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Abstract

Miniaturized Fourier transform infrared (FT-IR) spectrometers suffer from limited optical throughput due to their tiny aperture size. Therefore, coherent wideband sources with high brightness can provide an advantage over the wideband thermal radiation sources. However, the former ones are available based on pulsed operation. In this work, we present and study a miniaturized FT-IR spectrometer with pulsed light sources including chopped thermal source, semiconductor optical amplifier, Q-switched and femtosecond mode-locked laser sources. A system model for the FT-IR spectrometer system under a modulated input light source is presented. The model accounts for the relatively high scanning speed of the micro-electro-mechanical system (MEMS) interferometer. The signal-to-noise ratio of the spectrometer, due to the light source modulation, is calculated at different values of modulation repetition rate ranging from 20 Hz to 2 MHz, and duty cycle values ranging from 1% to 50%. An analytical expression for the worst-case repetition rate for the spectrometer system is derived. The model results are verified by experimental measurements showing good agreement with the theoretical expectations. Spectroscopic measurements for CO₂ gas with pressure ranging from 300 mbar to 700 mbar are also performed using a high-repetition rate source, and the measured spectra agree with the simulation results demonstrating the utility of the spectrometer.

Keywords

Fourier transform infrared spectroscopy FT-IR spectroscopy micro-electro-mechanical system MEMS technology pulsed sources spectrometer system gas sensing

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References

Fellgett

P.B.

“On the Ultimate Sensitivity and Practical Performance of Radiation Detectors”. J. Opt. Soc. Am. OSA. 1949, 39(11): 970–976.

Schuler

L.P.

Milne

J.S.

Dell

J.M.

, et al. “MEMS-Based Microspectrometer Technologies for NIR and MIR Wavelengths”. J. Phys. D. Appl. Phys. 2009, 42(13): 133001.

Mortada

Erfan

Medhat

, et al. “Wideband Optical MEMS Interferometer Enabled by Multimode Interference Waveguides”. J. Light. Technol. OSA. 2016, 34(9): 2145–2151.

Ayerden

N.P.

Aygun

Holmstrom

S.T.S.

, et al. “High-Speed Broadband FTIR System Using MEMS”. Appl. Opt. 2014, 53(31): 7267–7272.

Y.M. Eltagoury, Y.M. Sabry, D.A. Khalil. Novel Fourier Transform Infrared Spectrometer Architecture Based on Cascaded Fabry-Perot Interferometers. MOEMS and Miniaturized Systems XV. Bellingham, WA: International Society for Optics and Photonics, 2016. P. 97600L.

D. Khalil, Y. Sabry, H. Omran, et al. Characterization of MEMS FTIR Spectrometer. Bellingham, WA: International Society for Optics and Photonics, 2011. P. 79300J.

Y.M. Eltagoury, Y.M. Sabry, D.A. Khalil. “All Silicon Double Cavity Fourier Transform Infrared Spectrometer On Chip”. Adv. Mater. Technol. 2019. 1900441.

Erfan

Sabry

Y.M.

Sakr

, et al. “On-Chip Micro-Electro-Mechanical System Fourier Transform Infrared (MEMS FT-IR) Spectrometer-Based Gas Sensing”. Appl. Spectrosc. 2016, 70(5): 897–904.

S.-H. Shim, D.B. Strasfeld, Y.L. Ling, et al. “Mid-IR Pulse Shaping for Enhanced 2D IR Spectroscopy”. In: Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science. San Jose, CA: May 4–9, 2008. doi: 10.1109/CLEO.2008.4552404.

10.

Ogilvie

J.P.

Kubarych

K.J.

Alexandrou

, et al. “Fourier Transform Measurement of Two-Photon Excitation Spectra: Applications to Microscopy and Optimal Control”. Opt. Lett. 2005, 30(8): 911–913.

11.

Knutsen

K.P.

Johnson

J.C.

Miller

A.E.

, et al. “High Spectral Resolution Multiplex CARS Spectroscopy Using Chirped Pulses”. Chem. Phys. Lett. 2004, 387(4–6): 436–441.

12.

Hult

Watt

R.S.

Kaminski

C.F.

“High Bandwidth Absorption Spectroscopy with a Dispersed Supercontinuum Source”. Opt. Express. 2007, 15(18): 11385–11395.

13.

Kudlinski

Barviau

Leray

, et al. “Control of Pulse-to-Pulse Fluctuations in Visible Supercontinuum”. Opt. Express. 2010, 18(26): 27445–27454.

14.

S. Inoue, Y. Mizuno, K. Kashiwagi, et al. “Degradation of Spectral Linewidth and Signal-to-Noise Ratio in Supercontinuum Generation Process”. In: 17th Microopics Conference (MOC). Sendai, Japan: October 30–November 2, 2011. https://ieeexplore.ieee.org/document/6110362 [accessed Oct 9 2019].

