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Article

An Efficient and Compact Difference-Frequency-Generation Spectrometer and Its Application to 12CH3D/12CH4 Isotope Ratio Measurements

1
Department of Environmental Science and Technology, Interdisciplinary Graduate School of Science and Engineering, Tokyo Institute of Technology/4259, Nagatsuta-cho, Midori-ku, Yokohama, 226-8502, Japan
2
SENTAN, Japan Science and Technology Agency/Sanbancho 5, Chiyoda-ku, Tokyo 102-0075, Japan
3
Department of Physics, Faculty of Science and Technology, Keio University/3-14-1, Hiyoshi, Kohoku-ku, Yokohama, 223-8522, Japan
*
Author to whom correspondence should be addressed.
Sensors 2010, 10(7), 6612-6622; https://doi.org/10.3390/s100706612
Submission received: 4 February 2010 / Revised: 28 April 2010 / Accepted: 7 June 2010 / Published: 9 July 2010
(This article belongs to the Special Issue Laser Spectroscopy and Sensing)

Abstract

:
We have developed an efficient and compact 3.4 μm difference-frequency-generation spectrometer using a 1.55 μm distributed feedback (DFB) laser diode, a 1.06 μm DFB laser diode, and a ridge-waveguide periodically poled lithium niobate. It is continuously tunable in the 30 cm−1 span and is applied to 12CH3D/12CH4 isotope ratio measurements. The suitable pair of 12CH3D ν4 pP(7,6) and 12CH4 ν 24 R(6) F1(1) lines enabled us to determine their isotope ratio with a precision repeatability of 0.8‰ using a sample and a working standard of pure methane with an effective signal averaging time of 100 ms.

1. Introduction

Accurate isotope ratio measurements of environmental substances have been utilized to determine their production, transfer, and consumption processes. Conventionally, the isotope ratio has been determined by mass-spectrometer measurements because of the high sensitivity and accuracy possible with this technique. Recently, laser spectrometers have been applied to isotope ratio measurement, despite their relatively low sensitivity, because laser spectroscopy is more sensitive than mass spectrometry in some cases [1]. For example, it is able to distinguish isotopic molecules (isotopomers) with the same or almost equal weight (e.g., distinguishing 15N14N16O from 14N15N16O, and 12CH3D from 13CH4) without the dissociations or conversion processes that are usually required for mass spectrometry in such cases.
In the mid-infrared region, most molecules have strong absorption lines in the fundamental vibration band. However, light sources for mid-infrared spectroscopy have developed less remarkably than those in the near-infrared and visible regions. Recent development of tunable mid-infrared light sources, such as quantum cascade lasers and difference-frequency-generation (DFG) systems, has gradually driven their application to accurate spectroscopic measurement of trace gas, including isotope ratio measurements [111].
We have developed an efficient and compact 3.4 μm DFG light source using a 1.55 μm distributed feedback (DFB) laser diode, a 1.06 μm DFB laser diode, and a ridge-waveguide periodically poled lithium niobate (PPLN) [12]. The wavelength conversion of the PPLN is efficient, typically from 1 to 15%/W, which has been applied to molecular spectroscopy [1316]. The particular device we used has an efficiency of 5 %/W; thus, pump and signal waves, even from low-power diode lasers, can be converted to 7.5 μW mid-infrared waves sufficient for linear absorption spectroscopy. The two DFB lasers provide a 30 cm−1 continuous tuning range, similar to reference [14], and optical fibers and fiber couplers reduce the labor involved in optical alignment. They also contribute to the compact and flexible design of the spectrometer.
The laser technique has been employed in isotope ratio measurement of methane [2,10,11,1722] because it does not require the decompositions necessary in mass spectrometry. This is the initial report on such an application of the present spectrometer. Since it has a wider continuous tunable range in the strong fundamental band than those used in the previous works, we are able to choose an isotope pair appropriate for the measurement. Using pure sample gas, we have demonstrated that the spectrometer has potential for accurate isotope ratio measurements of environmental sample gas. To this end, it will be necessary to use an enhanced-cavity or multi-pass absorption cell and a preconcentration process because the 12CH3D/12CH4 ratio is 25 times smaller than the 13CH4/12CH4 ratio.

