Spin-exchange relaxation of naturally abundant Rb in a K–Rb–<sup>21</sup>Ne self-compensated atomic comagnetometer

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Lu Yan, Zhai Yueyang, Zhang Yong, Fan Wenfeng, Xing Li, Quan Wei. Spin-exchange relaxation of naturally abundant Rb in a K–Rb–²¹Ne self-compensated atomic comagnetometer. Chinese Physics B, 2020, 29(4): 043204 Copy to clipboard

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Spin-exchange relaxation of naturally abundant Rb in a K–Rb–²¹Ne self-compensated atomic comagnetometer

Lu Yan¹, Zhai Yueyang^{2, 3, 4}, Zhang Yong¹, Fan Wenfeng¹, Xing Li¹, Quan Wei^{2, 3, 4, †}

1School of Instrumentation Science and Opto-electronics Engineering, Beihang University, Beijing 100191, China

2Research Institute of Frontier Science, Beihang University, Beijing 100191, China

3Beijing Academy of Quantum Information Sciences, Beijing 100191, China

4Beijing Advanced Innovation Center for Big Data-Based Precision Medicine, Beihang University, Beijing 100191, China

† Corresponding author. E-mail: quanwei@buaa.edu.cn

Project supported by the National Key R&D Program of China (Grant Nos. 2016YFB0501600 and 2017YFB0503100), the National Natural Science Foundation of China (Grant Nos. 61773043, 61673041, 61721091, and 61703025), and the National Science Fund for Distinguished Young Scholars of China (Grant No. 61925301).

Abstract

The total effective spin-exchange relaxation of naturally abundant Rb in a K–Rb–²¹Ne comagnetometer is analyzed, and the results show that the coexistence of ⁸⁷Rb and ⁸⁵Rb isotopes in the same volume can lead to a large extra spin-exchange broadening compared to pure ⁸⁷Rb. This broadening mainly comes from the contribution of the equivalent reduction in the Rb spin-exchange rate. On this basis, an approximate relaxation model is proposed and experimentally demonstrated to be more accurate than that from a previous work. This study also provides a method for determining the properties of alkali-metal vapor cells.

PACS: ;32.10.Dk;;32.10.Fn;;32.80.Xx;

Keyword:;comagnetometer;;naturally abundant Rb;;spin-exchange relaxation;;spin polarization;

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1. Introduction

The self-compensated atomic comagnetometer first introduced in Ref. [1] uses the unique coupling dynamics of alkali-metal and noble-gas spin ensembles to cancel the external random magnetic field and maintain a high sensitivity to other types of interactions. For example, it has been used in tests of Lorentz and CPT symmetries (the CPT symmetry is a discrete symmetry under charge conjugation C, parity inversion P, and time reversal T)^[2,3] and spin-dependent forces.^[4–6] Furthermore, this comagnetometer can be exploited as a high-precision gyroscope for rotation sensing.^[7–9] For these applications, the fundamental limit on the comagnetometer sensitivity is essential, which can be optimized by suppressing the total relaxation rate of the alkali-metal atoms.^[7] Thus, research on the various spin relaxations, especially the relaxation caused by spin-exchange (SE) collisions between the alkali-metal atoms in comagnetometers that use relatively heavy noble-gas atoms, such as ²¹Ne or ¹²⁹Xe, is particularly important. In such cases, the classical dipolar field from alkali-metal electron magnetization can be considerably enhanced by the Fermi contact interaction between alkali metal and noble gas pairs, which result in large SE relaxation rates.^[8,10]

The relaxations of various mechanisms are similar for alkali-metal atoms with different nuclear spins I, except for that caused by the effect of SE collisions. For alkali-metal atoms with different I, the different effects of SE collisions are mainly reflected in the different precession properties,^[11] which further affect their polarizations and SE relaxations. Recently, many studies on the self-compensated atomic comagnetometer using naturally abundant Rb (72.2% ⁸⁵Rb with I = 5/2 and 27.8% ⁸⁷Rb with I = 3/2) as a spin source^[12–15] and studies using ⁸⁵Rb and ⁸⁷Rb isotopes in the same volume as the working material for other applications, such as the anomalous long-range spin-mass couplings of the proton^[16] and the magnetic resonance affected by the SE of two Rb isotopes,^[17] have been performed. However, no detailed studies on SE relaxation considering the effect of two Rb isotopes coexisting in the same volume have been presented.

