Measuring attostrains in a slow-light fiber Bragg grating

SPIE OPTO Pub Date : 2016-03-23 DOI:10.1117/12.2220219

G. Skolianos, Arushi Arora, M. Bernier, M. Digonnet

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引用次数: 16

Abstract

We report a new generation of slow-light FBG strain sensor with a strain resolution (or minimum detectable strain) as low as 30 fepsilon/√Hz at 30 kHz, which is one order of magnitude lower than the record held by the previous generation. This sensor has an ultra-stable output (no drift in 4 days) and is capable of resolving an absolute strain of ~250 attostrains by integrating its output for ~8 hours, which is also a new record for an FBG fiber sensor. These improvements were accomplished by first maximizing the slope of the slow-light resonances, and hence the strain sensitivity. To this end the apodized FBG was written in a deuterium-loaded fiber with a femtosecond infrared laser, then thermally annealed. The three main sources of noise in the sensor system were also carefully reduced. The dominant source of noise, laser frequency noise, was reduced by interrogating the FBG with an ultra-stable laser (linewidth under 200 Hz) with a low intensity noise. The phase noise was minimized by selecting the proper FBG length (~25 mm). When used as an acoustic sensor, the same grating had a measured average pressure resolution of 50 μPa/√Hz between 3 kHz and 6 kHz, one order of magnitude lower than the previous lowest reported value for an FBG sensor.

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测量慢光光纤布拉格光栅中的原子应变

我们报告了新一代慢光FBG应变传感器，其应变分辨率(或最小可检测应变)在30 kHz时低至30 fepsilon/√Hz，比上一代保持的记录低一个数量级。该传感器具有超稳定的输出(4天内无漂移)，并且能够通过集成其输出约8小时来解析~250阿应变的绝对应变，这也是FBG光纤传感器的新记录。这些改进是通过首先最大化慢光共振的斜率，从而最大化应变灵敏度来实现的。为此，采用飞秒红外激光器将光电化的光纤光栅写入氘负载光纤中，然后进行热退火。对传感器系统中的三个主要噪声源也进行了细致的降低。通过使用低强度噪声的超稳定激光器(线宽低于200 Hz)对光纤光栅进行询问，降低了主要噪声源激光频率噪声。通过选择合适的光纤光栅长度(~ 25mm)，使相位噪声降到最低。当用作声传感器时，同一光栅在3 kHz和6 kHz之间的测量平均压力分辨率为50 μPa/√Hz，比之前报道的FBG传感器的最低值低一个数量级。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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