1989
DOI: 10.1364/ao.28.003647
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Pyroelectric detection of submicrosecond laser pulses between 230 and 530 μm

Abstract: A continuously tunable far-IR Raman laser has been used to measure the responsivity and the spectral response of uncoated LiTaO(3) pyroelectric detectors between 230 and 530 microm. A striking feature of the spectral response curves is a periodic sequence of maxima and minima, with a modulation factor of >/=75%. Calculations based on the theory of an absorbing Fabry-Perot etalon indicate that these variations correspond to interference fringes produced by multiple reflections at the surfaces of the LiTaO(3) cr… Show more

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Cited by 16 publications
(4 citation statements)
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“…The question of the wavelength responsivity of pyroelectric detectors is more difficult to answer. There has been some experimental evidence from detectors that were similar but not identical to ours, that in the wavelength region 200-500 m, the responsivity exhibits interferencelike fringes and may vary by as much as a factor of 5 [22]. Since the mechanism proposed by the authors of [22] (multiple reflections on the crystal surfaces) depends critically on material thickness, electrode conductivity, etc., it is impossible to extrapolate reliably to our detectors and our wavelength region.…”
Section: B Correction Factorssupporting
confidence: 69%
See 1 more Smart Citation
“…The question of the wavelength responsivity of pyroelectric detectors is more difficult to answer. There has been some experimental evidence from detectors that were similar but not identical to ours, that in the wavelength region 200-500 m, the responsivity exhibits interferencelike fringes and may vary by as much as a factor of 5 [22]. Since the mechanism proposed by the authors of [22] (multiple reflections on the crystal surfaces) depends critically on material thickness, electrode conductivity, etc., it is impossible to extrapolate reliably to our detectors and our wavelength region.…”
Section: B Correction Factorssupporting
confidence: 69%
“…A purely empirical extrapolation of the data of Ref. [22] to the wavelength region 500-2500 m suggests that the intensity variations in the interference fringes may have decreased to about 20% of the average value. This uncertainty will appear as an increase in the systematic error.…”
Section: B Correction Factorsmentioning
confidence: 87%
“…This is a complicated task, especially in the far infrared, where absolute measurements are notoriously difficult and the availability of suitable sources is very limited. It should also be noted that, although pyroelectric detectors are supposed to have a flat spectral response, there have been reports in the literature that this may not be true [38]. The ideal solution to this problem would be a calibration of each detector against a Golay cell, taken over as many discreet wavelengths as possible, in the wavelength region of interest (0.5-2.6 mm); this statement assumes, of course, that the Golay cell itself has a flat spectral response.…”
Section: A Transmission Factorsmentioning
confidence: 99%
“…Characterization of the pyroelectric transducers in the far-infrared and terahertz regions is usually performed by measuring the broadband response of the detector to blackbody radiation of a Fourier transform infrared spectrometer (FTIR) source [27,28]. The use of monochromatic radiation is usually limited to HeNe or CO 2 lasers [29] with a few exceptions [30], since similar radiation sources in the THz region are not common [31,32]. There is also a lack of direct comparisons of different sensors made under identical or at least similar experimental conditions.…”
Section: Introductionmentioning
confidence: 99%