In this work, based on a K–Rb–²¹Ne comagnetometer, the pumping process of naturally abundant Rb considering the different effects of SE collisions of each individual isotope on their precession properties is derived, and the result shows that the two isotopes can achieve the same equilibrium spin polarization, although different amounts of time are required. Then, the total effective SE relaxation of naturally abundant Rb is analyzed, and the result shows that the coexistence of ⁸⁷Rb and ⁸⁵Rb isotopes in the same volume can lead to a large extra SE broadening compared to the case of using pure ⁸⁷Rb isotope, which is mainly attributed to the decrease in the effective SE rate of Rb atoms. Based on this analysis, an approximation model is proposed, in which the total effective SE relaxation rate of naturally abundant Rb is assumed to be equal to that of the contained ⁸⁷Rb isotope. Finally, by comparison with experimental results, this model is proven to be more accurate than the model used in a previous study,^[8] in which all naturally abundant Rb atoms were treated as ⁸⁵Rb atoms.

2. Theoretical analysis

2.1. Operation principle

In a self-compensated atomic comagnetometer, to suppress the relaxation due to SE collisions between alkali-metal atoms, a high-density alkali-metal vapor is required,^[11] while for the case of single alkali-metal species, this vapor also results in an optically thick medium, in which case the strong absorption of the pump light produces a significant polarization inhomogeneity in the cell and imposes a limit on the optical pumping efficiency.^[18] In this study, the K–Rb hybrid pumping technique^[2,18] is utilized in a K–Rb–²¹Ne comagnetometer to overcome this difficulty. The low-density K atoms, which are optically thin, are first polarized in the z-direction (see Fig. 1) by a circularly polarized pump light. Then, through SE interactions, the high-density Rb atoms are pumped by K atoms, and the ²¹Ne atoms are hyperpolarized by Rb atoms.^[2] After a period of time, K, Rb, and ²¹Ne reach their respective polarization equilibria , , and Pⁿ. Because the classical dipolar fields from the alkali-metal electron and noble-gas nuclear magnetizations are enhanced by the Fermi contact hyperfine interactions between K–²¹Ne and Rb–²¹Ne, the corresponding effective magnetic fields are , , and Bⁿ = λ Mⁿ Pⁿ, respectively^[7] (, , and Mⁿ are the magnetizations corresponding to full spin polarizations). In a spherical cell, λ = 8πκ₀/3, where κ₀ is the enhancement factor. For K–²¹Ne and Rb–²¹Ne pairs, the values of κ₀ are approximately 31 and 36, respectively.^[20] The density ratio of K to Rb is typically on the order of 10⁻². In addition, the K and Rb atoms are in spin-temperature equilibrium and have the same polarization because the SE rate between K and Rb is extremely large (exceeding 10⁶ s⁻¹ at typical densities).^[21] Then, the effective magnetic field experienced by ²¹Ne atoms is two orders of magnitude smaller than . The alkali-metal and noble-gas spin ensembles are coupled through one species precessing in the effective magnetic field of the other. Therefore, the coupling between ²¹Ne atoms and alkali-metal atoms is dominated by the Rb–²¹Ne pair, and the coupling between K and ²¹Ne can be safely ignored. Furthermore, in a K–Rb–²¹Ne comagnetometer, only Rb atoms are detected by the probe light used to monitor the change in the ²¹Ne nuclear magnetization and provide the output signal, while K atoms are not detected and are mainly responsible for the effective pumping. In conclusion, the K–Rb–²¹Ne comagnetometer can be simply represented by the Rb–²¹Ne comagnetometer.^[2,21]

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Fig. 1. Intuitive model of the operation principle: (a) Rb and ²¹Ne achieve polarization equilibrium, then the comagnetometer is set to the self-compensated state with B_z = −B2^c = −(Bⁿ + B^e); (b) when there is a rotation rate input Ω_y, the Rb electron spins are quickly repolarized, while the ²¹Ne nuclear spins remain oriented with respect to an inertial frame; (c) under the torque of magnetic field B_z on ²¹Ne nuclear spins, Pⁿ and, accordingly, Bⁿ rotate around the z-axis, resulting in a y-component of the nuclear magnetic field

; (d) under the torque of magnetic field

on Rb electron spins, P^e rotates and projects onto the x-axis. Then, the x-component

is detected by the linearly polarized probe light.

