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Jet Propulsion Laboratory, Pasadena, CA

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1 Jet Propulsion Laboratory, Pasadena, CA
MID-IR CAVITY RINGDOWN SPECTROSCOPY FOR ATMOSPHERIC ETHANE TO METHANE RATIO Linhan Shen1, Thinh Bui1, Lance Christensen2, Sally Newman3, Mitchio Okumura1 Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, CA Jet Propulsion Laboratory, Pasadena, CA Division of Geological and Planetary Sciences, California Institute of Technology, Pasadena, CA

2 Anthropogenic Methane Emissions
8%: Other 29%: Natural Gas and Petroleum Systems 10% Manure Management [C2H6]/[CH4] < 1% [C2H6]/[CH4] ~ 15 – 30% [C2H6]/[CH4] ~ 2 - 8% Ethane/Methane ratio is a good indicator for methane source identification. 10%: Coal Mining 26%: Enteric Fermentation 18%: Landfills Inventory of U.S. Greenhouse gas emissions and sinks. (EPA 430-R )

3 Goals and Difficulties
Goal: Measure ethane to methane ratio ([C2H6]/[CH4]) [C2H6] [CH4] Low Atmospheric Abundance ~ 3-15 ppb Hard to Standardize Concentration Atmospheric Abundance ~ 2ppm Relatively Easy to Measure Poorly Constraint Line Intensities Lack of Concentration Standards

4 Mid-IR Cavity Ringdown Spectrometer
Mg(ClO4)2 Filter AOM IC Laser MCT Detector R1 ~ 99.98% R2 ~ 99.98% L ~ 80cm Manufactured by JPL Microdevices Laboratory (MDL) Laser line center: 2977 cm-1 Tunable range: 2972 cm-1 to 2984 cm-1 Peak power: > 15 mW Lehmann, K. K. & Romanini, D, J. Chem. Phys. 105 (23) 10263 C. Borgentun, C. Frez, R. M. Briggs, M. Fradet, S. Forouhar, Optics Express, 23, (2015)

5 Spectrometer Sensitivity Test
For Ethane detection at ~ 2978cm-1: δτ/τ ~ 0.2 % αmin ~ 3.5 × cm-1 Data acquisition rate ~ 100 Hz NEA ~ × 10-9 cm-1Hz-1/2

6 HITRAN Simulation of C2H6 Spectrum

7 Spectra of 6ppb C2H6 in 250 Torr Zero Air
Band Center: cm-1. Summed Line Strength: 4.05 E-19 cm-1/ molecule cm-2 Contains 372 lines. Center of the laser, with the most power. Clear of water interference. 20 (GHz) Scanning Time: 45min Fit: Sum of 2 Lorentzian Distributions.

8 Spectra of 6ppb C2H6 in 250 Torr Zero Air
15 (GHz) Scanning Time: 30min Fit: Lorentzian Distribution. Band Center: cm-1. Summed Line Strength: E-19 cm-1/ molecule cm-2 Contains 48 lines. Edge of the laser. Very low laser power Small amount of water interference.

9 Measurement of 6ppb C2H6 in 250 Torr Zero Air
cm-1 Line cm-1 Line 1 6.29 ppb 5.88 ppb 2 6.15 ppb 6.04 ppb 3 6.32 ppb 5.93 ppb 4 6.22 ppb 6.11 ppb 5 6.07 ppb 6.06 ppb Average 6.21 ± 0.10 ppb 6.00 ± 0.10 ppb

10 Goals and Difficulties
Goal: Measure ethane to methane ratio ([C2H6]/[CH4]) [C2H6] [CH4] Low Atmospheric Abundance ~ 3-15 ppb Hard to Standardize Concentration Atmospheric Abundance ~ 2ppm Relatively Easy to Measure Poorly Constraint Line Intensities Lack of Concentration Standards

11 Solution for Concentration Standardization
0.5% [C2H6]: [CH4] Ethane Methane Mixtures in Zero Air Measure Ethane Abundance Using Two Lines in the MIR Measure Methane Abundance Using MIR and NIR CRDS Cross Calibrate Methane Abundance Measurement with Picarro Standardized Ethane Abundance Measurement

12 Atmospheric Sample Collections
Caltech Site Urban Air Samples collected in an evacuated 2L glass bulb. Water in the samples is removed by passing through a Mg(ClO4)2 filter. Each bulb is filled up to atmospheric pressure. Beach Site Clean Air

13 MIR Measurement of Air Sample
Measurement of cm-1 line. A multi-Lorentzian fit was done to calculate abundances of CH4 and C2H6. C2H6 Cavity Pressure: 350 Torr CH4 35 (GHz) H2O

14 MIR Measurement of Air Sample
Measurement of the cm-1 line A 2-Lorentzian fit was done to calculate abundance of C2H6. Cavity Pressure: 350 Torr C2H6 20 (GHz)

15 Correlation between Ethane and Methane Abundance
[C2H6] vs. [CH4]

16 Atmospheric Carbon Sources
Source Correlation Plot Increasing Natural Gas Emission Increasing Fossil Fuel Burning

17 Future Work Increase scan efficiency. Decrease scanning duration from 30 – 45 min to less than 5 min. Frequency stabilize the cavity to increase sensitivity. Redesign sample introduction system to adapt the spectrometer to a mobile measurement system.

18 Acknowledgement Funding:
Grant: This project is funded by JPL and Caltech President’s and Director’s Fund (PDF) Student Fellowships: Linhan Shen and Thinh Q. Bui are both supported by NASA NESSF fellowship. Support: JPL microdevice laboratory (MDL) for manufacturing the high power MIR IC Laser.

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