Tapered optical fibers as tools for probing magneto-optical trap characteristics

Morrissey, Michael; Deasy, Kieran; Wu, Yaqiao; Chakrabarti, Satyajit; Chormaic, Síle Nic

doi:10.1063/1.3117201

Cited by 68 publications

(67 citation statements)

References 34 publications

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“…Evanescent waves in optical waveguides have received great attention recently due to the advantage of optical coupling with systems such as microresonators, [1][2][3] cold atoms, [4][5][6][7][8] their use in optical sorting, 9,10 their ability to form microcavities themselves, [11][12][13] and to support cavities. [14][15][16] Of the many available waveguide types, the tapered optical fiber -otherwise known as the optical micro-or nanofiber (MNF) -is an important device in these research fields because it is relatively easy to fabricate, produces a strong evanescent field, and can be directly integrated into existing fiber optic systems.…”

Section: Introductionmentioning

confidence: 99%

Contributed Review: Optical micro- and nanofiber pulling rig

Ward¹,

Maimaiti

Le³

et al. 2014

Review of Scientific Instruments

122

101

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We review the method of producing adiabatic optical micro-and nanofibers using a hydrogen/oxygen flame brushing technique. The flame is scanned along the fiber, which is being simultaneously stretched by two translation stages. The tapered fiber fabrication is reproducible and yields highly adiabatic tapers with either exponential or linear profiles. Details regarding the setup of the flame brushing rig and the various parameters used are presented. Information available from the literature is compiled and further details that are necessary to have a functioning pulling rig are included. This should enable the reader to fabricate various taper profiles, while achieving adiabatic transmission of ~ 99% for fundamental mode propagation. Using this rig, transmissions ranging from 85-95% for higher order modes in an optical nanofiber have been obtained.

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Section: Introductionmentioning

confidence: 99%

Contributed Review: Optical micro- and nanofiber pulling rig

Ward¹,

Maimaiti

Le³

et al. 2014

Review of Scientific Instruments

122

101

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“…(2012), low loss, and promise of improved atom-light interaction Alton et al (2011);Le Kien et al (2005b); ; Goban et al (2012); Wuttke et al (2012) have led to increased interest in the physics community. Optical micro-or nanofibers are used for sensing and detection Knight et al (1997); Nayak et al (2007), and coupling light to resonators Knight et al (1997); Kakarantzas et al (2002); Spillane et al (2003); Louyer et al (2005); Morrissey et al (2009);Fujiwara et al (2012), NV centers Schröder et al (2012), or photonic crystals Thompson et al (2013); Sadgrove et al (2013).…”

Section: Optical Nanofibers As Enablers Of High Cooperativity and Optmentioning

confidence: 99%

“…Morrissey et al (2009) uses the nanofiber to measure several characteristics of a magneto-optical trap (MOT): cloud shape, cloud size, atom loading rate, and atom number. In another experiment, Russell et al (2012) measure sub-Doppler temperatures of an atom cloud by dithering the magnetic trapping field to extract the trap frequency.…”

Section: Atom-cloud Characteristicsmentioning

confidence: 99%

Optical Nanofibers

Solano

Grover

Hoffman

et al. 2017

Advances in Atomic, Molecular, and Optical Physics

100

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The development of optical nanofibers (ONF) and the study and control of their optical properties when coupling atoms to their electromagnetic modes has opened new possibilities for their use in quantum optics and quantum information science. These ONFs offer tight optical mode confinement (less than the wavelength of light) and diffraction-free propagation. The small cross section of the transverse field allows probing of linear and non-linear spectroscopic features of atoms with exquisitely low power. The cooperativity -the figure of merit in many quantum optics and quantum information systems -tends to be large even for a single atom in the mode of an ONF, as it is proportional to the ratio of the atomic cross section to the electromagnetic mode cross section. ONFs offer a natural bus for information and for inter-atomic coupling through the tightly-confined modes, which opens the possibility of one-dimensional many-body physics and interesting quantum interconnection applications. The presence of the ONF modifies the vacuum field, affecting the spontaneous emission rates of atoms in its vicinity. The high gradients in the radial intensity naturally provide the potential for trapping atoms around the ONF, allowing the creation of onedimensional arrays of atoms. The same radial gradient in the transverse direction of the field is responsible for the existence of a large longitudinal component that introduces the possibility of spin-orbit coupling of the light and the atom, enabling the exploration of chiral quantum optics.

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“…The TNF is mounted inside an ultra-high vacuum MOT chamber using electrical feedthroughs attached to a vacuum flange. Tapered region of the fibre is held in an U-shaped mount, ensuring that the thinnest section of the fibre is centred in MOT chamber 31 . Other than anti-Helmholtz coils, pairs of smaller coils are also used to spatially overlap the cold cloud with the waist region of TNF.…”

Section: Experimental Arrangementmentioning

confidence: 99%

“…A basic MOT set-up 29,30 was used to create a cold cloud of 85 Rb atoms near the waist region of TNF 31 . Three pairs of mutually perpendicular, opposite circularly polarized and retroreflecting laser beams, all intersecting at a point produce optical force necessary for cooling the atoms.…”

Section: Experimental Arrangementmentioning

confidence: 99%

Manipulating Cold Atoms with Optical Fibres

Chakrabarti¹

2017

Current Science

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In this article we present some demonstrations of atom-photon interactions at low photon level using optical fibres. We report an experiment on the interaction between cold atoms produced in a magneto optical trap and tapered optical nanofibre and discuss some applications of the same. We then expound our experimental plan to study nonlinear processes such as electromagnetically induced transparency in laser cooled atomic medium confined within a hollow core photonic crystal fibre. Possible applications of this system are also discussed.

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Tapered optical fibers as tools for probing magneto-optical trap characteristics

Cited by 68 publications

References 34 publications

Contributed Review: Optical micro- and nanofiber pulling rig

Contributed Review: Optical micro- and nanofiber pulling rig

Optical Nanofibers

Manipulating Cold Atoms with Optical Fibres

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