2. Methods

2.1. Experimental Setup

Figure 1 depicts a schematic diagram of the spectrometer. The DFG source consists of a ridge-waveguide PPLN (NEL, model WD-3360-000-A-B-C) with a conversion efficiency of 5 %/W, a 1.55 μm distributed feedback (DFB) laser diode module (Anritsu, model AB5A1102M521D) with a pigtail fiber output as a signal source, and a 1.064 μm DFB laser diode (Hamamatsu Photonics, model LA0927LP) as a pump source. The pump and signal lasers are each connected to an injection-current-temperature controller (ILX Lightwave, model LDC-3744B). The pump laser is mounted on a laser mount (Thorlabs, model LDM21) with a Peltier element, a thermistor, and a collimation lens.
The pump wave passes through an optical isolator (OFR, model IO-2.5-1064-VLP) and then an anamorphic prism pair (Thorlabs, model PS879-C), which transforms the beam shape from elliptical to circular for efficient coupling with an optical fiber. Half- and quarter-wave plates adjust the polarization of the pump wave for efficient wavelength conversion. The pump wave is then coupled with a polarization-maintaining (PM) single-mode fiber by a spatial-beam fiber coupler. The parallel-polarized signal (5 mW) and pump (30 mW) waves are combined by a PM fiber coupler and fed into the PPLN module through a pigtail fiber. A Peltier element and a thermistor in the PPLN module are connected with a temperature controller (ILX Lightwave, model LDT-5412) for phase matching. The generated 3.4 μm idler wave of 7.5 μW is sufficient for linear absorption spectroscopy, even though the total wavelength conversion efficiency is reduced due to loss at the spatial-beam fiber coupler, the PM fiber coupler, and three fiber connectors. The mid-infrared source is compact in dimension: the housings individually mounting the two DFB lasers and the PPLN are smaller than 100 cm3. The current sources and the temperature controllers used are typical commercially available products for low power consumption, and optical fibers reduce the number of mirror mounts and amount of space for optical alignment. The temperature tuning range of the individual laser device is 15 cm−1 without any frequency gap; therefore, the DFG source is tunable from 2,950 to 2,980 cm−1. The phase-matching condition of the PPLN is attained by temperature-tuning, and the single ridge-waveguide PPLN operates in the wavenumber range of 60 cm−1.
The idler wave is collimated by a sapphire lens and passes through a quartz wedge separating one tenth of the power level from the idler wave. The main beam enters a 150-cm-long absorption cell fitted with CaF2 windows, and the 470 cm3 volume is filled with 80 μmol of pure methane at a pressure of 400 Pa. The transmitted idler wave is sent back to the cell by a flat mirror, then reflected and focused onto a liquid-nitrogen-cooled InSb photodiode (Hamamatsu Photonics, model P5968-100) with the pump and signal waves removed by a 3.4 μm bandpass filter. The separated beam is immediately detected by another similar detector in order to monitor variations in the incident power level. The idler frequency is swept and modulated by superposing a 0.1 Hz triangle signal and a 5 kHz sinusoidal signal on the injection current of the 1.55 μm DFB laser. The modulation frequency is set at the highest response frequency of the detector [23,24]. The corresponding modulation depth is 250 MHz peak-to-peak, comparable with the absorption line width for obtaining a large signal without significant modulation broadening.
The detected signals are demodulated at 5 kHz (1f detection) by two lock-in amplifiers (Stanford Research Systems, model SR810) with a time constant of 10 ms. The 1f signals as well as the sweep signal are stored by the lock-in amplifiers at the acquisition rate of 500 Hz, corresponding to 2,500 data points in the up/down sweep of the idle frequency. The 1f signals are recorded ten times by the lock-in amplifiers, and the averaged spectrum is stored in a PC. The frequency sweep rate is limited by the time constant, the acquisition time, and the memory size of the lock-in amplifiers. The absorption cell is connected with a molecular turbo pump, an absolute pressure gauge (Edwards, 655AB) with an accuracy of 0.15 %, and two gas containers for exchanging sample and working standard gases. Neither the absorption cell temperature nor the room temperature is stabilized.

