Miniaturized optical spectrometers providing broadband operation and fine resolution have an immense potential for applications in remote sensing, non-invasive medical diagnostics and astronomy. Indeed, optical spectrometers working in the mid-infrared spectral range have garnered a great interest for their singular capability to monitor the main absorption fingerprints of a wide range of chemical and biological substances. Fourier-transform spectrometers (FTS) are a particularly interesting solution for the on-chip integration due to their superior robustness against fabrication imperfections. However, the performance of current on-chip FTS implementations is limited by tradeoffs in bandwidth and resolution. Here, we propose a new FTS approach that gathers the advantages of spatial heterodyning and optical path tuning by thermo-optic effect to overcome this tradeoff. The high resolution is provided by spatial multiplexing among different interferometers with increasing imbalance length, while the broadband operation is enabled by fine tuning of the optical path delay in each interferometer harnessing the thermo-optic effect. Capitalizing on this concept, we experimentally demonstrate a mid-infrared SiGe FTS, with a resolution better than 15 cm−1 and a bandwidth of 603 cm−1 near 7.7 μm wavelength with a 10 MZI array. This is a resolution comparable to state-of-the-art on-chip mid-infrared spectrometers with a 4-fold bandwidth increase with a footprint divided by a factor two.
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机译:能够提供宽带操作和高分辨率的微型光学光谱仪在遥感,非侵入性医学诊断和天文学中的应用具有巨大的潜力。的确,在中红外光谱范围内工作的光谱仪以其独特的能力来监视各种化学和生物物质的主要吸收指纹,引起了人们极大的兴趣。傅里叶变换光谱仪(FTS)由于对制造缺陷的超强耐用性而成为片上集成的一个特别有趣的解决方案。但是,当前片上FTS实现的性能受到带宽和分辨率的折衷的限制。在这里,我们提出了一种新的FTS方法,该方法通过热光效应来收集空间外差和光路调整的优势,以克服这种折衷。高分辨率是通过不平衡长度不断增加的不同干涉仪之间的空间复用来提供的,而宽带操作是通过利用热光效应对每个干涉仪中的光路延迟进行微调来实现的。利用这一概念,我们通过实验证明了中红外SiGe FTS,其分辨率优于15 cm -1 ,在7.7μm波长附近的带宽为603 cm -1 与10 MZI阵列。该分辨率可与最新的片上中红外光谱仪相媲美,带宽增加了4倍,占地面积除以2。
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