Optical Frequency References at 1542 nm: Precision Spectroscopy of the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 Lines of ¹²⁷I₂ at 514 nm

Abstract

Frequency-stabilized lasers are fundamental topics in research relating to optical frequency and wavelength standards. The absolute frequencies and hyperfine structures of the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 lines of molecular iodine (¹²⁷I₂) at 514 nm were measured using a frequency-stabilized laser based on modulation transfer spectroscopy. The hyperfine splitting of each line was fitted to a four-term Hamiltonian with an uncertainty of several kilohertz to obtain the hyperfine constants for the line. A total of 97 hyperfine transitions of the six lines were measured with an uncertainty of 5.6 kHz (fractionally 9.6 × 10⁻¹²). They can provide new optical frequency references for telecommunication and other applications.

1. Introduction

Optical frequency standards [1] in telecommunication wavelength bands are useful not only for the management of the channel frequency of Dense Wavelength Division Multiplexing (DWDM) systems but also for other applications, including precision measurement and satellite communication. Besides acetylene [2,3,4] and Rb [5,6] optical frequency (or wavelength) standards, optical frequency standards at telecommunication wavelengths have recently been developed using frequency-stabilized lasers based on the precision spectroscopy of molecular iodine [7]. The acetylene optical frequency standard uses an optical cavity in the spectroscopic system. Therefore, this system is not reliable enough for long-term operation because the optical cavity is sensitive to environmental vibration. The Rb optical frequency standard uses a magnetic shield in the spectroscopic system, which is relatively difficult to handle, to reduce the frequency shift of the spectrum due to the magnetic field in the environment. The iodine-based optical frequency standard at the telecommunication wavelength has the advantages of a simple setup and reliability (without an optical cavity or magnetic shield in the spectroscopic system) over acetylene and Rb standards. Precision spectroscopy was performed on three iodine lines [8] (blue dashed lines in Figure 1) close to the tripled frequency of the P(16) line of ¹³C₂H₂ (red line in Figure 1), which is recommended by the International Committee for Weights and Measures (CIPM) as an optical frequency standard at telecommunication wavelengths [9]. We also measured the hyperfine structure of the seven iodine lines in the same wavelength region (six of them have the same excited-state vibrational quantum number v′ = 44) to study the rotation dependence of the excited state hyperfine constants [10]. These seven lines are shown in Figure 1 as blue dot-dashed lines (two of them are close and overlap in Figure 1). As shown in Figure 1, there are several other iodine lines with excited-state vibrational quantum numbers other than v′ = 44 and, in some cases, relatively low intensity (green lines in Figure 1) [11]. They are the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 lines of ¹²⁷I₂ at 514 nm. These lines have not been investigated using Doppler-free laser spectroscopy, and their hyperfine structures have not yet been resolved. The absolute frequencies of these lines were only measured for the Doppler-limited line (an overlap of all the Doppler-broadened hyperfine structures in the line) center using Fourier transform spectroscopy with an uncertainty of several tens of megahertz [11].

In this study, we performed Doppler-free laser spectroscopy based on modulation transfer spectroscopy [12,13] for the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 lines of ¹²⁷I₂ at 514 nm. This study is a continuation of our previous works [8,10] and focuses on some relatively weak iodine lines. The absolute frequencies and hyperfine transitions of the lines were measured with an uncertainty of 5.6 kHz, which is an improvement of approximately four orders of magnitude compared to that of the Doppler-limited measurement [11]. The hyperfine constants for each line were obtained by fitting the observed hyperfine structure to a four-term Hamiltonian equation [14]. The observed 97 hyperfine transitions of the six iodine lines provide new optical frequency references for telecommunications and other applications, including optical frequency combs. In telecommunication applications, the obtained new optical frequency references can be used for DWDM channels where no frequency reference is available. In the frequency comb system, the obtained frequency-stabilized laser in the telecom wavelength region can serve as the frequency reference for Er-fiber combs [7].

