A simple 2 W continuous-wave laser system for trapping ultracold metastable helium atoms at the 319.8 nm magic wavelength

Rengelink, R. J.; Notermans, Remy; Vassen, W.

doi:10.1007/s00340-016-6395-y

Cited by 18 publications

(19 citation statements)

References 27 publications

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“…1.0(1) × 10 8 Wm −2 using a 1 W ODT beam. This intensity is roughly half of our estimate assuming perfect focusing conditions and beam quality [44]. The constant offset correction to the polarizability is found to be 3.4(5) a 3 0 .…”

Section: Resultsmentioning

confidence: 53%

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Precision spectroscopy of helium in a magic wavelength optical dipole trap

et al. 2018

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Improvements in both theory and frequency metrology of fewelectron systems such as hydrogen and helium have enabled increasingly sensitive tests of quantum electrodynamics (QED), as well as ever more accurate determinations of fundamental constants and the size of the nucleus. At the same time advances in cooling and trapping of neutral atoms have revolutionized the development of increasingly accurate atomic clocks. Here, we combine these fields to reach the highest precision on an optical tranistion in the helium atom to date by employing a Bose-Einstein condensate confined in a magic wavelength optical dipole trap. The measured transition accurately connects the ortho-and parastates of helium and constitutes a stringent test of QED theory. In addition we test polarizability calculations and ultracold scattering properties of the helium atom. Finally, our measurement probes the size of the nucleus at a level exceeding the projected accuracy of muonic helium measurements currently being performed in the context of the proton radius puzzle. 1 2 R.J. RENGELINK ET AL.In the past decades, high-precision spectroscopy measurements in atomic physics scale systems have pushed precision tests of quantum electrodynamics (QED), one of the cornerstones of the standard model of physics, ever further [1, 2] and have led to accurate determinations of fundamental constants [3][4][5][6]. Recently however, measurements of transition frequencies in muonic hydrogen (µH) have revealed a discrepancy of six standard deviations [7, 8] with respect to the accepted CODATA value for the proton charge radius. This discrepancy, which has become known as the "proton radius puzzle", has stimulated strong interest in the field, as its confirmation implies the violation of lepton universality, one of the pillars of the standard model. New experiments in atomic hydrogen [9, 10], and muonic deuterium [11] have only deepened the puzzle, prompting research into other elements such as muonic helium (µ 3,4 He + ) [12]. From these measurements the charge radii of the alpha-particle and the helion (1.68 fm resp. 1.97 fm) are projected to be determined with sub-attometer accuracy, which should be compared to high-precision experiments in electronic helium atoms or ions.QED theory of the helium atom, with two electrons more complicated than hydrogen, has seen impressive improvements in recent years, with QED corrections up to order mα 6 now evaluated [2]. Recent experiments are in good agreement [13][14][15][16][17][18][19][20] and may allow a competitive value for the fine structure constant in the near future [21][22][23][24]. The anticipated evaluation of the next highest order corrections (mα 7 ) [2] would allow the determination of the 4 He nuclear charge radius with an accuracy better than 1%. At present nuclear charge radii can already be determined differentially, i.e. with respect to 4 He, due to cancellation of higher-order terms in the isotope shift. Using this approach the radii of the exotic halo nuclei 6 He and 8 He [25,26], as well as t...

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Section: Resultsmentioning

confidence: 53%

“…The optical and electronic setup for generating the probe and ODT laser light are described in refs. [42] and [44].…”

Section: Setupmentioning

confidence: 99%

Precision spectroscopy of helium in a magic wavelength optical dipole trap

et al. 2018

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“…Our approach, shown in Fig. 1(b), is based on that described in [32], and is similar to that used in [23,33]. Two infra-red seed lasers are amplified and combined using sum frequency generation (SFG) in a periodically-poled stoichiometric lithium tantalate (PPSLT) crystal to produce red light at ∼ 633 nm -639 nm.…”

Section: Laser Construction and Characterizationmentioning

confidence: 99%

“…The conventional approach to generating tunable CW light in the near-UV region of the spectrum has been to frequency-double a dye laser [22,30,31]. Solid-state systems using sumfrequency generation (SFG) have been developed for particular cooling transitions, offering high power and narrow linewidth [23,32,33], but a tuning range of only a few GHz. Recently these techniques have been extended to lasers for Rydberg spectroscopy [23], where the restricted tuning range means that only a narrow range of principal quantum numbers are accessible.…”

Section: Introductionmentioning

confidence: 99%

Tunable cw UV laser with <35 kHz absolute frequency instability for precision spectroscopy of Sr Rydberg states

Bridge¹,

Keegan²,

Bounds³

et al. 2016

Opt. Express

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We present a solid-state laser system that generates over 200 mW of continuous-wave, narrowband light, tunable from 316.3 nm - 317.7 nm and 318.0 nm - 319.3 nm. The laser is based on commercially available fiber amplifiers and optical frequency doubling technology, along with sum frequency generation in a periodically poled stoichiometric lithium tantalate crystal. The laser frequency is stabilized to an atomic-referenced high finesse optical transfer cavity. Using a GPS-referenced optical frequency comb we measure a long term frequency instability of < 35 kHz for timescales between 10(-3) s and 10(3) s. As an application we perform spectroscopy of Sr Rydberg states from n = 37 - 81, demonstrating mode-hop-free scans of 24 GHz. In a cold atomic sample we measure Doppler-limited linewidths of 350 kHz.

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“…However, such systems are large and expensive, and their operation and maintenance are very complex. Newly-developed fiber lasers and amplifiers are more simple and reliable to operate and maintain [13,14]. For years, a number of nonlinear materials have been used to generate the UV, and among them -BaB2O4 (BBO) and LiB3O5 (LBO) are prime choices.…”

Section: Introductionmentioning

confidence: 99%

Development and characterization of a 22 W narrow-linewidth 3186 nm ultraviolet laser

Wang

Bai

et al. 2016

J. Opt. Soc. Am. B

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We demonstrate a high-power narrow-linewidth ultraviolet (UV) laser system at 318.6 nm for direct 6S1/2-nP (n = 70 to 100) Rydberg excitation of cesium atoms. Based on commercial fiber lasers and efficient nonlinear frequency conversion technology, 2.26 W of tunable UV laser power is obtained from cavity-enhanced second harmonic generation following sum-frequency generation of two infrared lasers at 1560.5 nm and 1076.9 nm to 637.2 nm. The maximum doubling efficiency is 57.3%. The typical UV laser power root-mean-square fluctuation is less than 0.87% over 30 minutes, and the continuously tunable range of the UV laser frequency is more than 6 GHz. Its beam quality factors M 2 X and M 2 Y are 1.16 and 1.48, respectively. This high-performance UV laser has significant potential use in quantum optics and cold atom physics.

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A simple 2 W continuous-wave laser system for trapping ultracold metastable helium atoms at the 319.8 nm magic wavelength

Cited by 18 publications

References 27 publications

Precision spectroscopy of helium in a magic wavelength optical dipole trap

Precision spectroscopy of helium in a magic wavelength optical dipole trap

Tunable cw UV laser with <35 kHz absolute frequency instability for precision spectroscopy of Sr Rydberg states

Development and characterization of a 22 W narrow-linewidth 3186 nm ultraviolet laser

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