About this Dataset

Data Associated With "Zeeman-resolved Autler-Townes Splitting In Rydberg Atoms With A Tunable RF Resonance And A Single Transition Dipole Moment"

Data associated with the publication: "Zeeman-resolved Autler-Townes splitting in Rydberg atoms with a tunable RF resonance and a single transition dipole moment"Applying a magnetic field as a method for tuning the frequency of Autler-Townes splitting for Rydberg electrometry has recently been demonstrated. In the corresponding paper, we provide a theoretical understanding of EIT signals in the presence of a large magnetic field, as well as demonstrate some advantages of this technique over traditional Autler-Townes based electrometry. We show that a strong magnetic field provides a well-defined quantization axis regardless of the optical field polarizations, we demonstrate that by separating the $m_J$ levels of the Rydberg state we can perform an Autler-Townes splitting with a single participating dipole moment, and we demonstrate recovery of signal strength by populating a single $m_J$ level using circularly polarized light.Included in this dataset is the data associated with every plot in the paper, separated by figure number, including:FIgure 2: Measured EIT signals in the presence of a strong(1.85(1) mT) magnetic field either aligned with or orthogonalto the polarization axis. Figure 3: Theoretical EIT signals for Cs in the presence ofa 1.85(1) mT magnetic field for light polarizations alignedto or orthogonal to the magnetic field.Figure 4: Measured Autler-Townes splittings in individual mJlevels via the 58D5/2(mJ = ±5/2) ? 59P3/2(mJ = ±3/2)transitions of Cs in the presence of 2.78(1) mT.Figure 5: Measured Autler-Townes splittings on the Cs58D5/2 ? 59P3/2 transition with and without mJ selectivityfor various RF fields up to 3.08 V/m. Figure 6: EIT in the presence of a large magnetic field using circularly polarized light.EIT signals correspond to voltage traces (collected on an oscilloscope) of a balanced photodiode as laser frequencies are scanned. The x axis is converted from a time series of each voltage to a frequency using a reference cell. The scaling is determined by measuring the difference between the EIT peaks corresponding to the D5/2 and D3/2 Rydberg states, and the zero is generally taken to be the location of the D5/2 EIT peak.
Organization: Department of Commerce
Last updated: 2025-09-30T05:26:42.771555
Tags: autler-townes, electrometry, magnetic-field, quantum-sensing, rydberg, spectroscopy, zeeman

Tables

Fig3a

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig3a

70.33 kB
10,002 rows
16 columns

CREATE TABLE fig3a (
  "mj_5_2_detuning_mhz" DOUBLE  -- MJ = -5/2 Detuning (MHz),
  "mj_5_2_amplitude_v" DOUBLE  -- MJ = -5/2 Amplitude (V),
  "mj_3_2_detuning_mhz" DOUBLE  -- MJ = -3/2 Detuning (MHz),
  "mj_3_2_amplitude_v" DOUBLE  -- MJ = -3/2 Amplitude (V),
  "mj_1_2_detuning_mhz" DOUBLE  -- MJ = -1/2 Detuning (MHz),
  "mj_1_2_amplitude_v" DOUBLE  -- MJ = -1/2 Amplitude (V),
  "mj_1_2_detuning_mhz_fb8dfb" DOUBLE  -- MJ = 1/2 Detuning (MHz),
  "mj_1_2_amplitude_v_687d0a" DOUBLE  -- MJ = 1/2 Amplitude (V),
  "mj_3_2_detuning_mhz_d9ef6b" DOUBLE  -- MJ = 3/2 Detuning (MHz),
  "mj_3_2_amplitude_v_b8b4a6" DOUBLE  -- MJ = 3/2 Amplitude (V),
  "mj_5_2_detuning_mhz_617286" DOUBLE  -- MJ = 5/2 Detuning (MHz),
  "mj_5_2_amplitude_v_92fc5b" DOUBLE  -- MJ = 5/2 Amplitude (V),
  "theoretical_coupling_detuning_mhz" DOUBLE  -- Theoretical Coupling Detuning (MHz),
  "theoretical_eit_signal_v" DOUBLE  -- Theoretical EIT Signal (V),
  "measured_coupling_detuning_mhz" DOUBLE  -- Measured Coupling Detuning (MHz),
  "measured_eit_signal_v" DOUBLE  -- Measured EIT Signal (V)
);