2.2. Absorption Lines for Isotope Ratio Measurement

Line selection has been discussed and analyzed [10,22,25,26]. Table 1 lists a pair of 12CH4 and 12CH3D lines with asterisks suitable for precisely measuring the isotope ratio together with the adjacent absorption lines having a line intensity exceeding 1.0 × 10−25 cm−1/(molecule·cm−2) [27]. The ν4 pP(7, 6) line is one of the strongest lines of the less abundant 12CH3D. It does not seriously overlap the lines of 12CH4 and 13CH4, and it has a transition frequency and absorption intensity similar to those of the ν2 + ν4 R(6) F1(1) line of 12CH4, which are favorable characteristics for measuring the isotope ratio. Therefore, the weak overtone band transition is chosen for the major isotope [10,22]. The absorption coefficient depends on temperature of −0.066 and −0.14 %/K at 295 K for the 12CH3D ν4 pP(7,6) and 12CH4 ν2 + ν4 R(6) F1(1) lines; therefore, the ratio has a low temperature dependence of 0.074 %/K, which is another advantage of the present pair.
Figure 2 plots the observed spectrum involving these transitions. The absorption lines have a dispersion-like shape because of the 1f detection in wavelength-modulation spectroscopy. The thin red curve is drawn on a scale 300 times larger than the thick blue curve, and the vertical scale is indicated on the right side of Figure 2. Most small variations in the spectral curves come from the weak absorption lines partially listed in Table 1. The signal-to-noise ratio is limited by some periodic distortion with a typical magnitude of 0.001 V, which will be discussed in Section 3.2. The absorbance is 6 % for the 12CH3D ν4 pP(7,6) line and 40 % for the 12CH4 ν2 + ν4 R(6) F1(1) line at a sample pressure of 400 Pa. These values lie in the desirable range for sensitivity and signal linearity. The idler wave changes in output power as the injection current of the 1.55 μm DFB laser, and the power level at the 12CH3D ν4 pP(7,6) line is 1.5 times higher than that at the 12CH4 ν2 + ν4 R(6) F1(1) line. Therefore, residual amplitude modulation (RAM) inducing asymmetries in signal line shapes on wavelength modulation spectroscopy affects the 1f signal differently for the 12CH3D and 12CH4 lines. These asymmetries, however, do not affect the signal amplitude or detection sensitivity [24].

2.3. Isotope Ratio Determination

Here we define the signal ratio R as:
R 12 CH 3 D = I 1 f 12 CH 3 D / I 1 f 12 CH 4
where I1f is the peak-to-peak amplitude of the 1f signal. The values of R for the working standard (WS) and the sample are alternately measured. The δ value of the isotope ratio is then determined by:
δ 12 CH 3 D Sample-WS = ( R Sample 12 CH 3 D R WS 12 CH 3 D ) / R WS 12 CH 3 D
Here, the value of RWS is the average of the working-standard measurements immediately before and after the particular sample measurement to eliminate the effect of uniform signal drift discussed in Section 3.3.
The hydrogen isotope ratio is reported as a value relative to the international standard Vienna Standard Mean Ocean Water (VSMOW) for δD. The value of δ12CH3DSample-WS is converted to that of δ12CH3D Sample-VSMOW as follows:
δ 12 CH 3 D Sample-VSMOW = 1 + δ 12 CH 3 D Sample-WS 1 + δ 12 CH 3 D WS-VSMOW 1

2.4. Sample and Standard Gases

We measured the isotope ratio of the sample and the working standard of pure methane gas whose δDVSMOW was determined to be −289.9 ± 2.8 and −183.2 ± 1.5‰ using a gas chromatograph high-temperature conversion IRMS (GC/ TC/IRMS, Delta XL, Thermo Finnigan, Bremen, Germany).
The value of δ12CH3D (the isotopomer ratio) determined from the present laser measurements is easily converted to that of δD-CH4 (the hydrogen isotope ratio of methane), because we use isotopically natural methane, for which the effects of other isotopomers (e.g., 13CH3D and 12CH2D2) are extremely small [28].

