Your search keyword '"Foley, Brian M."' showing total 3 results

1. Spectral phonon scattering effects on the thermal conductivity of nano-grained barium titanate.

Author

Donovan, Brian F., Foley, Brian M., Ihlefeld, Jon F., Maria, Jon-Paul, and Hopkins, Patrick E.

Subjects

*PHONON scattering, *BARIUM titanate, *ELECTRIC properties of metals, *THERMAL conductivity, *FERROELECTRIC materials, *THERMAL properties

Abstract

We study the effect of grain size on thermal conductivity of thin film barium titanate over temperatures ranging from 200 to 500 K. We show that the thermal conductivity of Barium Titanate (BaTiO3) decreases with decreasing grain size as a result of increased phonon scattering from grain boundaries. We analyze our results with a model for thermal conductivity that incorporates a spectrum of mean free paths in BaTiO3. In contrast to the common gray mean free path assumption, our findings suggest that the thermal conductivity of complex oxide perovskites is driven by a spectrum of phonons with varying mean free paths. [ABSTRACT FROM AUTHOR]

Published

2014

2. Crossover from incoherent to coherent phonon scattering in epitaxial oxide superlattices.

Author

Ravichandran, Jayakanth, Yadav, Ajay K., Cheaito, Ramez, Rossen, Pim B., Soukiassian, Arsen, Suresha, S. J., Duda, John C., Foley, Brian M., Lee, Che-Hui, Zhu, Ye, Lichtenberger, Arthur W., Moore, Joel E., Muller, David A., Schlom, Darrell G., Hopkins, Patrick E., Majumdar, Arun, Ramesh, Ramamoorthy, and Zurbuchen, Mark A.

Subjects

COHERENCE (Optics), SUPERLATTICES, EPITAXY, THERMAL conductivity, PHONON scattering, THERMOELECTRICITY

Abstract

Elementary particles such as electrons or photons are frequent subjects of wave-nature-driven investigations, unlike collective excitations such as phonons. The demonstration of wave-particle crossover, in terms of macroscopic properties, is crucial to the understanding and application of the wave behaviour of matter. We present an unambiguous demonstration of the theoretically predicted crossover from diffuse (particle-like) to specular (wave-like) phonon scattering in epitaxial oxide superlattices, manifested by a minimum in lattice thermal conductivity as a function of interface density. We do so by synthesizing superlattices of electrically insulating perovskite oxides and systematically varying the interface density, with unit-cell precision, using two different epitaxial-growth techniques. These observations open up opportunities for studies on the wave nature of phonons, particularly phonon interference effects, using oxide superlattices as model systems, with extensive applications in thermoelectrics and thermal management. [ABSTRACT FROM AUTHOR]

Published

2014

3. Thermal boundary conductance accumulation and interfacial phonon transmission: Measurements and theory.

Author

Cheaito, Ramez, Gaskins, John T., Caplan, Matthew E., Donovan, Brian F., Foley, Brian M., Giri, Ashutosh, Duda, John C., Szwejkowski, Chester J., Constantin, Costel, Brown-Shaklee, Harlan J., Ihlefeld, Jon F., and Hopkins, Patrick E.

Subjects

*THERMAL boundary layer, *PHONON scattering, *ELECTRIC conductivity, *DEBYE temperatures, *LOW temperatures, *METALLIC films

Abstract

The advances in phonon spectroscopy in homogeneous solids have unveiled extremely useful physics regarding the contribution of phonon energies and mean-free paths to the thermal transport in solids. However, as material systems decrease to length scales less than the phonon mean-free paths, thermal transport can become much more impacted by scattering and transmission across interfaces between two materials than the intrinsic relaxation in the homogeneous solid. To elucidate the fundamental interactions driving this thermally limiting interfacial phonon scattering process, we analytically derive and experimentally measure a thermal boundary conductance accumulation function. We develop a semiclassical theory to calculate the thermal boundary conductance accumulation function across interfaces using the diffuse mismatch model, and validate this derivation by measuring the interface conductance between eight different metals on native oxide/silicon substrates and four different metals on sapphire substrates. Measurements were performed at room temperature using time-domain thermoreflectance and represent the first-reported values for interface conductance across several metal/native oxide/silicon and metal/sapphire interfaces. The various metal films provide a variable bandwidth of phonons incident on the metal/substrate interface. This method of varying phonons' cutoff frequency in the film while keeping the same substrate allows us to mimic the accumulation of thermal boundary conductance and thus provides a direct method to experimentally validate our theory. We show that the accumulation function can be written as the product of a weighted average of the interfacial phonon transmission function and the accumulation of the temperature derivative of the phonon flux incident on the interface; this provides the framework to extract an average, spectrally dependent phonon transmissivity from a series of thermal boundary conductance measurements. Our approach provides a platform for analyzing the spectral phononic contribution to interfacial thermal transport in our experimentally measured data of metal/substrate thermal boundary conductance. Based on the assumptions made in this work and the measurement results on different metals on native oxide/silicon and sapphire substrates, we demonstrate that high-frequency phonons dictate the transport across metal/Si interfaces, especially in low Debye temperature metals with low-cutoff frequencies. [ABSTRACT FROM AUTHOR]

Published

2015