Title :
Phonon thermal conduction in periodically porous silicon nanobeams
Author :
Woosung Park ; Marconnet, Amy M. ; Kodama, Tomoya ; Joonsuk Park ; Sinclair, Robert ; Asheghi, Mehdi ; Goodson, Kenneth E.
Author_Institution :
Dept. of Mech. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
The thermal conductivity of single crystal silicon can be reduced by the introduction of boundaries at the nanoscale. We present the measured thermal conductivity of single crystal silicon nanobeams patterned with a single row of holes at room temperature: the hole diameter and the spacing vary from 100nm to 250nm and from 200 nm to 800nm, respectively. A steady-state four-probe joule heating measurement technique is used to extract the thermal conductivity of the porous silicon nanobeams across a range of pore geometries. The reduction in thermal conductivity owing to the hole boundaries is up to a factor of two.
Keywords :
elemental semiconductors; nanostructured materials; phononic crystals; porous semiconductors; silicon; thermal conductivity; four-probe joule heating measurement; hole boundaries; periodically porous silicon nanobeams; phonon thermal conduction; single crystal silicon nanobeams; size 100 nm to 800 nm; temperature 293 K to 298 K; thermal conductivity; Conductivity; Metals; Phonons; Resistance; Silicon; Temperature measurement; Thermal conductivity; Holey Silicon; Phononic Crystal; Porous Silicon; Silicon Porous Nanobeam; Thermal Conductivity;
Conference_Titel :
Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm), 2014 IEEE Intersociety Conference on
Conference_Location :
Orlando, FL
DOI :
10.1109/ITHERM.2014.6892341