3. Results and Discussion

3.1. Sensitivity of the Spectrometer

To evaluate the spectrometer sensitivity, we recorded the 1f signal for an evacuated cell. We found a periodic distortion in the baseline with a period of 0.05 cm−1. This interference fringe is caused by weak reflection at the anti-reflection-coated interfaces of the 5-cm-long PPLN with a refractive index of 2.1. We reduced the distortion by dividing the mid-infrared beam into two, using a quartz wedge, and subtracting the 1f signal without any sample from that with the sample. In this way, spectra such as Figure 2 were recorded, attaining a detectable absorbance of < 1 × 10−4 with an effective signal averaging time of 100 ms. Accordingly, the signal-to-noise ratio was enhanced from 100 to 1,000 for the 12CH3D ν4 pP(7,6) line. The resultant signal still had another smaller periodic distortion in the baseline with a period of 0.2 cm−1, probably because of the Brewster windows of the absorption cell. Distortion amplitude was sensitive to optical alignment and wavelength, limiting the minimum detectable coefficient to 4 × 10−9 cm−1·Hz−1/2. The sensitivity satisfied the necessary condition for determining the isotope ratio at an uncertainty level of 1 ‰.

3.2. Pressure Dependence of the Signal Ratio

Figure 3 illustrates the pressure dependence of the signal ratio RCH3D of Equation (1). The sample pressure is measured with the pressure gauge to an accuracy of 2 Pa. The large pressure dependence of 0.4 ‰/Pa at a pressure of 300 Pa is due to the difference of 5 to 1 in absorbance of 12CH4 to 12CH3D, and the exponential relation in the Lambert Beer's law between the absorbance and the pressure. Therefore, the pressure of the sample and the working standard must be identical with an uncertainty of 2.5 Pa for a 1-‰-level measurement.

3.3. Precision and Accuracy of the Isotope Ratio Measurement

The absorption cell is alternately refilled with the working standard and the sample methane. The gas pressure is carefully set at (400 ± 1) Pa, and the value remains constant within ±1 Pa from the initial value during the measurement. Figure 4 depicts the temporal variation of the alternate isotope ratio measurements.
The plots of the sample and the working standard similarly drift by a relative magnitude of 0.46 and 0.36 % on a time scale of an hour, probably because of the temperature variation. If it were due to only the temperature dependence of the absorption coefficient ratio discussed in Section 2.2, the room temperature would change by 6 K. Since it is one order of magnitude larger than the actual condition, we attribute it to the other slow variations of the optical alignment and the electric circuits. To remove the slow effect, we use the averaging procedure described in Section 2.3. The values of δ12CH3D Sample-VSMOW are then determined to be −294.2, −295.6, −293.7, and −293.5‰, yielding an average of −294.2‰ and the standard deviation of 0.8‰. The averaged δ12CH3DSample-VSMOW value is a little lower than the value of −289.9 ± 2.8‰ determined by a mass spectrometer. The difference is slightly beyond experiment uncertainty. This is the first report of the isotope ratio measurements by the present spectrometer. The result is tentative, and further measurements are required for comparison between laser spectroscopy and mass spectrometry.

4. Conclusions

We have developed a compact 3.4 μm DFG spectrometer using 1.06 and 1.55 μm DFB lasers and a waveguide PPLN, and precisely measured the 12CH3D/12CH4 ratio of pure methane having natural isotope abundance (12CH3D / 12CH4 < 0.1%). We determined the value of δVSMOW of the sample from four repetitive measurements using the working standard. The standard deviation is as small as 0.8‰, and the average is −294.2‰, which is slightly lower than −289.9 ± 2.8‰ determined by mass spectrometry.

Acknowledgments

We are grateful to SENTAN, Japan Science and Technology, for financial support.

