Jaeyun Moon, Mechanical Engineering, PhD. Thesis Defense
"Thermal conduction in amorphous materials and the role of collective excitations"
ABSTRACT
The atomic vibrations and thermal properties of amorphous dielectric solids are of
fundamental and practical interest. For applications, amorphous solids are widely
used as thermal insulators in thermopile and other detectors where low thermal
conductivity directly sets the sensitivity of the detector. Amorphous solids are of
fundamental interest themselves because the lack of atomic periodicity complicates
theoretical development. As a result, the lower limits of thermal conductivity in
solids as well as the nature of the vibrational excitations that carry heat remain active
topics of research.
In this thesis, we use numerical and experimental methods to investigate the thermal
conduction in amorphous dielectrics. We begin by using molecular dynamics
to investigate the thermal conductivity of amorphous nanocomposites. We find
that mismatching the vibrational density of states of constituent materials in the
composite is an effective route to achieve exceptionally low thermal conductivity in
fully dense solids.
We then transition to examining the properties of the atomic vibrations transporting
heating in amorphous solids. For decades, normal mode methods have been
used extensively to study thermal transport in amorphous solids. These methods
naturally assume that normal modes are the fundamental vibrational excitations
transporting heat. We examine the predictions from normal mode analysis that are
now able to be tested against experiment, and we find that the predictions from these
methods do not agree with experimental observations. For instance, normal mode
methods predict that the normal modes are scattered by anharmonic interactions as
in single crystalline solids. However, temperature dependent thermal conductivity
measurements demonstrate a typical glassy temperature dependence inconsistent
with normal modes scattering through anharmonic interactions. These discrepancies
suggest that normal modes are not the fundamental heat carriers in amorphous
dielectrics.
To identify the actual heat carriers, we draw on fundamental concepts from manybody
physics and inelastic scattering theory that dictate that the excitation energies of
a many-body interacting system are given by the poles of the single-particle Green's
function. The imaginary part of this function is proportional to the dynamic structure
factor that is directly measured in inelastic scattering experiments. Collective
excitations of a given energy and wavevector can thus be identified from peaks in
the dynamic structure factor; their damping is given by the broadening of the peak.
Using these concepts from many-body physics, the physical picture that emerges is
that heat is carried in large part by a gas of weakly interacting collective excitations
with a cutoff frequency that depends on the atomic structure and composition of the
glass.
We test this picture using numerical and experimental inelastic scattering measurements
on amorphous silicon, a commonly studied amorphous solid. We observe
collective excitations up to 10 THz, well into the thermal spectrum, and far higher
than previous inelastic scattering measurements on other glasses. Our numerical
and experimental evidence also confirms that the collective excitations are damped
by structural disorder rather than anharmonic interactions and that they dominate
the thermal conduction in amorphous silicon. Subsequent analysis shows that these
high frequency acoustic excitations are supported in amorphous silicon due to a
large sound velocity and monatomic composition, suggesting that other monatomic
amorphous solids with large sound velocities may also support these thermal excitations.
Overall, our results provide strong evidence that the heat carriers in amorphous dielectrics
are collective excitations rather than normal modes. This change in physical
picture advances our understanding of atomic dynamics in glasses and also provides a foundation for realizing dielectric solids with ultralow thermal conductivity.