To visually describe the operation principle, an intuitive model is shown in Fig. 1. Here we take rotation sensing as an example. Figure 1(a) shows the equilibrium polarizations P^e and Pⁿ and the corresponding effective magnetic fields B^e and Bⁿ for Rb and ²¹Ne spin ensembles, respectively. In general, the comagnetometer works in the self-compensated state as follows:^[1] , where B_z is the applied magnetic field in the z-direction, and B^c is the compensation point. The comagnetometer can use the unique coupling dynamics of alkali-metal and noble-gas spin ensembles to suppress external magnetic field disturbance in this state.^[1] Thus, this is the operating state of the comagnetometer. If there is a rotation rate input Ω_y, as shown in Fig. 1(b), then the Rb electron spins will be quickly repolarized, while the ²¹Ne nuclear spins remain oriented with respect to an inertial frame.^[19] Under the torque of magnetic field B_z on ²¹Ne nuclear spins, as shown in Fig. 1(c), Pⁿ and, accordingly, Bⁿ rotate around the z-axis, resulting in a y-component of the nuclear magnetic field , which is experienced by Rb atoms. In Fig. 1(d), under the torque of magnetic field on Rb electron spins, P^e rotates and projects onto the x-axis. In this way, Rb atomic spins can sensitively detect , i.e., the x-component of Rb polarization changes with , which generates a linear correlation between and Ω_y,^[8]

After a linearly polarized probe beam passes through the Rb vapor cell, the polarization plane of the probe beam rotates to an angle^[22]

which is proportional to both the Rb density n^e and the polarization component

. The probe light is modulated by a photoelastic modulator (PEM), the photoelectric conversion signal of the photodetector (PD) is demodulated by a lock-in amplifier, and the first harmonic is recorded as the ultimate output signal^[23]

which is proportional to the optical rotation angle θ. The output signal is then linearly correlated with the input rotation, and the rotation can be measured.

2.2. Equilibrium spin polarization

The spin evolutions of the coupled Rb and ²¹Ne spin ensembles in a K–Rb–²¹Ne comagnetometer can be described by a set of Bloch equations.^[6,24] Without any field or rotation input, the Bloch equations in the z-direction are given by

Here R_p is the K–Rb hybrid optical pumping rate,

is the SE rate from Rb to ²¹Ne atoms, and

and

are the longitudinal relaxation times of the Rb electron spin and the ²¹Ne nuclear spin (excluding contributions from R_p and

), respectively.

is the nuclear slowing-down factor that depends on the nuclear spin I and the polarization

of Rb, and for the case of fast SE collisions between Rb atoms in this study, it is expressed as^[11]

For an alkali-metal isotope with I = 3/2, the dimensionless gyromagnetic ratio

is given by

and for an alkali-metal isotope with I = 5/2,

Here the subscripts a and b are used to indicate ⁸⁷Rb with I_a = 3/2 and ⁸⁵Rb with I_b = 5/2, respectively.

When using naturally abundant Rb, the different effects of the SE collisions of each individual isotope on their precession properties need to be considered, which is reflected in the fact that they have different . Substituting Eqs. (6), (7), and (8) into Eq. (4), the pumping process of the two isotopes can be described as

Here the pumping rate R_p and the longitudinal relaxation rate

of the ⁸⁷Rb isotope are assumed to be identical to those of the ⁸⁵Rb isotope because they occupy the same volume with nearly the same collisional environment (the

factors for enhancing the relaxation of wall collisions^[25] are different for these isotopes, but this small rate can be neglected for simplicity). Solving Eqs. (9) and (10), the equilibrium spin polarizations of the ⁸⁷Rb and ⁸⁵Rb isotopes are given by