2. Experiment

In this study, an external-cavity diode laser at 1542 nm (RIO PLANEX) was used for spectroscopy and laser frequency stabilization. The output of the laser light was injected into an Er-doped fiber amplifier for power amplification. The amplified laser output was sent to a periodically poled lithium niobate (PPLN) waveguide [7] for the third-harmonic generation (THG) at 514 nm. The generated THG light was used for Doppler-free spectroscopy of molecular iodine based on modulation transfer spectroscopy [12,13]. The iodine spectrometer contained a 30 cm-long iodine cell. In the modulation transfer spectroscopy, a pump beam with phase modulation was used to saturate the iodine absorption. The phase modulation was set to 220 kHz using an acousto-optic modulator. A probe laser beam was used to detect the saturation dip through modulation transfer [12,13]. The modulation on the pump beam was transferred to the probe beam only when saturation occurred. The probe beam was sent to a photodetector to generate first-derivative-like modulation transfer signals through demodulation. Laser frequency stabilization was achieved by using the observed modulation transfer signal as an error signal. Possible error signal offset from feedback electronics was minimized by adjusting the lock point to the averaged level of the off-resonance spectral baseline. Servo control was achieved by the feedback control of the laser current and temperature. For the laser frequency measurement, we conducted a beat frequency measurement between the frequency-locked laser and Er-doped fiber comb [15]. An iodine-stabilized Nd:YAG laser [16] was used as an optical frequency reference for the Er-doped fiber comb. Further details of the experimental setup and method can be found elsewhere [8,10].

Figure 2 shows the observed hyperfine structures of the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 lines of ¹²⁷I₂. The laser frequency was swept to observe hyperfine structures by gradually changing the laser temperature. The cold-finger temperature of the iodine cell was maintained at −10 °C, which corresponds to an iodine pressure of approximately 1.4 Pa. The optical powers of the pump and probe beams were 1.8 and 0.28 mW, respectively, except for the P(71)46-0 line, where the probe beam power was 0.15 mW. The diameters of both the beams were approximately 1.7 mm. The hyperfine transitions of the R(84)47-0 and R(59)45-0 lines are shown as the “a” and “b” series, respectively, in the same graph [Figure 2c]. For the R(106)50-0, R(100)49-0, P(82)47-0 and R(84)47-0 lines, whose ground state J″ is even (106, 100, 82, and 84, respectively), 15 hyperfine transitions were observed [Figure 2a,b,d, and “a” series of Figure 2c, respectively]. On the other hand, 21 hyperfine transitions were observed for the P(71)46-0 and R(59)45-0 lines, whose ground state J″ is odd (71 and 59, respectively) [Figure 2e and “b” series of Figure 2c]. The weak components in the spectra of the R(106)50-0, R(100)49-0, and P(82)47-0 lines belonged to nearby rovibrational lines. Several close hyperfine transitions that were not resolved in Figure 2 were resolved on an enlarged scale and could be locked separately: (i) the a₂ transition of the R(100)49-0 line and the nearby transition of another line, (ii) the b₇ and b₈ transitions of the R(59)45-0 line, and (iii) the a₆ and a₇ transitions of the P(82)47-0 line.

The diode laser was stabilized to all 15 or 21 hyperfine transitions of the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0 and P(71)46-0 lines. The absolute frequency of the laser locked to each hyperfine transition was determined by the beat measurement between the iodine-stabilized diode laser and the frequency comb. The measured absolute frequencies of the laser locked to the a₁(b₁) transitions of the six lines are summarized in

Table 1. Measured absolute frequencies of the ¹²⁷I₂ transitions.

Transition	Frequency (kHz)
R(106)50-0:a1	583,069,385,497.5 (5.6)
R(100)49-0:a1	583,071,194,338.3 (5.6)
R(84)47-0:a1	583,092,689,333.5 (5.6)
R(59)45-0:b1	583,093,530,646.8 (5.6)
P(82)47-0:a1	583,128,690,994.0 (5.6)
P(71)46-0:a1	583,132,532,647.7 (5.6)

. The statistical uncertainty of the measurement was estimated to be 0.4 kHz from the repeatability (lock and unlock) of the frequency-stabilized laser. The total systematic uncertainty was evaluated to be 5.6 kHz in our previous studies [8,10], where the largest systematic uncertainty was 5 kHz, owing to cell impurities. By combining the statistical and systematic uncertainties, the uncertainty of the measured absolute frequency was determined to be 5.6 kHz (fractional uncertainty of 9.6 × 10⁻¹²).

In

Table 2. Observed and calculated hyperfine splittings of the even J number transitions, where all values are in kHz, and SD denotes the standard deviation of the fit.

