United Time-Frequency Spectroscopy for Dynamics and Global Structure

Marian, Adela; Stowe, Matthew C.; Lawall, John; Felinto, D.; Ye, Jun

doi:10.1126/science.1105660

Cited by 265 publications

(197 citation statements)

References 27 publications

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“…In addition to controlling nuclear dynamics, a femtosecond laser can be employed for high-resolution spectroscopy in ultracold systems by utilizing it as a frequency comb [21]. These two limits have recently been combined in a spectroscopic study with coherent pulse accumulation [22]. The appeal of such an approach lies in the fact that with a femtosecond frequency comb it is possible to continuously switch between the two limits, selecting the desired time and frequency resolution.…”

Section: Introductionmentioning

confidence: 99%

Short-pulse photoassociation in rubidium below theD1line

2006

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Photoassociation of two ultracold rubidium atoms and the subsequent formation of stable molecules in the singlet ground and lowest triplet states is investigated theoretically. The method employs laser pulses inducing transitions via excited states correlated to the 5S + 5P 1/2 asymptote. Weakly bound molecules in the singlet ground or lowest triplet state can be created by a single pulse while the formation of more deeply bound molecules requires a two-color pump-dump scenario. More deeply bound molecules in the singlet ground or lowest triplet state can be produced only if efficient mechanisms for both pump and dump steps exist. While long-range 1/R 3 -potentials allow for efficient photoassociation, stabilization is facilitated by the resonant spin-orbit coupling of the 0 + u states. Molecules in the singlet ground state bound by a few wavenumbers can thus be formed. This provides a promising first step toward ground state molecules which are ultracold in both translational and vibrational degrees of freedom.

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Section: Introductionmentioning

confidence: 99%

Short-pulse photoassociation in rubidium below theD1line

2006

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“…Obviously, larger differences between pulse propagations with symmetric and asymmetric detunings are obtained for energies that do not satisfy the one-photon resonance condition [9], since the twophoton Raman resonance is always fulfilled for symmetric detunings. There is one exception, when a similar behavior of the pulse propagation leading to EIT is obtained for asymmetric detunings that do not correspond to one-photon resonance, δ p = −δ c = (2 m p + 1) ω r /2, because the twophoton Raman detuning is again a multiple of the repetition angular frequency and therefore the twophoton resonance condition is satisfied, as shows, in Fig.…”

Section: Propagation Of Probe and Coupling Laser Pulsementioning

confidence: 99%

“…By using a comb laser, which means an ultrafast laser pulse train with a high repetition rate, one can carry out the ultrahigh resolution spectroscopy. Recently it has been shown that the accumulation ef-fects of coherence by a laser pulse train play an important role for coherent control of atomic or molecular systems [9,10]. The use of a chirped laser pulse train is another way for coherent control of population transfer [11].…”

Section: Introductionmentioning

confidence: 99%

Propagation of two short laser pulse trains in a Λ-type three-level medium under conditions of electromagnetically induced transparency

Buică¹,

Nakajima²

2014

Optics Communications

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We investigate the dynamics of a pair of short laser pulse trains propagating in a medium consisting of three-level Λ-type atoms by numerically solving the Maxwell-Schrödinger equations for atoms and fields. By performing propagation calculations with different parameters, under conditions of electromagnetically induced transparency, we compare the propagation dynamics by a single pair of probe and coupling laser pulses and by probe and coupling laser pulse trains. We discuss the influence of the coupling pulse area, number of pulses, and detunings on the probe laser propagation and realization of electromagnetically induced transparency conditions, as well on the formation of a dark state.

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“…For example, individual comb components can be tuned to scan over the frequency gap. [16][17][18][19][20][21] Other methods include spatially separating the comb lines using gratings, 21 Fourier transform spectroscopy of a single OFC 22 and dual-mode spectroscopy using two OFCs. 23,24 Nevertheless, few efforts have been made to decrease the comb spacing to improve the spectral resolution.…”

Section: Introductionmentioning

confidence: 99%

A digitally generated ultrafine optical frequency comb for spectral measurements with 0.01-pm resolution and 0.7-µs response time

Bao

et al. 2015

Light Sci Appl

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Optical spectral measurements are crucial for optical sensors and many other applications, but the prevailing methods, such as optical spectrum analysis and tunable laser spectroscopy, often have to make compromises among resolution, speed, and accuracy. Optical frequency combs are widely used for metrology of discrete atomic and molecular spectral lines. However, they are usually generated by optical methods and have large comb spacing, which limits the resolution for direct sampling of continuous spectra. To overcome these problems, this paper presents an original method to digitally generate an ultrafine optical frequency comb (UFOFC) as the frequency ruler for spectral measurements. Each comb line provides one sampling point, and the full spectrum can be captured at the same time using coherent detection. For an experimental demonstration, we adopted the inverse fast Fourier transform to generate a UFOFC with a comb spacing of 1.46 MHz over a 10-GHz range and demonstrated its functions using a Mach-Zehnder refractive index sensor. The UFOFC obtains a spectral resolution of 0.01 pm and response time of 0.7 ms; both represent 100-fold improvements over the state of the art and could be further enhanced by several orders of magnitude. The UFOFC presented here could facilitate new label-free sensor applications that require both high resolution and fast speed, such as measuring binding kinetics and single-molecule dynamics.

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United Time-Frequency Spectroscopy for Dynamics and Global Structure

Cited by 265 publications

References 27 publications

Short-pulse photoassociation in rubidium below theD1line

Short-pulse photoassociation in rubidium below theD1line

Propagation of two short laser pulse trains in a Λ-type three-level medium under conditions of electromagnetically induced transparency

A digitally generated ultrafine optical frequency comb for spectral measurements with 0.01-pm resolution and 0.7-µs response time

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