Although the simulation results show that the times required for the two isotopes to reach equilibrium are different, they achieve the same equilibrium spin polarization P^e, which can be used to represent their total equilibrium spin polarization. Additionally, when considering the SE interactions between ⁸⁵Rb and ⁸⁷Rb isotopes, because the SE cross-section between ⁸⁵Rb and ⁸⁷Rb is 1.7 × 10⁻¹⁴ cm²^[26] and the SE rate can reach 10⁵ s⁻¹ at typical densities, the ⁸⁵Rb and ⁸⁷Rb isotopes are in spin-temperature equilibrium and can maintain the same polarization. Solving Eq. (5), the equilibrium spin polarization Pⁿ of ²¹Ne is

Combining the self-compensation state condition and Eq. (12) gives

Here the constant k is determined in this work from the measurement of B^c based on magnetic field zeroing and the measurement of B^e based on the fastest decay of the coupled spin ensembles under the step magnetic field B_y.^[8]

2.3. Spin-exchange relaxation analysis of naturally abundant rubidium

When an SE collision between two atoms occurs, the singlet and triplet states of the dimer formed during the collision have different energies, the singlet and triplet amplitudes evolve at different rates, thus the spin states of the two atoms may change.^[27] The total angular momentum of the colliding pair is conserved after the collision, and each individual atom has a probability of switching hyperfine levels. Because the gyromagnetic ratios in the two ground-state hyperfine levels have opposite signs, the spin precession direction of a single atom switches with every SE collision, which leads to dephasing in the spin precession of the ensemble. For the case of SE collisions of the same species, the SE mechanism contributes to the transverse relaxation without affecting the longitudinal component; in the limit case in which the rate of SE collisions R_se is much larger than the Larmor frequency ω_L = γ^eB, the atoms lock into a net precession at a slower rate ω₀ in the direction of the F = I + 1/2 state (fast SE regime^[11]) because this hyperfine level has a larger statistical weight, and the SE relaxation rate can be expressed as^[28,29]

in the low polarization limit. Here the SE rate R_se is given by

where σ and

are the SE cross-section and the relative velocity between the pairs of alkali-metal atoms, respectively, and the slower rate ω₀ is given by ω₀ = γ^eB/Q(P^e), with γ^e being the gyromagnetic ratio of a bare electron and B the magnetic field experienced by the alkali-metal atoms. The previous experimental study in Ref. [11] showed that for arbitrary Rb polarization at a low magnetic field of less than approximately 100 nT, Eq. (14) still holds. In this work, the magnetic fields experienced by Rb at different pump light intensities range from 4 to 82 nT, and thus, we can use Eq. (14) for theoretical analysis.

In a vapor cell with naturally abundant Rb, SE collisions also occur between different Rb isotopes. The nuclear spins and hyperfine structures of ⁸⁷Rb and ⁸⁵Rb are quite different, and thus, they cannot be treated as one species. SE collisions between different Rb isotopes can shift ⁸⁵Rb to a higher frequency and ⁸⁷Rb to a lower frequency, as indicated in Ref. [16], while this effect was ignored in that work, and only the intraisotope interaction was considered. In this study, we also ignore this effect, not only because it has a minor effect on the atomic precession frequency but also because we infer that it does not significantly affect the coherence of the atomic ensemble of each individual isotope. For SE relaxation under the fast SE regime, coherence of the atomic ensemble is the most essential aspect,^[22] and it cannot be well achieved by different isotopes with such different precession frequencies, as shown in Fig. 2(c). Therefore, the SE relaxation of each isotope will be considered separately in the following analysis.

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Fig. 2. Simulations for comparison of the various parameters associated with the SE relaxation between the ⁸⁷Rb and ⁸⁵Rb isotopes contained in naturally abundant Rb in the same vapor cell. (a) Dimensionless gyromagnetic ratios γ(P^e); (b) slowing-down factors Q(P^e); (c) precession rates ω₀; (d) simulated SE relaxation rates

in a naturally abundant Rb vapor cell obtained using the densities n_a = 27.8% × n^e and n_b = 72.2% × n^e for ⁸⁷Rb and ⁸⁵Rb, respectively, where n^e = 3.831 × 10¹⁴ cm⁻³ is the total Rb vapor density measured during the cell preparation process.

