A surface-patterned chip as a strong source of ultracold atoms for quantum technologies

Nshii, C. C.; Vangeleyn, Matthieu; Cotter, J. P.; Griffin, Paul F.; Hinds, E. A.; Ironside, C. N.; See, P.; Sinclair, Alastair G.; Riis, Erling; Arnold, Aidan S.

doi:10.1038/nnano.2013.47

Cited by 146 publications

(157 citation statements)

References 31 publications

(42 reference statements)

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“…Prior work has shown that 2D + GMOT flux is maximal for laser intensities near 20 mW/cm 2 , while the 3D GMOT atom number saturates near 50 mW/cm 2 [18]. Both are significantly higher than the 11 mW/cm 2 produced by our laser system.…”

Section: Comparisons and Outlookmentioning

confidence: 55%

“…Custom non-directional etched gratings have been fabricated to this standard for the 3D GMOT [18,25,26], albeit with considerable design time and fabrication cost. Such gratings often require e-beam lithography for small (≈ 500 nm) feature sizes.…”

Section: Theory and Designmentioning

confidence: 99%

“…These successes have spurred interest in transitioning cold atom devices from the lab to more demanding environments [9][10][11][12][13][14][15][16][17]. Recently, a three dimensional grating magneto-optical trap (3D GMOT) was demonstrated that satisfies many needs of a deployable system [18][19][20]. Particularly, the GMOT increases optical access while reducing system size, weight, power, and cost compared to conventional techniques.…”

Section: Introductionmentioning

confidence: 99%

“…The 2D GMOT enables faster loading rates and higher atom number in the 3D GMOT by separating the source vapor from the experimental region. The resulting 3D GMOT shows comparable atom number scaling to standard six-beam MOT's [18] and is able to achieve sub-Doppler cooling [21].…”

Section: Introductionmentioning

confidence: 99%

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Two-dimensional grating magneto-optical trap

Imhof

Stuhl²,

Kasch³

et al. 2017

Phys. Rev. A

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We demonstrate a two dimensional grating magneto-optical trap (2D GMOT) with a single input cooling laser beam and a planar diffraction grating using 87 Rb. This configuration increases experimental access when compared with a traditional 2D MOT. As described in the paper, the output flux is several hundred million rubidium atoms/s at a mean velocity of 16.5(9) m/s and a velocity distribution of 4(3) m/s standard deviation. We use the atomic beam from the 2D GMOT to demonstrate loading of a three dimensional grating MOT (3D GMOT) with 2.46(7) × 10 8 atoms. Methods to improve output flux are discussed.

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Section: Comparisons and Outlookmentioning

confidence: 55%

Section: Theory and Designmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Two-dimensional grating magneto-optical trap

Imhof

Stuhl²,

Kasch³

et al. 2017

Phys. Rev. A

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“…Miniaturized pyramid MOTs, however, suffer from low atom capture rates due to the small volume in which the beams overlap 45,46 , significant backscatter making the atoms difficult to detect 47 , and the geometry making transfer of the atoms to magnetic surface traps non-trivial. A recently demonstrated ver- sion of the tetrahedral-MOT using a planar grating as a reflector (which we refer to as the 'G-MOT', see Figure 2) can capture a large number of atoms, has lower backscatter 48 , and can be easily integrated with atom chip structures 49 . Some disadvantages include the effect of the grating on the wavefronts and polarizations of the manipulation beams 50 , and added difficulty in situations which require several widely-spaced wavelengths.…”

Section: The Magneto Optical Trap Systemmentioning

confidence: 99%

Contributed Review: The feasibility of a fully miniaturized magneto-optical trap for portable ultracold quantum technology

