2017
DOI: 10.1073/pnas.1706040114
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Photoacoustic trace detection of gases at the parts-per-quadrillion level with a moving optical grating

Abstract: The amplitude of the photoacoustic effect for an optical source moving at the sound speed in a one-dimensional geometry increases linearly in time without bound in the linear acoustic regime. Here, use of this principle is described for trace detection of gases, using two frequency-shifted beams from a CO 2 laser directed at an angle to each other to give optical fringes that move at the sound speed in a cavity with a longitudinal resonance. The photoacoustic signal is detected with a high-Q, piezoelectric cry… Show more

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Cited by 39 publications
(34 citation statements)
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“…There has been a focus recently to improve the transducing mechanism for PA imaging, involving the use of piezoelectric transducers [ 60 ], quartz based transducers [ 75 , 76 ], and MC-based transducers [ 57 , 74 ]. These have found use as ultrasensitive gas detectors [ 57 , 77 ] because of their high sensitivity (in the parts per trillion range). As the transducer is one of the limiting factors in the effectiveness of PA imaging, and with the development of high sensitivity microelectromechanical systems (MEMS) as transducers, it is likely that transducer improvements will continue to be an area of interest for the foreseeable future.…”
Section: Mechanical Biosensorsmentioning
confidence: 99%
“…There has been a focus recently to improve the transducing mechanism for PA imaging, involving the use of piezoelectric transducers [ 60 ], quartz based transducers [ 75 , 76 ], and MC-based transducers [ 57 , 74 ]. These have found use as ultrasensitive gas detectors [ 57 , 77 ] because of their high sensitivity (in the parts per trillion range). As the transducer is one of the limiting factors in the effectiveness of PA imaging, and with the development of high sensitivity microelectromechanical systems (MEMS) as transducers, it is likely that transducer improvements will continue to be an area of interest for the foreseeable future.…”
Section: Mechanical Biosensorsmentioning
confidence: 99%
“…However, such reports on simultaneous emission of X-ray and THz wave are quite limited to a few reports on targets like Al-coated glass substrate [21], He gas [21], Ar gas [22], or water in solution phase [23]. On the other hand, sound/ultrasound emission, as another emission from laser-induced plasma, has recently emerged as one promising source for microscopy with super-resolution [24,25,26] or has been applied to an advanced analytical method for trace detection of gases at ppm level [27]. Following these progresses in sound technology, combination usages of sound/ultrasound with other emission like X-ray or THz wave are also expected.…”
Section: Introductionmentioning
confidence: 99%
“…Extreme working conditions combined with life-threatening risks, such as intoxication and poisoning of the operators, triggered many remote sensing solutions like the employment of unmanned aerial vehicle (UAVs) [8][9][10].Laser based spectroscopic techniques guarantee a high detection selectivity because of the narrow linewidths characterizing the laser source employed in the visible to the terahertz range, capable of exciting the target molecules while not being absorbed by the gas matrix [11][12][13][14]. The spectral purity of the excitation source, combined with wavelength/amplitude modulation approaches and the efficiency of the optical detection techniques result in reaching detection sensitivity levels as low as parts per quadrillion [15][16][17].Depending on the specific application, these unique characteristics can make laser-based sensors more suitable solutions for remote, fast, selective and sensitive trace gas detections relying on UAVs compared to electrochemical and semiconductor sensors. For instance, a non-dispersive infrared (NDIR) sensor was mounted on a UAV for environmental monitoring and proved to be able to detect CO 2 concentrations of 0.5% in air with a 10 s warm-up time [8].…”
mentioning
confidence: 99%
“…Laser based spectroscopic techniques guarantee a high detection selectivity because of the narrow linewidths characterizing the laser source employed in the visible to the terahertz range, capable of exciting the target molecules while not being absorbed by the gas matrix [11][12][13][14]. The spectral purity of the excitation source, combined with wavelength/amplitude modulation approaches and the efficiency of the optical detection techniques result in reaching detection sensitivity levels as low as parts per quadrillion [15][16][17].…”
mentioning
confidence: 99%