Based on the fact that the two Rb isotopes precess in a common magnetic field equal to −B^e (B_z + Bⁿ = −B^e), various parameters associated with are simulated and compared between the two isotopes. Figures 2(a), 2(b), and 2(c) show the dimensionless gyromagnetic ratios γ(P^e), slowing-down factors Q(P^e), and precession rates ω₀, respectively. These parameters are all different for the two isotopes. Figure 2(d) shows the simulated in a naturally abundant Rb vapor cell obtained using the densities n_a = 27.8% × n^e and n_b = 72.2% × n^e for ⁸⁷Rb and ⁸⁵Rb, respectively, where n^e = 3.831 × 10¹⁴ cm⁻³ is the total Rb vapor density measured during the cell preparation process. Using Eq. (15), the calculated R_se values for the two isotopes with SE cross-section σ = 1.9 × 10⁻¹⁴ cm²^[30,31] and vapor temperature T = 461 K are R_ase = 9.8 × 10⁴ s⁻¹ and R_bse = 2.5 × 10⁵ s⁻¹, respectively.

For the derivation of the total effective of naturally abundant Rb, both the precession rates ω₀ and relaxation rates of the two isotopes should be considered. Similar to the magnetic resonance response in an alkali-metal atomic magnetometer,^[32] when a cosine oscillating magnetic field B_y = B_0y cos (ω t) is applied, the response is given by

Here the linewidth is Δω = 1/T₂ with the transverse relaxation time T₂ corresponding to the contribution from SE relaxation

. Equation (16) includes the sum of two Lorentzian curves centered at frequencies ±ω₀. Because the resonance frequency ω₀ is larger than the linewidth Δω, the counterpropagating response centered at −ω₀ can be approximately ignored^[33] to simplify Eq. (16) to

According to Eqs. (2) and (3), the output signal obeys

. Then, at a certain P^e, using Eq. (17), we have the total resonance absorption signal of naturally abundant Rb,

because the two isotopes both participate in the optical probing process and contribute to the output signal. Here the linewidth due to SE broadening is

, the resonance frequency is ν_i0 = ω_i0/2π, and h is a constant that is irrelevant to our analysis. From the half width at half maximum (HWHM) of Eq. (18), the total effective SE relaxation of naturally abundant Rb can be estimated. In Fig. 3, the theoretical results based on Eq. (18) are shown, where the solid lines are the total effective SE relaxation rates, and the dashed and dashed-dotted lines correspond to the first and second terms in Eq. (18), respectively.

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	Fig. 3. Theoretical results of the SE relaxation rates of naturally abundant Rb at different Rb polarizations. The solid lines are the total effective SE relaxation rates; the dashed and dashed-dotted lines correspond to the first and second terms in Eq. (18), respectively.

We find that the absorption curves are distorted due to the difference in the resonance frequencies ν_a0 and ν_b0, especially when Δν_i is relatively small compared to |ν_a0 − ν_b0|. Figure 3 shows that we can obtain the total effective SE relaxation of naturally abundant Rb from the HWHM of magnetic resonance absorption lines within the polarization range of 20% to 80%, and the result is shown by Δν_total in Fig. 4(a) (black triangles). Here in comparison with the case of using pure ⁸⁷Rb in a K–Rb–²¹Ne comagnetometer, we analyze the effect of the coexistence of the two isotopes ⁸⁷Rb and ⁸⁵Rb in the same volume on the SE broadening of Rb when using naturally abundant Rb. We choose pure ⁸⁷Rb for the comparison because its SE relaxation rate is smaller than that of pure ⁸⁵Rb at arbitrary Rb polarization, as shown by (green triangles) and (purple triangles) in Fig. 4(a), respectively.

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Fig. 4. Theoretical results of SE broadening linewidths of magnetic resonance absorption lines. (a) Δν_total is the linewidth for using naturally abundant Rb,

is the linewidth for the assumption that the difference in the resonance frequencies between the two isotopes is zero, Δν_a is the linewidth for the assumption that the other isotope ⁸⁵Rb does not exist in naturally abundant Rb,

is the linewidth for using pure ⁸⁷Rb, and

is the linewidth for using pure ⁸⁵Rb. (b)

is the extra broadening of naturally abundant Rb compared to the case of pure ⁸⁷Rb,

is the extra broadening of naturally abundant Rb caused by the reduction in the effective Rb SE rate, and

is the extra broadening of naturally abundant Rb caused by the difference in the resonance frequencies of the two isotopes.

