Microstructured Fiber Bragg Gratings

Cusano, A.; Paladino, Domenico; Iadicicco, Agostino

doi:10.1109/jlt.2009.2021535

Cited by 66 publications

(40 citation statements)

References 145 publications

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“…For instance, FBG incorporated MOF sensors can induce a contra-directional coupling between forward and backward fiber modes through resonant scattering and thus perform very well in strain, pressure and microfluidic refractive index sensing applications [27][28][29][30][31][32]. For instance, C. Martelli et al characterized strain and temperature responses of the FBG on the MOF and showed an increased sensitivity to strain by leaky modes of MOFs which was not presented in conventional fibers [27].…”

Section: Microstructured Optical Fiber Bragg Grating Sensorsmentioning

confidence: 99%

Advances in optical fiber Bragg grating sensor technologies

et al. 2012

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Abstract:The authors review their recent advances in the development of optical fiber Bragg grating (FBG) sensor technologies. After a brief review of the fiber grating sensors, several newly developed FBG sensors are described. With the continuous development of fiber materials, microstructures and post-processing technologies, FBG sensors are still creative after the first demonstration of permanent gratings thirty years ago.

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Section: Microstructured Optical Fiber Bragg Grating Sensorsmentioning

confidence: 99%

Advances in optical fiber Bragg grating sensor technologies

et al. 2012

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“…In general, there are two configurations that have been mainly used to design MSF sensors: grating and interferometric-based sensors. In the case of grating-based MSF sensors, Bragg gratings (FBGs) [15] and long-period gratings (LPGs) [16] are inscribed along the MSF; meanwhile, for interferometric geometries, different configurations can be used such as the Mach-Zehnder interferometer [17], Sagnac interferometer (SI) [18], Fabry-Pérot interferometer [19], or Michelson interferometer [20].…”

Section: Introductionmentioning

confidence: 99%

Temperature Sensor Based on an Asymmetric Two-Hole Fiber Using a Sagnac Interferometer

et al. 2018

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We report in this paper a temperature sensor based on an asymmetric two-hole fiber (ATHF) using a Sagnac interferometer (SI) configuration. The operation principle is based on the birefringence change induced by the temperature difference between the air holes and the silica fiber. As a result, the transmitted spectrum of the SI exhibits a sinusoidal profile which is shifted when the temperature is increased. A linear wavelength shift as a function of temperature is observed, and a sensitivity of 2.22 nm/°C was achieved using a 2 m long asymmetric THF, which is in the same order as those previously reported using similar microstructured fibers. The advantage of this system is a linear response, the use of a microstructured fiber with a simpler transverse geometry, and the use of bigger holes which can facilitate the insertion of several materials and improve the sensitivity of the sensor for different applications.

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“…The diameter, uniformity and length of the etched fiber can manipulate the intensity of evanescent field, leading to the change of the reflectivity of the grating and thus its SRI sensitivity [6][7][8]. Moreover, FBGs were also directly written in microstructured optical fiber (MOF) without etching the cladding to improve their SRI sensing performance for specific applications, which is based on the intrinsic interaction between the guided mode and medium introduced into the holes of MOF [9,10]. Nevertheless, the devices made in such a way suffer from rather limited detection dynamic range and low sensitivity, especially for some biological or environmental applications which involve aqueous solutions with low level of SRI [5,11].…”

Section: Introductionmentioning

confidence: 99%

Refractometer probe based on a reflective carbon nanotube-modified microfiber Bragg grating

et al. 2016

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A carbon nanotube (CNT)-modified microfiber Bragg grating (MFBG) is proposed to measure the refractive index with strong enhancement of the sensitivity in low refractive index region. The introduction of the CNT layer influences evanescent field of the MFBG and causes modification of the reflection spectrum. With the increase of the surrounding refractive index (SRI), we observe significant attenuation to the peak of the Bragg resonance while its wavelength almost remains unchanged. Our detailed experimental results disclose that the CNT-MFBG demonstrates strong sensitivity in the low refractive index range of 1.333~1.435, with a peak intensity up to -53.4 dBm/RIU, which is 15-fold higher than that of the uncoated MFBG. Therefore, taking advantage of the CNT-induced evanescent field enhancement, the reflective MFBG probe presents strong sensing capability in biochemical fields.

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Microstructured Fiber Bragg Gratings

Cited by 66 publications

References 145 publications

Advances in optical fiber Bragg grating sensor technologies

Advances in optical fiber Bragg grating sensor technologies

Temperature Sensor Based on an Asymmetric Two-Hole Fiber Using a Sagnac Interferometer

Refractometer probe based on a reflective carbon nanotube-modified microfiber Bragg grating

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