Fig3b

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig3b

71.68 kB
10,002 rows
18 columns

CREATE TABLE fig3b (
  "mj_5_2_detuning_mhz" DOUBLE  -- MJ = -5/2 Detuning (MHz),
  "mj_5_2_amplitude_v" DOUBLE  -- MJ = -5/2 Amplitude (V),
  "mj_3_2_detuning_mhz" DOUBLE  -- MJ = -3/2 Detuning (MHz),
  "mj_3_2_amplitude_v" DOUBLE  -- MJ = -3/2 Amplitude (V),
  "mj_1_2_detuning_mhz" DOUBLE  -- MJ = -1/2 Detuning (MHz),
  "mj_1_2_amplitude_v" DOUBLE  -- MJ = -1/2 Amplitude (V),
  "mj_1_2_detuning_mhz_fb8dfb" DOUBLE  -- MJ = 1/2 Detuning (MHz),
  "mj_1_2_amplitude_v_687d0a" DOUBLE  -- MJ = 1/2 Amplitude (V),
  "mj_3_2_detuning_mhz_d9ef6b" DOUBLE  -- MJ = 3/2 Detuning (MHz),
  "mj_3_2_amplitude_v_b8b4a6" DOUBLE  -- MJ = 3/2 Amplitude (V),
  "mj_5_2_detuning_mhz_617286" DOUBLE  -- MJ = 5/2 Detuning (MHz),
  "mj_5_2_amplitude_v_92fc5b" DOUBLE  -- MJ = 5/2 Amplitude (V),
  "theoretical_coupling_detuning_mhz" DOUBLE  -- Theoretical Coupling Detuning (MHz),
  "theoretical_eit_signal_v" DOUBLE  -- Theoretical EIT Signal (V),
  "measured_coupling_detuning_mhz" DOUBLE  -- Measured Coupling Detuning (MHz),
  "measured_eit_signal_v" DOUBLE  -- Measured EIT Signal (V),
  "mf" DOUBLE,
  "n_mf" DOUBLE  -- N(mF)
);

Fig3d

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig3d

82.56 kB
10,002 rows
18 columns

CREATE TABLE fig3d (
  "mj_5_2_detuning_mhz" DOUBLE  -- MJ = -5/2 Detuning (MHz),
  "mj_5_2_amplitude_v" DOUBLE  -- MJ = -5/2 Amplitude (V),
  "mj_3_2_detuning_mhz" DOUBLE  -- MJ = -3/2 Detuning (MHz),
  "mj_3_2_amplitude_v" DOUBLE  -- MJ = -3/2 Amplitude (V),
  "mj_1_2_detuning_mhz" DOUBLE  -- MJ = -1/2 Detuning (MHz),
  "mj_1_2_amplitude_v" DOUBLE  -- MJ = -1/2 Amplitude (V),
  "mj_1_2_detuning_mhz_fb8dfb" DOUBLE  -- MJ = 1/2 Detuning (MHz),
  "mj_1_2_amplitude_v_687d0a" DOUBLE  -- MJ = 1/2 Amplitude (V),
  "mj_3_2_detuning_mhz_d9ef6b" DOUBLE  -- MJ = 3/2 Detuning (MHz),
  "mj_3_2_amplitude_v_b8b4a6" DOUBLE  -- MJ = 3/2 Amplitude (V),
  "mj_5_2_detuning_mhz_617286" DOUBLE  -- MJ = 5/2 Detuning (MHz),
  "mj_5_2_amplitude_v_92fc5b" DOUBLE  -- MJ = 5/2 Amplitude (V),
  "theoretical_coupling_detuning_mhz" DOUBLE  -- Theoretical Coupling Detuning (MHz),
  "theoretical_eit_signal_v" DOUBLE  -- Theoretical EIT Signal (V),
  "measured_coupling_detuning_mhz" DOUBLE  -- Measured Coupling Detuning (MHz),
  "measured_eit_signal_v" DOUBLE  -- Measured EIT Signal (V),
  "mf" DOUBLE,
  "n_mf" DOUBLE  -- N(mF)
);

Fig4a

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig4a

117.85 kB
10,002 rows
2 columns

CREATE TABLE fig4a (
  "coupler_detuning_mhz" DOUBLE  -- Coupler Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V)
);

