Nanotechnology with atom optics

McClelland, Jabez J.; Hill, Shannon B.; Pichler, Marin; Celotta, Robert

doi:10.1016/j.stam.2004.02.023

Cited by 21 publications

(10 citation statements)

References 26 publications

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“…Manipulation and control of matter at the micro-nano-and atomic level has become increasingly important for the investigation of cold quantum gases [1], atom interferometry [2], quantum information processing [3] and precision positioning of atoms on or under surfaces [4,5]. For the most part magnetic forces have been used in order to take advantage of favorable scaling laws and on-chip integration technologies as component size reduces to the micron scale [6,7,8].…”

Section: Introductionmentioning

confidence: 99%

All-optical atom surface traps implemented with one-dimensional planar diffractive microstructures

Alloschery¹,

Mathevet²,

Weiner³

et al. 2006

Opt. Express

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Abstract:We characterize the loading, containment and optical properties of all-optical atom traps implemented by diffractive focusing with one-dimensional (1D) microstructures milled on gold films. These on-chip Fresnel lenses with focal lengths of the order of a few hundred microns produce optical-gradient-dipole traps. Cold atoms are loaded from a mirror magneto-optical trap (MMOT) centered a few hundred microns above the gold mirror surface. Details of loading optimization are reported and perspectives for future development of these structures are discussed.

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Section: Introductionmentioning

confidence: 99%

All-optical atom surface traps implemented with one-dimensional planar diffractive microstructures

Alloschery¹,

Mathevet²,

Weiner³

et al. 2006

Opt. Express

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“…Although the cross-cavity OSG has not yet been implemented experimentally, the cross-cavity setup has been built to test Lorentz invariance at the 10 −17 level [10]. In addition to the developments in probing atomic and cavity-field states, atomic lithography-where classical light is used to focus matter on the nanometer scale-has also witnessed considerable progress in recent decades [11][12][13]. The atom-light interaction is manipulated to assemble a structured array of atoms with potential applications to nanotechnology-related fields.…”

mentioning

confidence: 99%

“…The atom-light interaction is manipulated to assemble a structured array of atoms with potential applications to nanotechnology-related fields. Beyond the achievements in the growth of spatially periodic and quasi-periodic [14] atomic patterns [11][12][13], recent works have explored the possibility of creating nonperiodic arrays by using complex optical fields [15][16][17].…”

mentioning

confidence: 99%

Quantum atomic lithography via cross-cavity optical Stern–Gerlach setup

Máximo¹,

Batalhão²,

Bachelard³

et al. 2014

J. Opt. Soc. Am. B

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We present a fully quantum scheme to perform two-dimensional atomic lithography based on a cross-cavity optical Stern-Gerlach setup: an array of two mutually orthogonal cavities crossed by an atomic beam perpendicular to their optical axes, which is made to interact with two identical modes. After deriving an analytical solution for the atomic momentum distribution, we introduce a protocol allowing us to control the atomic deflection by manipulating the amplitudes and phases of the cavity field states. Our quantum scheme provides subwavelength resolution in the nanometer scale for the microwave regime.

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“…Compared with the conventional optical lithography, the atom lithography technique in performance has potential advantages. The process of atom lithography is based on two different types of interactional forces that can be used to manipulate neutral atoms by laser field, the atomic beam is collimated and the standing-wave field acts like an array of cylindrical lenses and can focus them onto the substrate and then form the nanometre structure, the spacing between the lines is predictably coincident with the half-wavelength of the optical standing-wave that is used as a light mask [1][2][3] .Since the purpose of direct write atomic lithography is to deposit small features, any influence that contribute to a broadening of the features must be considered [4] . Based on the semi-classical model in this paper, we analyze the motion equation of atoms in the laser standing wave field, and then get the trajectory of the atoms in the standing wave field by analytical simulation.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Influence of laser power on deposition of the chromium atomic beam in laser standing wave

Zhang

Zhu

Zhang

et al. 2009

Sci. China Ser. G-Phys. Mech. Astron.

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One-dimensional deposition of collimated Cr atomic beam focused by a near-resonant Gaussian standing-laser field with wavelength of 425.55 nm is examined from particle-optics approach by using an adaptive step size, fourth-order Runge-Kutta type algorithm. The influence of laser power on deposition of atoms in laser standing wave is discussed and the simulative result shows that the FWHM of nanometer stripe is 102 nm and contrast is 2 : 1 with laser power equal to 3 mW, the FWHM is 1.2 nm and contrast is 32 : 1 with laser power equal to 16 mW, but with laser power increase, equal to 50 mW, the nonmeter structure forms the multi-crests and exacerbates.atom lithography, laser standing wave, laser power Direct writing atom lithography is a new technique in which resonant light is used to pattern an atomic beam and the nanostructures are formed when the atoms deposit on the substrate. Compared with the conventional optical lithography, the atom lithography technique in performance has potential advantages. The process of atom lithography is based on two different types of interactional forces that can be used to manipulate neutral atoms by laser field, the atomic beam is collimated and the standing-wave field acts like an array of cylindrical lenses and can focus them onto the substrate and then form the nanometre structure, the spacing between the lines is predictably coincident with the half-wavelength of the optical standing-wave that is used as a light mask [1][2][3] .Since the purpose of direct write atomic lithography is to deposit small features, any influence that contribute to a broadening of the features must be considered [4] . Based on the semi-classical model in this paper, we analyze the motion equation of atoms in the laser standing wave field, and then get the trajectory of the atoms in the standing wave field by analytical simulation. Basing on these analyses, we put the emphasis on the effect of laser power in standing wave for the nanometer structure's characteristic. The simulation results have shown that suitable laser power is very important for depositing fine nanometer structure with direct-write atom lithography.

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Nanotechnology with atom optics

Cited by 21 publications

References 26 publications

All-optical atom surface traps implemented with one-dimensional planar diffractive microstructures

All-optical atom surface traps implemented with one-dimensional planar diffractive microstructures

Quantum atomic lithography via cross-cavity optical Stern–Gerlach setup

Influence of laser power on deposition of the chromium atomic beam in laser standing wave

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