TY - JOUR
T1 - Excitation and detection of acoustic phonons in nanoscale systems
AU - Ng, Ryan C.
AU - Sachat, Alexandros el
AU - Céspedes Mulero, Francisco
AU - Poblet, Martin
AU - Madiot, Guilhem
AU - Jaramillo Fernández, Juliana
AU - Florez, Omar
AU - Xiao, Peng
AU - Sledzinska, Marianna
AU - Sotomayor Torres, Clivia M
AU - Chávez Ángel, Emigdio
PY - 2022
Y1 - 2022
N2 - Phonons play a key role in the physical properties of materials, and have long been a topic of study in physics. While the effects of phonons had historically been considered to be a hindrance, modern research has shown that phonons can be exploited due to their ability to couple to other excitations and consequently affect the thermal, dielectric, and electronic properties of solid state systems, greatly motivating the engineering of phononic structures. Advances in nanofabrication have allowed for structuring and phonon confinement even down to the nanoscale, drastically changing material properties. Despite developments in fabricating such nanoscale devices, the proper manipulation and characterization of phonons continues to be challenging. However, a fundamental understanding of these processes could enable the realization of key applications in diverse fields such as topological phononics, information technologies, sensing, and quantum electrodynamics, especially when integrated with existing electronic and photonic devices. Here, we highlight seven of the available methods for the excitation and detection of acoustic phonons and vibrations in solid materials, as well as advantages, disadvantages, and additional considerations related to their application. We then provide perspectives towards open challenges in nanophononics and how the additional understanding granted by these techniques could serve to enable the next generation of phononic technological applications.
AB - Phonons play a key role in the physical properties of materials, and have long been a topic of study in physics. While the effects of phonons had historically been considered to be a hindrance, modern research has shown that phonons can be exploited due to their ability to couple to other excitations and consequently affect the thermal, dielectric, and electronic properties of solid state systems, greatly motivating the engineering of phononic structures. Advances in nanofabrication have allowed for structuring and phonon confinement even down to the nanoscale, drastically changing material properties. Despite developments in fabricating such nanoscale devices, the proper manipulation and characterization of phonons continues to be challenging. However, a fundamental understanding of these processes could enable the realization of key applications in diverse fields such as topological phononics, information technologies, sensing, and quantum electrodynamics, especially when integrated with existing electronic and photonic devices. Here, we highlight seven of the available methods for the excitation and detection of acoustic phonons and vibrations in solid materials, as well as advantages, disadvantages, and additional considerations related to their application. We then provide perspectives towards open challenges in nanophononics and how the additional understanding granted by these techniques could serve to enable the next generation of phononic technological applications.
KW - Acoustic phonons
KW - Acoustic-phonons
KW - Diverse fields
KW - Nano scale
KW - Nano-scale system
KW - Nanoscale device
KW - Phonon confinement
KW - Physical properties of materials
KW - Quantum electrodynamics
KW - Solid-state system
U2 - 10.1039/d2nr04100f
DO - 10.1039/d2nr04100f
M3 - Article
C2 - 36082529
SN - 2040-3364
VL - 14
SP - 13428
EP - 13451
JO - Nanoscale
JF - Nanoscale
IS - 37
ER -