Title :
Thermoplasmonic Membrane-Based Infrared Detector
Author :
Fei Yi ; Hai Zhu ; Reed, Jason C. ; Zhu, Alexander Y. ; Cubukcu, Ertugrul
Author_Institution :
Dept. of Mater. Sci. & Eng., Univ. of Pennsylvania, Philadelphia, PA, USA
Abstract :
In this letter, we experimentally demonstrate, by integrating plasmonic nanoantennas, that membrane-based micromechanical resonators can become infrared (IR) active. The photo-thermomechanical effect induced by nanoantennas enables actuation of mechanical structures. Using this hybrid nanoantenna coupled mechanical device as a thermal IR detector, we achieved a current responsivity of 12 mA/W corresponding to a displacement responsivity of 98.7 μm/W and a thermal time constant of 5.7 ms at a wavelength of 6 μm. This approach can be extended to any mechanical resonator for new optomechanical sensing modalities.
Keywords :
infrared detectors; membranes; metamaterial antennas; micro-optomechanical devices; micromechanical resonators; nanophotonics; optical sensors; photothermal effects; plasmonics; current responsivity; displacement responsivity; hybrid nanoantenna coupled mechanical device; infrared active; mechanical structures; membrane-based micromechanical resonators; optomechanical sensing modalities; photothermomechanical effect; plasmonic nanoantenna integration; thermal IR detector; thermal time constant; thermoplasmonic membrane-based jnfrared detector; time 5.7 ms; wavelength 6 mum; Absorption; Gold; Noise; Optical interferometry; Optical resonators; Optical sensors; Plasmons; Nanoantenna; infrared; nanomechanical resonator; plasmonic absorber; thermal detector;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2013.2292307
