Design, fabrication and characterization of infrared LVOFs for measuring gas composition

Ghaderi, M.; Ayerden, N. Pelin; Emadi, A.; Enoksson, Peter; Correia, J. H.; Graaf, G. de; Wolffenbuttel, R.F.

doi:10.1088/0960-1317/24/8/084001

Cited by 34 publications

(26 citation statements)

References 26 publications

(39 reference statements)

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“…Linear variable optical filters have previously been presented as microspectrometers in the visible [23] and mid-IR [24] with tapered silicon dioxide resonator layers. The optical requirements in LVOF design for the gas filled resonator are different from the typical LVOF design in the sense that a much longer cavity is used, resulting in a higher mode of resonance (m > 10).…”

Section: Lvof Cavity As a Gas Cellmentioning

confidence: 99%

“…Subsequently, the profile of the photoresist is transferred to the desired optical layer lying underneath by one-to-one plasma etching. This fabrication method has previously been used for tapering resonator layers in LVOFs [23,24]. In this paper, the same method is used to taper the first layer of the tapered Bragg mirror.…”

Section: Device Fabricationmentioning

confidence: 99%

“…2(a). Several research groups have reported miniaturized light sources [18][19][20], optical filters [17,[21][22][23][24][25][26][27][28], and detectors [29,30]. However, the sample cell which is used for storing the sample gas occupies a large part of the microspectrometer.…”

Section: Introductionmentioning

confidence: 99%

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Compact gas cell integrated with a linear variable optical filter

2016

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A miniaturized methane (CH 4 ) sensor based on nondispersive infrared absorption is realized in MEMS technology. A high level of functional integration is achieved by using the resonance cavity of a linear variable optical filter (LVOF) also as a gas absorption cell. For effective detection of methane at λ = 3.39 µm, an absorption path length of at least 5 mm is required. Miniaturization therefore necessitates the use of highly reflective mirrors and operation at the 15th-order mode with a resonator cavity length of 25.4 µm. The conventional description of the LVOF in terms of the Fabry-Perot resonator is inadequate for analyzing the optical performance at such demanding boundary conditions. We demonstrate that an approach employing the Fizeau resonator is more appropriate. Furthermore, the design and fabrication in a CMOS-compatible microfabrication technology are described and operation as a methane sensor is demonstrated. 1-3), 191-197 (2000). 604-606 (1990). 42. T. T. Kajava, H. M. Lauranto, and R. R. E. Salomaa, "Fizeau interferometer in spectral measurements," J. Opt. ©2016 Optical Society of AmericaSoc. Am. B 10(11), 1980-1989 (1993). 43. P. Langenbeck, "Fizeau interferometer-fringe sharpening," Appl. Opt. 9(9), 2053-2058 (1970) Characteristics," Appl. Opt. 6(8), 1343-1351 (1967). 49. J. Altmann, R. Baumgart, and C. Weitkamp, "Two-mirror multipass absorption cell," Appl. Opt. 20(6), 995-999 (1981

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Section: Lvof Cavity As a Gas Cellmentioning

confidence: 99%

Section: Device Fabricationmentioning

confidence: 99%

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Compact gas cell integrated with a linear variable optical filter

2016

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“…These users combined constitute a high-volume application, which favors the use of a technique such as CMOS that offers costs advantages in batch fabrication [3]. The characteristic absorption lines of the hydrocarbons are in the mid-infrared (mid-infrared) spectral range between about 3.1 μm and 3.5 μm (Free Spectral Range, FSR = 400 nm at λ o = 3300 nm) and should be measured with a Full-Width Half-Magnitude resolution, FWHM, in the range between λ FWHM = 2 and 5 nm for effective composition measurement [4].…”

Section: Introductionmentioning

confidence: 99%

CMOS-compatible mid-IR metamaterial absorbers for out-of-band suppression in optical MEMS

Ghaderi¹,

Shahmarvandi²,

Wolffenbuttel³

2018

Opt. Mater. Express

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“…They also can be utilized to make up a spectrum detector with a CCD/CMOS camera, remarkably improving the simplicity, stability, and efficiency of the optical splitting system [1][2][3] . A LVOF set as the pivotal optical splitting component of a spectrometer can be applied to applications in aerospace, field detection, atmospheric monitoring, biological fluid detection, chemical sensors, spectral imaging, and so on [4][5][6] . As such, relevant research on LVOF has attracted extensive interest [7][8][9][10][11][12][13][14][15] .…”

mentioning

confidence: 99%

Linear variable filters fabricated by ion beam etching with triangle-shaped mask and normal film coating technique

et al. 2015

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In this Letter, we propose a method of fabricating linear variable filters by ion beam etching with masking mechanisms. A triangle-shaped mask is designed and set between the ion source and sample. During the ion etching, the sample is moved back and forth repeatedly with a constant velocity for the purpose of obtaining the linearly varied thickness of the cavity. Combined with ion beam assistant thermal oxidative electron beam evaporation deposition technology, we finish the fabrication of linear variable filters, whose filtering range is from 500 to 580 nm. The measured results indicate that the transmittance and bandwidth at the peak wavelength are around 40% and 3 nm.

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Design, fabrication and characterization of infrared LVOFs for measuring gas composition

Cited by 34 publications

References 26 publications

Compact gas cell integrated with a linear variable optical filter

Compact gas cell integrated with a linear variable optical filter

CMOS-compatible mid-IR metamaterial absorbers for out-of-band suppression in optical MEMS

Linear variable filters fabricated by ion beam etching with triangle-shaped mask and normal film coating technique

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