15.

B. Mortada, Y.M. Sabry, M. Nagi, et al. “High-Throughput Deeply-Etched Scanning Michelson Interferometer On-Chip”. In: 2014 International Conference on Optical MEMS and Nanophotonics. Glasgow, UK: August 17–21, 2014. Pp. 161–162. doi: 10.1109/OMN.2014.6924572.

16.

Y.M. Sabry, H. Omran, D. Khalil. “Intrinsic Improvement of Diffraction-Limited Resolution in Optical MEMS Fourier-Transform Spectrometers”. In: National Radio Science Conference (NRSC) Proceedings. Cairo, Egypt: April 28–30, 2014. doi: 10.1109/NRSC.2014.6835093.

17.

Collins

S.D.

Smith

R.L.

Stewart

K.P.

, et al. “Fourier-Transform Optical Microsystems”. Opt. Lett. 1999, 24(12): 844–846.

18.

Ferhanoglu

Seren

H.R.

Lüttjohann

“Lamellar Grating Optimization for Miniaturized Fourier Transform Spectrometers”. Opt. Express. 2009, 17(23): 21289–21301.

19.

M. Kraft, A. Kenda, T. Sandner, et al. “MEMS-based Compact FT-Spectrometers-A Platform for Spectroscopic Mid-infrared Sensors”. In: Proceedings of IEEE Sensors. Lecce, Italy: October 26–29, 2008. Pp. 130–133. doi: 10.1109/ICSENS.2008.4716400.

20.

A. Kenda, A. Frank, M. Kraft, et al. “Compact High-Speed Spectrometers Based on MEMS Devices with Large Amplitude In-Plane Actuators”. Procedia Chem. 2009. 556-559.

21.

A. Kenda, M. Kraft, S. Lüttjohann, et al. “Enabling Mid-IR Spectroscopic Sensing: MEMS-Based High-Speed FT-IR Compact Spectrometers”. In: IEEE Sensors. Limerick, Ireland: October 28–31, 2011. Pp. 1592–1595. doi: 10.1109/ICSENS.2011.6127343.

22.

Wang

Liu

Zhang

, et al. “Fourier Transform Infrared Spectrometer Based on an Electrothermal MEMS Mirror”. Appl. Opt. 2018, 57(21): 5956.

23.

Erfan

Sabry

Y.M.

Ragheb

, et al. Optical Gas Sensing with Miniaturized MEMS FTIR Spectrometers. Bellingham, WA: SPIE Press, 2017.

24.

P.R. Griffiths, J.A. de Haseth. “Theoretical Background”. In: Fourier Transform Infrared Spectrometry. New York: John Wiley and Sons, Inc., 2007.

25.

Sabry

Y.M.

Khalil

Saadany

, et al. “Integrated Wide-Angle Scanner Based on Translating a Curved Mirror of A Cylindrical Shape”. Opt. Express. 2013, 21(12): 13906–13916.

26.

Al-Saeed

T.A.

Khalil

D.A.

“Signal-to-Noise Ratio Calculation in a Moving-Optical-Wedge Spectrometer”. Appl. Opt. 2012, 51(30): 7206–7213.

27.

A.M. Othman, H.E. Kotb, Y. Sabry, et al. “MEMS-Based Fourier Transform Spectrometer Using Pulsed Infrared Light Source”. Proceedings of the SPIE 10545, MOEMS and Miniaturized Systems XVII. 2018. Pp. 105450Y–10545–8.

28.

H.E. Kotb, M.A. Abdelalim, H. Anis. “An Efficient Semi-Vectorial Model for All-Fiber Mode-Locked Femtosecond Lasers Based on Nonlinear Polarization Rotation”. IEEE J. Sel. Top. Quantum Electron. 2014. 20(5): 416-424.

29.

Baumgartl

Ortaç

Limpert

, et al. “Impact of Dispersion on Pulse Dynamics in Chirped-Pulse Fiber Lasers”. Appl. Phys. B. 2012, 107(2): 263–274.

30.

G.P. Agrawal. Nonlinear Fiber Optics. 2013. 5th ed.

31.

HITRAN. “HITRAN on the Web”. 2010. http://hitran.iao.ru/ [accessed Dec 15 2018].

32.

Gordon

I.E.

Rothman

L.S.

Hill

, et al. “The HITRAN2016 Molecular Spectroscopic Database”. J. Quant. Spectrosc. Radiat. Transf. 2017, 203: 3–69.

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Micro-Electro-Mechanical System Fourier Transform Infrared (MEMS FT-IR) Spectrometer Under Modulated–Pulsed Light Source Excitation

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