The strategy of the Atomic Physics Division is to develop and apply atomic physics research methods, and particulary the interaction between atoms and electromagnetic fields, to achieve fundamental advances in measurement science--some at the quantum limit--relevant to industry and the technical community, and to produce and critically compile physical reference data.

Strategic Focus Areas:

First

Light-Matter Interactions and Atom Optics  -  to advance the physics of electromagnetic-matter interactions, to explore new applications for laser cooled and trapped atoms, to study exotic states of matter, and to study and control many-body quantum systems.

Second

Nanoscale and Quantum Metrology  -  to advance measurement science at the atomic and nanometer scale, focusing on precision optical metrology, quantum devices, nanoscale plasmas and nanooptical systems.

Third

Critically Evaluated Atomic Data  -  to produce reference data on atomic structure, to critically compile reference data for scientific and technological applications, and to develop techniques to apply the data to further the understanding of important plasma devices.

Light-Matter Interactions and Atom Optics:

INTENDED OUTCOME AND BACKGROUND

This strategic element focuses on the physics of laser cooling and electromagnetic trapping of neutral particles, the manipulation of Bose-Einstein condensates (BECs), and the use of optical dipole forces as a new tool for analyzing of microscopic objects in biochemistry. It includes both fundamental and applied studies, such as developing measurement techniques for biomolecular systems and developing a quantum information processor. A strong theoretical-experimental collaboration is aimed at interpreting experimental results and providing guidance for new experiments.

The development of laser cooling and trapping techniques allows exquisite control over the motion of atoms. Such control has been exploited to build more precise atomic clocks and gravity gradiometers. These techniques also enable the study and manipulation of atoms and molecules under conditions in which their quantum or wave behavior dominates. This research has revolutionized the field of matter-wave optics.

Our research includes theoretical and experimental projects that contribute to the understanding and exploitation of: Bose-Einstein condensation of neutral atoms; matter-wave optics; optical and magnetic control of trapped-atom collisions; advanced laser cooling and collision studies for atomic clocks; the quantum behavior of atoms in optical lattices, including in low dimensionality; the superfluid to Mott-insulator quantum phase transition; quantum information processing; quantum-computing architectures; and optical characterization and manipulation of single molecules, biomolecules, and biomembranes.

Accomplishments

Control of Cold Quantum Gases

Figure 1. Lifetime of the tunable, molecular bound state of the 85Rb2 dimer as a magnetic field B is varied near a scattering resonance at 15.2 mT. The rapid increase in lifetime is due to the dramatic increase in the size of the weakly bound atom-pair, to hundreds of nanometers, as the field gets closer to the resonance value.

Many recent atomic physics experiments have used magnetic field control of scattering resonances to modify the properties and dynamics of ultracold atomic quantum gases such as Bose-Einstein condensates or mixtures of fermions. These resonances occur when the energy of a bound state of two atoms is tuned to the same energy as that of two separated cold atoms. Such resonances can be used to make cold molecules and molecular Bose-Einstein condensates, to strongly modify the nature of superfluid atom pairing, and to modify the properties of atoms trapped in optical lattices. Such phenomena are relevant to fundamental physics, condensed matter (solid state) physics, atomic clocks, and quantum information.

We have applied quantum mechanical models to quantitatively characterize such resonances and to develop simple physical models for understanding them. These have been applied to give good agreement with data and predictive power for bosonic species ⁸⁵Rb (see Fig. 1) and ¹³³Cs, and for fermionic species ⁶Li and ⁴⁰K. We have also initiated studies on optically induced scattering resonances for laser control of quantum gases of alkaline earth species such as Ca or Sr, which are of great interest for next-generation atomic clocks.

CONTACT: Dr. Paul S. Julienne (301) 975-2596 paul.julienne@nist.gov





• Spectroscopy of Na₂ Molecules in the Lowest Triplet State

  We have used the technique of two-color photoassociation spectroscopy (two colliding atoms absorbing photons to create a diatomic molecule) to improve the spectroscopy of the lowest triplet state of the Na₂ molecule. The spectra obtained represent a factor of 1000 improvement in resolution over the previously obtained spectra of this state, and include a number of previously unobserved vibrational levels, as well as unresolved hyperfine and fine structure. This knowledge has altered our view of the angular momentum coupling scheme that must be used to represent this state of the molecule.
  