Fig4b

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig4b

118.26 kB
10,002 rows
2 columns

CREATE TABLE fig4b (
  "coupler_detuning_mhz" DOUBLE  -- Coupler Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V)
);

Fig4c

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig4c

117.29 kB
10,002 rows
2 columns

CREATE TABLE fig4c (
  "coupler_detuning_mhz" DOUBLE  -- Coupler Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V)
);

Fig5a

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig5a

291.05 kB
10,001 rows
27 columns

CREATE TABLE fig5a (
  "sqrt_p_0_mw_1_2" VARCHAR  -- Sqrt(P) = 0 (mW^1/2),
  "coupling_detuning_mhz" DOUBLE  -- Coupling Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "sqrt_p_0_56_mw_1_2" VARCHAR  -- Sqrt(P) = 0.56 (mW^1/2),
  "coupling_detuning_mhz_1" DOUBLE  -- Coupling Detuning (MHz).1,
  "eit_signal_v_1" DOUBLE  -- EIT Signal (V).1,
  "sqrt_p_1_41_mw_1_2" VARCHAR  -- Sqrt(P) = 1.41 (mW^1/2),
  "coupling_detuning_mhz_2" DOUBLE  -- Coupling Detuning (MHz).2,
  "eit_signal_v_2" DOUBLE  -- EIT Signal (V).2,
  "sqrt_p_2_24_mw_1_2" VARCHAR  -- Sqrt(P) = 2.24 (mW^1/2),
  "coupling_detuning_mhz_3" DOUBLE  -- Coupling Detuning (MHz).3,
  "eit_signal_v_3" DOUBLE  -- EIT Signal (V).3,
  "sqrt_p_2_82_mw_1_2" VARCHAR  -- Sqrt(P) = 2.82 (mW^1/2),
  "coupling_detuning_mhz_4" DOUBLE  -- Coupling Detuning (MHz).4,
  "eit_signal_v_4" DOUBLE  -- EIT Signal (V).4,
  "sqrt_p_3_55_mw_1_2" VARCHAR  -- Sqrt(P) =3.55 (mW^1/2),
  "coupling_detuning_mhz_5" DOUBLE  -- Coupling Detuning (MHz).5,
  "eit_signal_v_5" DOUBLE  -- EIT Signal (V).5,
  "sqrt_p_3_78_mw_1_2" VARCHAR  -- Sqrt(P) =3.78 (mW^1/2),
  "coupling_detuning_mhz_6" DOUBLE  -- Coupling Detuning (MHz).6,
  "eit_signal_v_6" DOUBLE  -- EIT Signal (V).6,
  "sqrt_p_4_86_mw_1_2" VARCHAR  -- Sqrt(P) =4.86 (mW^1/2),
  "coupling_detuning_mhz_7" DOUBLE  -- Coupling Detuning (MHz).7,
  "eit_signal_v_7" DOUBLE  -- EIT Signal (V).7,
  "sqrt_p_6_06_mw_1_2" VARCHAR  -- Sqrt(P) = 6.06 (mW^1/2),
  "coupling_detuning_mhz_8" DOUBLE  -- Coupling Detuning (MHz).8,
  "eit_signal_v_8" DOUBLE  -- EIT Signal (V).8
);

Fig5b

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig5b

36.59 kB
10,001 rows
5 columns

CREATE TABLE fig5b (
  "sqrt_p_6_06_mw_1_2" VARCHAR  -- Sqrt(P) = 6.06 (mW^1/2),
  "coupling_detuning_mhz" DOUBLE  -- Coupling Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "peak_location_1_2_1_2_mhz" DOUBLE  -- Peak Location +- 1/2 -> +-1/2 (MHz),
  "peak_location_3_2_3_2_mhz" DOUBLE  -- Peak Location +- 3/2 -> +-3/2 (MHz)
);