	R(106)50-0		R(100)49-0		R(84)47-0		P(82)47-0
	Obs.	Obs.-Cal.	Obs.	Obs.-Cal.	Obs.	Obs.-Cal.	Obs.	Obs.-Cal.
a1	0.0	−0.6	0.0	−0.3	0.0	0.1	0.0	−0.3
a2	106,679.4	10.6	133,636.6 *	20.1	180,615.0	4.4	186,005.2	2.0
a3	241,694.6	−11.3	248,832.0	−6.9	261,646.6	−4.9	263,087.9	−3.6
a4	287,194.3	−2.8	307,368.9	4.6	303,297.8	3.7	301,900.2	2.8
a5	321,834.8	10.3	315,171.8	6.2	342,167.7	−2.0	346,140.8	−1.9
a6	335,920.0	−9.0	349,683.2	−3.8	373,765.7	−3.1	376,498.3 *	2.1
a7	455,458.3	−11.0	428,980.4	−4.9	383,039.2	−5.0	377,690.8 *	−14.7
a8	508,736.3	12.3	495,666.6	6.5	472,932.5	4.5	470,257.7	2.4
a9	556,748.7	3.2	537,316.3	2.4	504,020.2	3.2	500,110.5	−1.8
a10	563,631.1	0.2	564,090.1	−1.9	564,983.0	0.0	565,021.9	0.8
a11	615,902.0	0.1	629,677.7	3.8	653,574.1	0.8	656,264.3	0.3
a12	658,122.7	−3.6	665,218.9	−3.3	677,414.0	−1.6	678,746.6	−0.2
a13	750,756.8	1.6	744,818.7	−1.5	734,877.9	0.3	733,643.8	1.1
a14	794,627.6	−0.4	781,947.8	−0.9	760,263.5	−1.0	757,680.9	−2.2
a15	846,558.6	0.5	847,196.5	0.0	848,449.5	0.6	848,507.5	0.5
SD		8.6		5.0		3.6		2.4

* Values excluded from the fit.

and

Table 3. Observed and calculated hyperfine splittings of the odd J number transitions, where all values are in kHz, and SD denotes the standard deviation of the fit.

	R(59)45-0			P(71)46-0
	Obs.	Obs.-Cal.		Obs.	Obs.-Cal.
b1	0.0	3.6	a1	0.0	4.0
b2	83,603.1	1.8	a2	101,327.1	0.6
b3	163,631.9	−1.5	a3	199,012.9	−3.6
b4	279,747.0	−1.0	a4	286,598.2	−0.1
b5	357,652.8	−2.6	a5	370,322.1	−3.2
b6	375,380.5	1.8	a6	397,768.6	2.4
b7	449,748.8 *	−0.0	a7	460,292.4	−1.4
b8	452,019.3 *	−2.9	a8	478,039.8	−0.1
b9	478,373.9	−3.4	a9	488,201.7	−3.8
b10	536,505.4	0.4	a10	561,763.0	2.6
b11	558,578.1	−0.1	a11	586,521.9	2.0
b12	586,575.4	−1.2	a12	595,357.3	−0.5
b13	649,336.5	−1.6	a13	666,749.0	−0.6
b14	714,116.2	−1.0	a14	739,068.0	−0.2
b15	735,632.0	−2.2	a15	749,684.8	−1.1
b16	769,617.0	−0.1	a16	784,372.6	−0.2
b17	810,264.1	1.9	a17	830,673.5	2.0
b18	842,749.7	1.1	a18	863,660.5	1.5
b19	908,277.9	0.9	a19	923,297.9	−0.8
b20	930,226.5	1.1	a20	947,820.3	0.3
b21	955,688.4	2.0	a21	975,243.0	0.1
SD		2.1			2.2

* Values excluded from the fit.

, the “Obs.” columns represent the measured values for the hyperfine splittings of the six lines, which were obtained by taking the frequency difference between each hyperfine transition and the a₁(b₁) transition. Because the frequency shift is similar for each hyperfine transition, the measurement uncertainty of the hyperfine splitting interval is not affected by systematic uncertainties, such as optical power and iodine pressure shifts. The measurement uncertainty of the hyperfine splittings was mainly contributed by the repeatability (0.4 kHz) of the stabilized diode laser and was calculated to be 0.6 kHz ($\sqrt{2}\times 0.4$ kHz).

