Difference between revisions of "Optical Fiber Laser-THz Emission Microscope"

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We report the fabrication of an optical-fiber terahertz emitter with
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Terahertz Waves Emitted from an Optical Fiber
a 45-degree wedged tip coated with InAs thin film. The mechanism of
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terahertz generation from the optical fiber tip is explained by the
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We report a simple method of creating terahertz waves by applying the photo-Dember effect in a (100)-oriented InAs film coated onto the 45-degree wedged-end facet of an optical fiber. The terahertz waves are generated by infrared pulses guided through the optical fiber which is nearly in contact with a sample and then measured by a conventional photo-conductive antenna detector. Using this alignment-free terahertz source, we performed proof-of-principle experiments of terahertz timedomain spectroscopy and near-field terahertz microscopy. We obtained a bandwidth of 2 THz and 180-mm spatial resolution. Using this method, the THz imaging resolution is expected to be reduced to the size of the optical fiber core. Applications of this device can be extended to sub-wavelength terahertz spectroscopic imaging, miniaturized terahertz system design, and remote sensing.
photo-Dember effect in low-band gap semiconductor. Applications of
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the devised terahertz emitter can be extended to near-field
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21 June 2010 / Vol. 18, No. 13 / OPTICS EXPRESS 13693
sub-wavelength imaging, spectroscopy, polarization studies and
 
remote sensing.
 

Latest revision as of 09:49, 26 July 2010

Terahertz Waves Emitted from an Optical Fiber

We report a simple method of creating terahertz waves by applying the photo-Dember effect in a (100)-oriented InAs film coated onto the 45-degree wedged-end facet of an optical fiber. The terahertz waves are generated by infrared pulses guided through the optical fiber which is nearly in contact with a sample and then measured by a conventional photo-conductive antenna detector. Using this alignment-free terahertz source, we performed proof-of-principle experiments of terahertz timedomain spectroscopy and near-field terahertz microscopy. We obtained a bandwidth of 2 THz and 180-mm spatial resolution. Using this method, the THz imaging resolution is expected to be reduced to the size of the optical fiber core. Applications of this device can be extended to sub-wavelength terahertz spectroscopic imaging, miniaturized terahertz system design, and remote sensing.

21 June 2010 / Vol. 18, No. 13 / OPTICS EXPRESS 13693