In Fig. 4(b), the difference (black diamonds) shows that the linewidth of naturally abundant Rb is considerably broadened compared to the case of using pure ⁸⁷Rb, which can be attributed to the following reasons: (1) The linewidths due to SE broadening of the two isotopes are different. (2) The resonance frequencies of the two isotopes are different. (3) The fast SE regime is only applicable to a single isotope, and the effective Rb density is only the density of a single Rb isotope contained in naturally abundant Rb; thus, the effective SE rate decreases, leading to large SE broadening. Because the difference in the SE relaxation rates between the two Rb isotopes is small, as shown in Fig. 2(d), the influence of the first factor mentioned above is minor, and we mainly consider the influence of the latter two factors.

Figure 4(a) also shows the theoretical results of the total linewidth (red circles) under the assumption that the difference in the resonance frequencies between the two isotopes is zero and the linewidth Δν_a of ⁸⁷Rb (blue squares) under the assumption that the other isotope ⁸⁵Rb does not exist in naturally abundant Rb. The calculated (blue squares) and (red circles) in Fig. 4(b) represent the extra broadenings of naturally abundant Rb caused by the difference in the resonance frequencies of the two isotopes and by the reduction in the effective Rb SE rate, respectively. We can see that the large extra broadening of naturally abundant Rb compared to the case of pure ⁸⁷Rb mainly comes from the contribution of the equivalent reduction in the Rb SE rate, which accounts for approximately 80% of the total extra broadening at a typical Rb polarization of 50%. Therefore, our subsequent work focuses on this dominant factor and ignores the secondary contribution from the different resonance frequencies of the two isotopes, which accounts for approximately 20%.

For further study, we approximate Δν_total in terms of Δν_a, i.e., we assume that the total effective SE relaxation rate of naturally abundant Rb is equal to that of the contained ⁸⁷Rb isotope. Then, we have

which is referred to as the ⁸⁷Rb model in this text. Because only the effect of intraisotope SE collisions is considered, this model corresponds to an equivalent decrease in the Rb vapor density n^e, which decreases the effective SE rate to R_ase = 9.8 × 10⁻⁴ s⁻¹.

This approximation model is obviously more accurate than that in a previous study (see in Fig. 4(a)).^[8] For verification, the most direct method is to compare experimental results of the SE relaxation with the above theoretical results, but no method to directly measure the SE relaxation currently exists. In this work, we first substitute the ⁸⁷Rb model into the expression of the scale factor K, which is related to various relaxations of Rb, and fit the experimental results of the B^c ∼ K relationship; then, we calculate the total Rb relaxation rates using the obtained fitting parameters. Finally, we measure the total Rb relaxation rates using two methods (the traditional zero-field resonance line method and the low frequency B_x modulation method^[8]) and compare the measured results with the calculated results.

2.4. Theoretical formulas

To determine the various parameters in the comagnetometer, several theoretical formulas are indispensable for fitting the experimental data. From Eq. (11), we have

where P is the pump light intensity, and C¹ = R_p/P is the optical pumping coefficient, which is a constant.

The scale factor K of the comagnetometer is expressed as

where K² is the factor that converts

into the output voltage signal S by the PEM detection system, γⁿ is the gyromagnetic ratio of the ²¹Ne nucleus, and

is the total Rb relaxation rate.^[28]