3. Calculation and Discussion

The measured intervals of the hyperfine transitions were fitted to a four-term Hamiltonian [14] to calculate the hyperfine constants of the iodine lines. The four-term Hamiltonian includes the electric quadrupole, spin–rotation, tensor spin–spin, and scalar spin–spin interactions, where eQq, C, d, and δ are the respective hyperfine constants corresponding to these interactions [14]. In the present calculation, a nonlinear least-squares fit was performed using the ROOT analysis libraries of CERN [17]. The detailed procedure and parameters of the fitting are described elsewhere [18,19]. The hyperfine splitting calculated from the fit was compared with the measured hyperfine splitting. The differences between the measurement and calculation are listed in the columns “Obs.-Cal.” in Table 2 and Table 3. The measured frequencies of the a₂ transition of the R(100)49-0 line, the b₇ and b₈ transitions of the R(59)45-0 line, and the a₆ and a₇ transitions of the P(82)47-0 line were excluded from the fitting because they were too close to each other or to other hyperfine transitions. The residual slope on the error signal from adjacent transitions will introduce an offset in the signal and hence shift the line center when the lock point is set to the averaged level of the off-resonance spectral baseline. The standard deviation of the theoretical fit was approximately 2 or 3 kHz, except for the R(106)50-0, R(100)49-0 lines. The larger standard deviation of the fit for the R(106)50-0, R(100)49-0 lines (8.6 and 5.0 kHz, respectively) is caused by overlapping with other relatively weak lines, as shown in Figure 2a,b. Through the theoretical fit, hyperfine constants ΔeQq, ΔC, Δd, and Δδ, which are the differences in the hyperfine constants between the upper and lower states, were obtained. The calculated hyperfine constants of the six iodine lines are listed in

Table 4. Hyperfine constants obtained from fitting.

Line	ΔeQq (MHz)	ΔC (kHz)	Δd (kHz)	Δδ (kHz)
R(106)50-0	1886.649 (17)	398.308 (10)	−221.07 (56)	55.12 (45)
R(100)49-0	1887.605 (9)	355.587 (7)	−199.36 (43)	38.10 (45)
R(84)47-0	1889.559 (8)	284.410 (5)	−158.50 (23)	15.97 (21)
R(59)45-0	1891.696 (3)	228.863 (3)	−126.39 (7)	3.80 (5)
P(82)47-0	1889.654 (4)	281.774 (4)	−156.49 (13)	15.16 (13)
P(71)46-0	1890.699 (3)	252.942 (2)	−140.33 (12)	8.56 (9)

.

The uncertainties in the values for the main hyperfine constant, ΔeQq, were <10 kHz, except for the R(106)50-0 line. The slightly larger uncertainty of ΔeQq (17 kHz) of the R(106)50-0 line obtained from fitting is due to slightly larger measurement uncertainties caused by the overlapping with other lines. Furthermore, the intensity of the R(106)50-0 line was the lowest among the observed lines. Small uncertainties were also observed for ΔC, Δd, and Δδ. Accurate hyperfine constants were used to reproduce the hyperfine spectra of iodine. Therefore, formulae for predicting hyperfine constants are essential for spectroscopy [20]. In our previous work, we derived formulae to express the rotational dependence of the ground state eQq″ (v″ = 0) [21] and excited states eQq′ (v′ = 32 and 44) [10,19]. The hyperfine constants obtained in this study can be used to improve our understanding of the rotational dependence of the excited-state hyperfine constants for v′ = 45, 46, 47, 49, and 50.

We observed 97 hyperfine transitions in six lines with an uncertainty of 5.6 kHz over a range greater than 64 GHz. By combining the absolute frequencies presented in Table 1 and the hyperfine splittings in Table 2 and Table 3, we can determine the frequencies of all the hyperfine transitions, except for the unresolved and excluded transitions. Such a grid of iodine reference lines was already investigated in the 571–596 nm wavelength region, with an uncertainty of approximately 2 MHz in an early stage of Doppler-free spectroscopy [22]. However, the present study has achieved a measurement uncertainty approximately 400 times smaller than that in Ref. [22]. Because our iodine-stabilized laser outputs at a fundamental wavelength of 1542 nm, these transitions can serve as new optical frequency references for telecommunications and other applications. As indicated in Figure 1, the acetylene optical frequency standard next to the P(16) line of ¹³C₂H₂ is the P(27) line of ¹²C₂H₂ [9]. The transitions observed in this study provide new candidates for frequency standards at telecom wavelengths to fill the gap in existing CIPM-recommended standards. In particular, when an iodine-stabilized diode laser is used as a frequency reference for an optical frequency comb, the variation in its laser frequency is useful in finding a suitable beat frequency for frequency locking. An iodine-stabilized diode laser at 1542 nm [7] was used as the optical frequency reference in the astrocomb [23].

4. Conclusions

In conclusion, we measured the absolute frequency and studied the hyperfine structure of the R(106)50-0, R(100)49-0, R(84)47-0, R(59)45-0, P(82)47-0, and P(71)46-0 lines of molecular iodine at 514 nm using high-resolution spectroscopy and a narrow-linewidth diode laser. The hyperfine splitting of each line was fitted to a four-term Hamiltonian with an uncertainty of several kilohertz to obtain accurate hyperfine constants for the line. The measurement of absolute frequencies and hyperfine structures of these lines are valuable for practical applications, such as telecommunication and optical frequency combs.