Kyle Horne scite author profile

This paper discusses the initial design and evaluation of a high temperature viscosity measurement system with the focus on the uncertainty assessment. Numerical simulation of the viscometer is used to estimate viscosity uncertainties through the Monte Carlo method. The simulation computes the system response for a particular set of inputs (viscosity, moment of inertia, spring constant and hysteretic damping), and the viscosity is calculated using two methods: the Roscoe approximate solution and a numerical-fit method. For numerical fitting, a residual function of the logarithmic decay of oscillation amplitude and oscillation period is developed to replace the residual function of angular oscillation, which is mathematically stiff. The results of this study indicate that the method using computational solution of the equations and fitting for the parameters should be used, since it almost always out-performs the Roscoe approximation in uncertainty. The hysteretic damping and spring stiffness uncertainties translate into viscosity uncertainties almost directly, whereas the moment of inertial and vessel-height uncertainties are magnified approximately two-fold. As the hysteretic damping increases, so does the magnification of its uncertainty, therefore it should be minimized in the system design. The result of this study provides a general guide for the design and application of all oscillation-vessel viscosity measurement systems.

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Thermal conductivity measurement of few layer graphene film by a micropipette sensor with laser point heating source

Jeong

Lee

Shrestha

et al. 2016

Mater. Res. Express

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Monte carlo uncertainty analysis for photothermal radiometry measurements using a curve fit process

Horne¹,

Fleming²,

Timmins³

et al. 2015

Metrologia

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Abstract. Photothermal Radiometry (PTR) has become a popular method to measure thermal properties of layered materials. Much research has been done to determine the capabilities of PTR, but with little uncertainty analysis. This study performs a Monte Carlo uncertainty analysis to quantify uncertainty of film diffusivity and effusivity measurements, presents a sensitivity study for each input parameter, compares linear and logarithmic spacing of data points on frequency scans, and investigates the validity of a 1-D heat transfer assumption.

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CGNS I/O Performance on Parallel File Systems

Hauser¹,

Horne²

2010

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Kyle Horne

Photothermal radiometry measurement of thermophysical property change of an ion-irradiated sample

Monte Carlo uncertainty estimation for an oscillating-vessel viscosity measurement

Thermal conductivity measurement of few layer graphene film by a micropipette sensor with laser point heating source

Monte carlo uncertainty analysis for photothermal radiometry measurements using a curve fit process

CGNS I/O Performance on Parallel File Systems

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