3. Experimental setup and procedure

A schematic of the experimental setup is shown in Fig. 5, which is similar to previous apparatuses.^[12,35] The comagnetometer includes a spherical aluminosilicate glass vapor cell with a diameter of 14 mm that contains a small droplet of K–Rb mixture with naturally abundant Rb, approximately 2000 Torr ²¹Ne gas (70% isotope enriched) and approximately 50 Torr N₂ gas for quenching. An oven composed of an AC electrical heater system pasted on a boron nitride ceramic is utilized to heat the cell. For thermal insulation, the oven is in a closed vacuum environment, achieved by turbo molecular pumps. To attenuate the ambient magnetic field, four layers of μ-metal magnetic field shields and a layer of a ferrite barrel^[36] are utilized around the vacuum wall, and the residual magnetic field is further compensated for by a set of three-axis Helmholtz coils;^[37] thus, the magnetic field noise is suppressed. For cooling of the vacuum wall, a water jacket is utilized, and the temperature of the magnetic field shield is sufficiently reduced. The electron spin of K atoms is polarized along the z-axis by the circularly polarized pump light, which is produced by an external cavity diode laser (ECDL) and amplified by a tapered amplifier (TA). The wavelength of the pump light is tuned to the D1 resonance of K. The Gaussian-shaped pump light beam is expanded by a beam expander (BE), and the relatively uniform light intensity area is set to approximately 14 mm × 14 mm using a rectangular aperture to fully cover the vapor cell. The x-component of the Rb polarization is measured by the linearly polarized probe light along the x-axis generated by a distributed feedback (DFB) laser, with a wavelength that is 0.4 nm from the absorption center of the Rb D1 line. The power densities of the pump light and the probe light are stabilized by an electrically controlled half-wave plate and a noise eater, respectively. A PEM modulates the probe light with a frequency of 50 kHz and an amplitude of 0.08 rad. The photoelectric conversion signal of the PD is demodulated by a lock-in amplifier, and the first harmonic is recorded as the ultimate output signal.^[23]

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	Fig. 5. Experimental setup of the K–Rb–²¹Ne comagnetometer (not to scale). PDA, photodiode amplifier; PD, photodetector; TA, tapered amplifier; GT, Glan–Thompson polarizer; PBS, polarization beam splitter; BE, beam expander; NE, noise eater; PEM, photoelastic modulator.

In this experiment, the temperature of the naturally abundant Rb vapor cell is set to 461 K, and a series of parameters, such as the compensation point B^c, scale factor K and total relaxation rate of Rb atoms, are measured at various pump light intensities. First, the three components of the magnetic field are zeroed before the experiment to achieve the magnetic field self-compensation state, and the compensation field B^c in the z-direction is recorded. Then, the Rb magnetic field B^e is measured, and the relationship is fitted using Eq. (13) to obtain k. Next, the B^c ∼ P relationship is fitted using Eq. (20) to obtain λ M^e and . Finally, the scale factor K and the total relaxation rate are measured using low frequency B_x modulation method, and the B^c ∼ K relationship is fitted using Eq. (21) to obtain C¹ and K². Thus, the theoretical values of the total Rb relaxation rates at various pump light intensities can be calculated using Eq. (22) and compared with the experimental results.

4. Experimental results and discussion

From the fitting of the B^c ∼ B^e and B^c ∼ P relationships, as shown in Figs. 6(a) and 6(b), respectively, k = 0.22, mW/cm², and λ M^e = 107.5 nT are obtained. The derived Rb vapor density (from λ M^e) n^e = 3.876 × 10¹⁴ cm⁻³ agrees well with the value of 3.831 × 10¹⁴ cm⁻³ determined during the filling process of cell preparation. Fitting the relationship between B^c and K, as shown in Fig. 7(a), we have C¹ = 32.77 s⁻¹ · mW⁻¹ · cm² and K² = 26.11 s· V · nT⁻¹. Substituting the above fitting parameters into Eq. (22), we obtain the theoretical values of the total Rb relaxation rates at various compensation points, as shown in Fig. 7(b) (black line), which are generally consistent with the experimental results of both the traditional method (blue triangles) and the low frequency B_x modulation method^[34] (purple diamonds). The Rb polarizations derived from are also shown for reference in Fig. 7(c). Combined with the Rb polarization, we can conclude that the ⁸⁷Rb model is a good approximation in the polarization range of 18%–77% (due to the limitation of the maximum output power of the pump laser in this experiment, the Rb polarization cannot exceed 77%), which corresponds to the applicable range of the theoretical results: 20%–80%. The relatively large deviation between the traditional results and the theoretical values is attributed to the traditional measurement being affected by the magnetic field gradient. Such inaccuracy also exists in the measurement of the scale factor K by the traditional method in a previous study.^[35] For an approximate model of the SE relaxation of naturally abundant Rb, the effective SE rate R_se is the most essential aspect, which is 9.8 × 10⁴ s⁻¹ in the ⁸⁷Rb model. By changing R_se, refitting the B^c ∼ K relationship and recalculating the total Rb relaxation rates, we find that any change in R_se causes a deviation from the experimental result. The red dashed line in Fig. 7(b) is an example with R_se = 3.5 × 10⁵ s⁻¹, corresponding to the approximation in a previous study,^[8] in which all naturally abundant Rb atoms are treated as ⁸⁵Rb atoms (see in Fig. 4(a)). Thus, the ⁸⁷Rb model is proven to be a more accurate approximation.