References and Notes

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Figure 1. Schematic diagram of the experiment set-up. DFB: distributed feedback laser diode. I-V: current-voltage converter.
Figure 1. Schematic diagram of the experiment set-up. DFB: distributed feedback laser diode. I-V: current-voltage converter.
Sensors 10 06612f1
Figure 2. Recorded spectrum involving a suitable pair of 12CH3D and 12CH4 lines.
Figure 2. Recorded spectrum involving a suitable pair of 12CH3D and 12CH4 lines.
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Figure 3. Pressure dependence of the signal ratio, RCH3D = I1fCH3D/I1fCH4.
Figure 3. Pressure dependence of the signal ratio, RCH3D = I1fCH3D/I1fCH4.
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Figure 4. Alternate measurements of the signal ratio of 12CH3D/12CH4 of the working standard (circles) and the sample methane (triangles).
Figure 4. Alternate measurements of the signal ratio of 12CH3D/12CH4 of the working standard (circles) and the sample methane (triangles).
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Table 1. Absorption lines of 12CH3D and 12CH4 in the vicinity of the pair for isotope ratio measurement (HITRAN 2008 [27]).
Table 1. Absorption lines of 12CH3D and 12CH4 in the vicinity of the pair for isotope ratio measurement (HITRAN 2008 [27]).
AssignmentWavenumber [cm−1]Line intensity @296 K [cm−1/(molecule·cm−2) ]Lower-level energy [cm−1]
12CH42 P(14) F1(1)2950.48192.826 × 10−241095.6320
*12CH4 ν2 + ν4 R(6) F1(1)2950.53181.354 × 10−22219.9411
12CH4ν3 + ν4 − ν4 P(6) E2950.55192.914 × 10−231521.2847
12CH4ν2 + ν3 − ν2 P(5) E2950.55964.464 × 10−241692.8063
12CH4ν2 + ν4 R(6) E2950.57758.566 × 10−25219.9133
12CH4ν3 + ν4 − ν4 P(11) F2(1)2950.61755.102 × 10−251935.4170
12CH4ν3 + ν4 − ν4 P(9) A2(2)2950.64281.415 × 10−241773.7814
12CH3D ν4 pP (8,2)2950.64896.712 × 10−24284.5492
12CH4ν2 + ν4 R(9) F1(3)2950.66014.011 × 10−23470.8548
12CH3D 2ν5 rQ (9,1)2950.77841.872 × 10−25350.1516
12CH4ν2 + ν4 R(9) F1(1)2950.79825.009 × 10−25470.7167
12CH4ν3 + ν4 − ν4 P(12) A2(1)2950.80212.272 × 10−252101.1899
*12CH3D ν4 PP (7,6)2950.85082.734 × 10−23266.3169
12CH4ν3 + ν4 − ν4 P(9) F2(5)2950.85482.280 × 10−251775.9617
12CH4ν1 + ν4 − ν4 R(7) F2(3)2950.86271.447 × 10−241599.2841

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MDPI and ACS Style

Tsuji, K.; Teshima, H.; Sasada, H.; Yoshida, N. An Efficient and Compact Difference-Frequency-Generation Spectrometer and Its Application to 12CH3D/12CH4 Isotope Ratio Measurements. Sensors 2010, 10, 6612-6622. https://doi.org/10.3390/s100706612

AMA Style

Tsuji K, Teshima H, Sasada H, Yoshida N. An Efficient and Compact Difference-Frequency-Generation Spectrometer and Its Application to 12CH3D/12CH4 Isotope Ratio Measurements. Sensors. 2010; 10(7):6612-6622. https://doi.org/10.3390/s100706612

Chicago/Turabian Style

Tsuji, Kiyoshi, Hiroaki Teshima, Hiroyuki Sasada, and Naohiro Yoshida. 2010. "An Efficient and Compact Difference-Frequency-Generation Spectrometer and Its Application to 12CH3D/12CH4 Isotope Ratio Measurements" Sensors 10, no. 7: 6612-6622. https://doi.org/10.3390/s100706612

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