Line shape of amplitude or frequency-modulated spectral profiles including resonator distortions

Martin Suter; Martin Quack

doi:10.1364/AO.54.004417

Applied Optics
Vol. 54,
Issue 14,
pp. 4417-4431
(2015)
•https://doi.org/10.1364/AO.54.004417

Line shape of amplitude or frequency-modulated spectral profiles including resonator distortions

Martin Suter and Martin Quack

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Martin Suter and Martin Quack, "Line shape of amplitude or frequency-modulated spectral profiles including resonator distortions," Appl. Opt. 54, 4417-4431 (2015)

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Abstract

We report experiments and an improved method of analysis for any harmonics of frequency-modulated spectral line shapes allowing for very precise determinations of the resonance frequency of single absorption lines for gigahertz spectroscopy in the gas phase. Resonator perturbations are implemented into the formalism of modulation spectroscopy by means of a full complex transmission function being able to model the asymmetrically distorted absorption line shapes for arbitrary modulation depths, modulation frequencies, and resonator reflectivities. Exact equations of the in-phase and the quadrature modulation signal, taking into account a full resonator transmission function, are simultaneously adjusted to two-channel lock-in measurements performed in the gigahertz regime to obtain the spectral line position. The determination of the absorption line position of the rotational transition $J^{'} = 7 \leftarrow J^{''} = 6$ of ${}^{16}O {}^{12}C {}^{32}S$ in the vibrational ground state is investigated while changing the resonator distortions. The results are subjected to the approach proposed here and compared to standard methods known from the literature.

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Equations (71)

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Spec. Const.	Value
$B_{0} / MHz$	6 081.492 115 0(52)
$D_{0} / kHz$	1.301 427 4(32)
$H_{0} / mHz$	−0.089 38(33)
$ν_{0} / kHz$	85 139 104.04(7)

Parameter	Method A	Method B	Method C
$ν_{fit} / kHz$	85 139 102.32(16)	85 139 106.40(10)	85 139 105.78(7)
$Γ_{L} / kHz$	209.4(9)	209.6(4)	209.6(3)
$Γ_{D} / kHz$	135 ^b	135 ^b	135 ^b
$β / kHz$	47(4)	48.3(15)	48.2(15)
$α_{\max} / {cm}^{- 1}$	$1.4220 (21) \cdot 10^{- 3}$	$1.4224 (9) \cdot 10^{- 3}$	$1.4222 (9) \cdot 10^{- 3}$

Parameter	Method $D_{const; XY}$	Method $D_{var, R; XY}$	Method E
$ν_{fit} / kHz$	85 139 103.77(3)	85 139 105.27(4)	85 139 110.00(20)
$Γ_{L} / kHz$	190.2(3)	190.8(2)	193(1)
$Γ_{D} / kHz$	135 ^b	135 ^b	135 ^b
$β / kHz$	38(1)	40(1)	47(2)
$α_{\max} / {cm}^{- 1}$	0.0014 ^b	0.0014 ^b	–
$φ_{L} / rad$	0.0242(3)	0.0242 ^b	–
$R$	0.096 ^b	0.1056(2)	–
$l_{rel}$	0.49 ^b	0.49 ^b	–

Spec. Const.	Value
$B_{0} / MHz$	6 081.492 115 0(52)
$D_{0} / kHz$	1.301 427 4(32)
$H_{0} / mHz$	−0.089 38(33)
$ν_{0} / kHz$	85 139 104.04(7)

Parameter	Method A	Method B	Method C
$ν_{fit} / kHz$	85 139 102.32(16)	85 139 106.40(10)	85 139 105.78(7)
$Γ_{L} / kHz$	209.4(9)	209.6(4)	209.6(3)
$Γ_{D} / kHz$	135 ^b	135 ^b	135 ^b
$β / kHz$	47(4)	48.3(15)	48.2(15)
$α_{\max} / {cm}^{- 1}$	$1.4220 (21) \cdot 10^{- 3}$	$1.4224 (9) \cdot 10^{- 3}$	$1.4222 (9) \cdot 10^{- 3}$

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Equations (71)

Applied Optics