Nanomechanical Torsional Resonators for Frequency-Shift Infrared Thermal Sensing
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1.
California Institute of Technology
Abstract
We investigate use of nanomechanical torsional resonators for frequency-shift-based infrared (IR) thermal sensing. Nanoscale torsion rods, ∼1 μm long and 50–100 nm in diameter, provide both extraordinary thermal isolation and excellent angular displacement and torque sensitivities, of order ∼10⁻⁷ rad·Hz^(–1/2) and ∼10⁻²² (N·m) Hz^(–1/2), respectively. Furthermore, these nanorods act as linear torsional springs, yielding a maximum angular displacement of 3.6° and a dynamic range of over 100 dB; this exceeds the performance of flexural modes by as much as 5 orders of magnitude. These attributes lead to superior noise performance for torsional-mode sensing. We demonstrate the operational principles of torsional-mode IR detection, attaining an uncooled noise equivalent temperature difference (NETD) of 390 mK. By modeling the fundamental noise processes, we project that further reduction of device size can significantly improve thermal responsivity; a room-temperature NETD below 10 mK appears feasible.
Copyright and License
© 2013 American Chemical Society.
Acknowledgement
We thank L.G. Villanueva for stimulating discussions, X. L. Feng for a critical reading of the manuscript, R. B. Karabalin for help in the optical measurement, D. Chi for assistance in electron beam lithography, and J. E. Sader acknowledges support from the Australian Research Council grants scheme. We are grateful for the support from DARPA/MTO under the Grant W31P4Q-10-1-0006.
Conflict of Interest
The authors declare no competing financial interest.
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Additional details
- ISSN
- 1530-6992
- Australian Research Council
- Defense Advanced Research Projects Agency
- W31P4Q-10-1-0006
- Caltech groups
- Kavli Nanoscience Institute