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	Fig. 6. (a) Fitting result of the B^c ∼ B^e relationship; (b) fitting result of the B^c ∼ P relationship.

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Fig. 7. (a) Fitting result of the B^c ∼ K relationship; (b) comparison between theoretical and experimental results of the total relaxation rate

of naturally abundant Rb: the blue triangles and purple diamonds are the

measured by the traditional method and low frequency B_x modulation method, respectively, and the black line and red dashed line are calculated using the parameters obtained from fitting the B^c ∼ K relationship with the ⁸⁷Rb model and the previous approximation in Ref. [8], respectively; (c) Rb polarization.

The polarization validity range of approximately 20–80% of the theoretical results includes the polarizations of nearly 50%, which we are concerned about. The comagnetometer has the maximum signal at nearly 50% polarization of Rb electrons. As shown in Fig. 7, the scale factor is the largest at the compensation point B^c = 235 nT, where the Rb polarization is 49%. Unlike the atomic magnetometer operating in the spin-exchange-relaxation-free (SERF) regime,^[22] the maximum signal does not necessarily correspond to 50% electron polarization. In an SERF atomic magnetometer, the SE relaxation does not need to be considered, and the scale factor obeys . By solving ∂ K¹/∂ R_p = 0, we can obtain , and thus, we have . In the K–Rb–²¹Ne comagnetometer, the nonzero SE relaxation rate caused by the relatively large Rb magnetic field is not negligible and should be included in the scale factor K¹ as . Because is related to P^e and R_p, the solution at the peak of the K curve is not as simple as above. However, the simulation results under different typical experimental conditions show that the solution is within the range of approximately 40%–60%, which is still safely included in the validity range of the theoretical results.

5. Conclusions

In this study, based on a K–Rb–²¹Ne comagnetometer, we have derived the equilibrium spin polarization of naturally abundant Rb considering the different effects of SE collisions of each individual isotope on their precession properties, and the result shows that although the times required to reach equilibrium for ⁸⁷Rb and ⁸⁵Rb are different, these isotopes can reach the same equilibrium spin polarization. Then, we analyze the total effective SE relaxation of naturally abundant Rb and demonstrate that the coexistence of the ⁸⁷Rb and ⁸⁵Rb isotopes in the same volume can lead to a large extra SE broadening compared to the case of the pure ⁸⁷Rb isotope, for which the decrease in the effective SE rate of Rb atoms accounts for approximately 80% and the difference in the resonance frequency of the two isotopes accounts for approximately 20%. Based on this analysis, we propose an approximation model in which we assume that the total effective SE relaxation rate of naturally abundant Rb is equal to that of the contained ⁸⁷Rb isotope. This model is experimentally proven to be more accurate than the model in a previous study in which all naturally abundant Rb atoms are treated as ⁸⁵Rb atoms.

The large extra SE broadening demonstrated in this work emphasizes the necessity of using pure ⁸⁷Rb for improving the sensitivity of the comagnetometer, although naturally abundant Rb is relatively more accessible. The consistency between the ⁸⁷Rb model and the experimental results indicates the reasonableness of ignoring the minor effect of interisotope SE collisions on the atomic precession frequency for simplicity and considering the SE relaxation of each individual isotope separately in the fast SE regime, which implies that this regime only exists in the single species atomic system. This study is useful for relaxation-related research in which two alkali-metal isotopes coexist in the same volume and provides a method to obtain the properties of the alkali-metal vapor cell, including the spin relaxation rates, spin polarizations and atomic densities.

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