  Knowledge of the interaction potentials between two sodium atoms, at the level of detail that can be obtained by photoassociation spectroscopy, is required to predict the behavior of this prototype system of two colliding, effectively single-electron atoms. Improved theory in this area is necessary for understanding many experiments in atomic and molecular physics, and is especially pertinent for current studies of atomic and molecular Bose-Einstein condensates.

  CONTACT: Dr. Paul Lett (301) 975-6559 paul.lett@nist.gov

  
  
  

• Optical Manipulation of Nanocontainers for Biotechnology

  In collaboration with researchers in CSTL and CARB, we are developing optical techniques for manipulating nanocontainers (containers with femto-liter volumes of fluids), to perform ultrasmall volume chemistry and to isolate and sort single molecules.
  
  We are currently investigating three systems, liposomes, polymersomes, and hydrosomes, for use as nanocontainers. Liposomes and polymersomes are closed structures composed of a lipid and polymer membrane, respectively, typically about 10 micrometers in diameter. The membrane acts as a barrier to separate an aqueous interior environment from an aqueous exterior environment. Hydrosomes are micrometer-sized, surfactant-stabilized water droplets that reside in a fluorocarbon environment.
  
  The techniques we use include optical tweezers, for trapping and remotely moving the nanocontainers, and an "optical scalpel," for opening membranes in order to induce fusion of liposomes and polymersomes. (See Fig. 2.) In all three systems, we are able to bring together two similar nanocontainers using optical trapping and to subsequently fuse them together, allowing their contents to mix.
  
  We have demonstrated the use of liposomes and hydrosomes in performing controlled, elementary chemical reactions. We are currently investigating the application of these nanocontainers for single-molecule studies and single-molecule sorting.
  

  Figure 2. Time sequence of video microscopy images showing two liposomes, brought into contact with optical tweezers and induced to fuse by an optical scalpel, a pulsed ultraviolet laser focused on the contact point, which initiates the fusion (a). Images (b), (c), and (d) were taken 132 ms, 264 ms, and 528 ms later, respectively.

  CONTACT: Dr. Kristian Helmerson (301) 975-4266 kristian.helmerson@nist.gov

  
  
  

• Neutral-Atom Quantum Information

  Figure 3. As the 3-D lattice depth is increased, the tunneling between lattice sites decreases. At a lattice depth of around 10 recoil energies, the system undergoes the Mott transition, and the diffraction pattern disappears. The transition is reversible, and the diffraction reappears when the lattice depth is reduced.

  Single atoms can act as qubits for quantum information (QI) using, for example, the internal hyperfine and Zeeman states as the qubit states. Our approach to neutral-atom QI is to hold and manipulate the atoms using laser fields for trapping and transporting. An optical lattice provides a natural register for atomic qubits. A BEC loaded adiabatically into an optical lattice provides, potentially, millions of qubits initialized in their ground states, since the BEC, or at least the condensed fraction, is initially in the ground state.
  
  If a noninteracting BEC is slowly loaded into an optical lattice, the typical result is that the coherent wavefunction of each atom is spread across all the available lattice sites, so that there is a statistical (Poissonian) fluctuation in the number of atoms in any given site. If, however, there are repulsive interactions, at some lattice depth the competition between tunneling and the on-site repulsive interaction favors the ground state being one (or some fixed number of) atom(s) per lattice site. This is a phase transition known as the Mott insulator transition because the system goes from being superfluid (at large tunneling rate) to insulating (at small tunneling).
  
  We observe the phase transition for Rb atoms in a three-dimensional optical lattice by looking at the diffraction pattern formed by the atoms upon release from the lattice. As shown in Fig. 3, well-resolved diffraction indicates phase coherence across the lattice, and therefore an uncertain atom number in each site. The disappearance of the diffraction pattern is characteristic of a fixed number per site, and therefore an uncertain phase difference from site to site, indicative of being in the insulator state.

  CONTACT: Dr. William D. Phillips (301) 975-6554 william.phillips@nist.gov

First strategic focus   |   Second strategic focus   |   Third strategic focus

"Technical Activities 2004" - Table of Contents