Rushton

Aldous

Himsworth

2014

Review of Scientific Instruments

101

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Experiments using laser cooled atoms and ions show real promise for practical applications in quantumenhanced metrology, timing, navigation, and sensing as well as exotic roles in quantum computing, networking and simulation. The heart of many of these experiments has been translated to microfabricated platforms known as atom chips whose construction readily lend themselves to integration with larger systems and future mass production. To truly make the jump from laboratory demonstrations to practical, rugged devices, the complex surrounding infrastructure (including vacuum systems, optics, and lasers) also needs to be miniaturized and integrated. In this paper we explore the feasibility of applying this approach to the Magneto-Optical Trap; incorporating the vacuum system, atom source and optical geometry into a permanently sealed microlitre system capable of maintaining 10 −10 mbar for more than 1000 days of operation with passive pumping alone. We demonstrate such an engineering challenge is achievable using recent advances in semiconductor microfabrication techniques and materials.PACS numbers: 07.07.Df, 37.10.Gh, 07.30.Kf, I. ULTRACOLD QUANTUM TECHNOLOGYSince the first demonstrations of atoms and ions at sub-millikelvin temperatures in the mid-1980s, the field of atomic physics has been revolutionized by laser cooling and trapping as it provides researchers with a method to probe some of the purest and sensitive quantum systems available. This field is still highly productive and recently has put significant emphasis on the practical applications of this technology beyond the laboratory 1,2 . It was evident very early on that ultracold matter would be an indispensable tool in precise timing applications and a recent demonstration 3 has shown extremely low instabilities at the 10 −18 level. The wavelike nature of atoms as they are cooled to lower temperatures can be used to form atomic interferometers that outperform optical counterparts in measurements of accelerated reference frames 4-7 , which are important for inertial guidance systems, but can also provide sensitive measurements of mass, charge and magnetic fields [8][9][10][11] . Greater sensitivity beyond the classical limit is possible via squeezed 12 and entangled states 13-15 , which are also fundamental attributes for quantum computing 16,17 , and long distance quantum networking 18 . Ultracold matter has been used in the emerging field of quantum simulation 19 and is an indispensable tool in determining fundamental constants 20 , testing general relativity 21 and defining measurement standards 22 . Many researchers and industries believe such tools will be a major part of the 'second quantum revolution' in which the more 'exotic' properties of quantum physics are applied for practical applications 23,24 .The field of ultracold matter has reached a matua) m.d.himsworth@soton.ac.uk rity in both experimental methods and theoretical understanding allowing experiments to begin leaving the laboratory 25-27 . These systems are bespoke, rarely take up a ...

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Metasurfaces toward Optical Manipulation Technologies for Quantum Precision Measurement

Xu,

Su,

Chai

et al. 2023

Laser & Photonics Reviews

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Metasurface‐based optical field manipulation has significantly broadened the application range of micro‐optical components and integrated optics, gradually replacing bulky and complicated optical components. With the continuous development of micro and nano processing technology as well as computational analysis technology, metasurfaces have progressively shown their superior application prospects. After demonstrating tremendous results in classical optical applications, their application range has now extended to the field of quantum sensing. Due to their unique properties, such as small planar size, easy integration, flexible performance design, and tunable functionality, they have opened up a series of novel and rich applications for generating, manipulating, controlling, and detecting optical fields. In this paper, the basic principle and implementation of quantum measurement are presented and an overview of the design principles of metasurfaces, along with a summary of the latest advancements and potential applications of these surfaces in optical field modulation techniques for quantum precision measurement. Additionally, a thorough discussion and analysis of the challenges encountered by metasurfaces and their future development prospects is provided. Metasurfaces offer brand‐new opportunities for low‐cost, high‐performance, multifunctional miniaturized quantum sensors and are expected to play a significant role in the development of next‐generation quantum sensors.

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A surface-patterned chip as a strong source of ultracold atoms for quantum technologies

Cited by 146 publications

References 31 publications

Two-dimensional grating magneto-optical trap

Two-dimensional grating magneto-optical trap

Contributed Review: The feasibility of a fully miniaturized magneto-optical trap for portable ultracold quantum technology

Metasurfaces toward Optical Manipulation Technologies for Quantum Precision Measurement

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