The surrogate is used to arXiv:1805.00118v2 [physics.comp-ph]

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Development of a reduced model of formation reactions in Zr-Al nanolaminates

Cited by 13 publications

References 52 publications

Design analysis for optimal calibration of diffusivity in reactive multilayers

Design analysis for optimal calibration of diffusivity in reactive multilayers

Sensitivity-Driven Adaptive Construction of Reduced-space Surrogates

Uncertainty quantification in non-equilibrium molecular dynamics simulations of thermal transport

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