Determination of the thermal properties of a material is an important task in
many scientific and engineering applications. How a material behaves when
subjected to high or fluctuating temperatures can be critical to the safety and
longevity of a system's essential components. The laser flash experiment is a
well-established technique for indirectly measuring the thermal diffusivity,
and hence the thermal conductivity, of a material. In previous works,
optimization schemes have been used to find estimates of the thermal
conductivity and other quantities of interest which best fit a given model to
experimental data. Adopting a Bayesian approach allows for prior beliefs about
uncertain model inputs to be conditioned on experimental data to determine a
posterior distribution, but probing this distribution using sampling techniques
such as Markov chain Monte Carlo methods can be incredibly computationally
intensive. This difficulty is especially true for forward models consisting of
time-dependent partial differential equations. We pose the problem of
determining the thermal conductivity of a material via the laser flash
experiment as a Bayesian inverse problem in which the laser intensity is also
treated as uncertain. We introduce a parametric surrogate model that takes the
form of a stochastic Galerkin finite element approximation, also known as a
generalized polynomial chaos expansion, and show how it can be used to sample
efficiently from the approximate posterior distribution. This approach gives
access not only to the sought-after estimate of the thermal conductivity but
also important information about its relationship to the laser intensity, and
information for uncertainty quantification. We also investigate the effects of
the spatial profile of the laser on the estimated posterior distribution for
the thermal conductivity