Fig5c

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig5c

286.98 kB
10,001 rows
24 columns

CREATE TABLE fig5c (
  "sqrt_p_0_mw_1_2" VARCHAR  -- Sqrt(P) = 0 (mW^1/2),
  "coupling_detuning_mhz" DOUBLE  -- Coupling Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "sqrt_p_0_40_mw_1_2" VARCHAR  -- Sqrt(P) = 0.40 (mW^1/2),
  "coupling_detuning_mhz_1" DOUBLE  -- Coupling Detuning (MHz).1,
  "eit_signal_v_1" DOUBLE  -- EIT Signal (V).1,
  "sqrt_p_1_12_mw_1_2" VARCHAR  -- Sqrt(P) = 1.12 (mW^1/2),
  "coupling_detuning_mhz_2" DOUBLE  -- Coupling Detuning (MHz).2,
  "eit_signal_v_2" DOUBLE  -- EIT Signal (V).2,
  "sqrt_p_1_78_mw_1_2" VARCHAR  -- Sqrt(P) = 1.78 (mW^1/2),
  "coupling_detuning_mhz_3" DOUBLE  -- Coupling Detuning (MHz).3,
  "eit_signal_v_3" DOUBLE  -- EIT Signal (V).3,
  "sqrt_p_2_82_mw_1_2" VARCHAR  -- Sqrt(P) = 2.82 (mW^1/2),
  "coupling_detuning_mhz_4" DOUBLE  -- Coupling Detuning (MHz).4,
  "eit_signal_v_4" DOUBLE  -- EIT Signal (V).4,
  "sqrt_p_3_78_mw_1_2" VARCHAR  -- Sqrt(P) =3.78 (mW^1/2),
  "coupling_detuning_mhz_5" DOUBLE  -- Coupling Detuning (MHz).5,
  "eit_signal_v_5" DOUBLE  -- EIT Signal (V).5,
  "sqrt_p_4_86_mw_1_2" VARCHAR  -- Sqrt(P) =4.86 (mW^1/2),
  "coupling_detuning_mhz_6" DOUBLE  -- Coupling Detuning (MHz).6,
  "eit_signal_v_6" DOUBLE  -- EIT Signal (V).6,
  "sqrt_p_6_06_mw_1_2" VARCHAR  -- Sqrt(P) = 6.06 (mW^1/2),
  "coupling_detuning_mhz_7" DOUBLE  -- Coupling Detuning (MHz).7,
  "eit_signal_v_7" DOUBLE  -- EIT Signal (V).7
);

Fig5d

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig5d

40.31 kB
10,001 rows
4 columns

CREATE TABLE fig5d (
  "sqrt_p_6_06_mw_1_2" VARCHAR  -- Sqrt(P) = 6.06 (mW^1/2),
  "coupling_detuning_mhz" DOUBLE  -- Coupling Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "peak_location_5_2_3_2_mhz" DOUBLE  -- Peak Location - 5/2 -> -3/2 (MHz)
);

Fig6a

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig6a

46.67 kB
2,501 rows
9 columns

CREATE TABLE fig6a (
  "no_b" VARCHAR,
  "coupling_deutning_mhz" DOUBLE  -- Coupling Deutning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "perp_perp" VARCHAR,
  "coupling_deutning_mhz_1" DOUBLE  -- Coupling Deutning (MHz).1,
  "eit_signal_v_1" DOUBLE  -- EIT Signal (V).1,
  "sigma_sigma" VARCHAR  -- Sigma+ Sigma+,
  "coupling_deutning_mhz_2" DOUBLE  -- Coupling Deutning (MHz).2,
  "eit_signal_v_2" DOUBLE  -- EIT Signal (V).2
);

Fig6b

@usgov.doc_gov_data_associated_with_zeeman_resolved_autler_to_c70b6480.fig6b

55.54 kB
2,501 rows
12 columns

CREATE TABLE fig6b (
  "sigma" VARCHAR  -- Sigma++,
  "coupler_detuning_mhz" DOUBLE  -- Coupler Detuning (MHz),
  "eit_signal_v" DOUBLE  -- EIT Signal (V),
  "sigma_27ad78" VARCHAR  -- Sigma+-,
  "coupler_detuning_mhz_1" DOUBLE  -- Coupler Detuning (MHz).1,
  "eit_signal_v_1" DOUBLE  -- EIT Signal (V).1,
  "sigma_c6488a" VARCHAR  -- Sigma-+,
  "coupler_detuning_mhz_2" DOUBLE  -- Coupler Detuning (MHz).2,
  "eit_signal_v_2" DOUBLE  -- EIT Signal (V).2,
  "sigma_42e9d3" VARCHAR  -- Sigma--,
  "coupler_detuning_mhz_3" DOUBLE  -- Coupler Detuning (MHz).3,
  "eit_signal_v_3" DOUBLE  -- EIT Signal (V).3
);