Publications

Bartelt, Norman C.; Sadler, Lorraine E.; Steele, John T.; Strecker, Kevin S.; Tewell, Craig R.; Bisson, Scott E.; Brubaker, Erik B.; Hoops, Alexandra A.; Krenz, Kevin D.; Leonard, Francois L.; Le Galloudec, Nathalie J.

Abstract not provided.

Strecker, Kevin S.; Kay, Jeffrey J.; Steill, Jeffrey D.

Abstract not provided.

Strecker, Kevin S.

Abstract not provided.

Bartelt, Norman C.; Sadler, Lorraine E.; Shimizu, David A.H.; Steele, John T.; Strecker, Kevin S.; Tewell, Craig R.; Bisson, Scott E.; Brubaker, Erik B.; Hoops, Alexandra A.; Krenz, Kevin D.; Leonard, Francois L.; Le Galloudec, Nathalie J.

Abstract not provided.

Bartelt, Norman C.; Sadler, Lorraine E.; Steele, John T.; Strecker, Kevin S.; Tewell, Craig R.; Bisson, Scott E.; Brubaker, Erik B.; Hoops, Alexandra A.; Krenz, Kevin D.; Leonard, Francois L.; Le Galloudec, Nathalie J.

Abstract not provided.

Hoops, Alexandra A.; Chandler, D.W.; Moore, Sean M.; Patterson, Brian D.; Strecker, Kevin S.

Abstract not provided.

Hoops, Alexandra A.; Bisson, Scott E.; Sadler, Lorraine E.; Shimizu, David A.H.; Steele, John T.; Strecker, Kevin S.

Abstract not provided.

Hoops, Alexandra A.; Bisson, Scott E.; Steele, John T.; Strecker, Kevin S.

Abstract not provided.

Bisson, Scott E.; Hoops, Alexandra A.; Marleau, Peter M.; Neel, Wiley C.; Sadler, Lorraine E.; Shimizu, David A.H.; Strecker, Kevin S.

Abstract not provided.

Bisson, Scott E.; Strecker, Kevin S.; Hoops, Alexandra A.

Abstract not provided.

Bartelt, Norman C.; Bisson, Scott E.; Hoops, Alexandra A.; Krenz, Kevin D.; Kulp, Thomas J.; Leonard, Francois L.; Strecker, Kevin S.; Steele, John T.

Abstract not provided.

Chandler, D.W.; Strecker, Kevin S.

The 'dual etalon frequency comb spectrometer' is a novel low cost spectometer with limited moving parts. A broad band light source (pulsed laser, LED, lamp ...) is split into two beam paths. One travels through an etalon and a sample gas, while the second arm is just an etalon cavity, and the two beams are recombined onto a single detector. If the free spectral ranges (FSR) of the two cavities are not identical, the intensity pattern at the detector with consist of a series of heterodyne frequencies. Each mode out of the sample arm etalon with have a unique frequency in RF (radio-frequency) range, where modern electronics can easily record the signals. By monitoring these RF beat frequencies we can then determine when an optical frequencies is absorbed. The resolution is set by the FSR of the cavity, typically 10 MHz, with a bandwidth up to 100s of cm{sup -1}. In this report, the new spectrometer is described in detail and demonstration experiments on Iodine absorption are carried out. Further we discuss powerful potential next generation steps to developing this into a point sensor for monitoring combustion by-products, environmental pollutants, and warfare agents.

Journal of Chemical Physics

Chandler, D.W.; Strecker, Kevin S.

Abstract not provided.

Physical Review A

Strecker, Kevin S.; Chandler, D.W.

Abstract not provided.

Bisson, Scott E.; Bartelt, Norman C.; Leonard, Francois L.; Hoops, Alexandra A.; Kulp, Thomas J.; Krenz, Kevin D.; Strecker, Kevin S.; Steele, John T.

Abstract not provided.

Chandler, D.W.; Strecker, Kevin S.

We have developed a novel experimental technique for direct production of cold molecules using a combination of techniques from atomic optical and molecular physics and physical chemistry. The ability to produce samples of cold molecules has application in a broad spectrum of technical fields high-resolution spectroscopy, remote sensing, quantum computing, materials simulation, and understanding fundamental chemical dynamics. Researchers around the world are currently exploring many techniques for producing samples of cold molecules, but to-date these attempts have offered only limited success achieving milli-Kelvin temperatures with low densities. This Laboratory Directed Research and Development project is to develops a new experimental technique for producing micro-Kelvin temperature molecules via collisions with laser cooled samples of trapped atoms. The technique relies on near mass degenerate collisions between the molecule of interest and a laser cooled (micro-Kelvin) atom. A subset of collisions will transfer all (nearly all) of the kinetic energy from the 'hot' molecule, cooling the molecule at the expense of heating the atom. Further collisions with the remaining laser cooled atoms will thermally equilibrate the molecules to the micro-Kelvin temperature of the laser-cooled atoms.

Strecker, Kevin S.; Chandler, D.W.

A molecular fountain directs slowly moving molecules against gravity to further slow them to translational energies that they can be trapped and studied. If the molecules are initially slow enough they will return some time later to the position from which they were launched. Because this round trip time can be on the order of a second a single molecule can be observed for times sufficient to perform Hz level spectroscopy. The goal of this LDRD proposal was to construct a novel Molecular Fountain apparatus capable of producing dilute samples of molecules at near zero temperatures in well-defined user-selectable, quantum states. The slowly moving molecules used in this research are produced by the previously developed Kinematic Cooling technique, which uses a crossed atomic and molecular beam apparatus to generate single rotational level molecular samples moving slowly in the laboratory reference frame. The Kinematic Cooling technique produces cold molecules from a supersonic molecular beam via single collisions with a supersonic atomic beam. A single collision of an atom with a molecule occurring at the correct energy and relative velocity can cause a small fraction of the molecules to move very slowly vertically against gravity in the laboratory. These slowly moving molecules are captured by an electrostatic hexapole guiding field that both orients and focuses the molecules. The molecules are focused into the ionization region of a time-of-flight mass spectrometer and are ionized by laser radiation. The new molecular fountain apparatus was built utilizing a new design for molecular beam apparatus that has allowed us to miniaturize the apparatus. This new design minimizes the volumes and surface area of the machine allowing smaller pumps to maintain the necessary background pressures needed for these experiments.

Chandler, D.W.; Strecker, Kevin S.

Abstract not provided.

Physical Chemistry Chemical Physics

Strecker, Kevin S.; Jusinski, Leonard E.; Taatjes, Craig A.; Osborn, David L.

Abstract not provided.

Chandler, D.W.; Rahn, Larry A.; Strecker, Kevin S.

The production of Ultra-cold molecules is a goal of many laboratories through out the world. Here we are pursuing a unique technique that utilizes the kinematics of atomic and molecular collisions to achieve the goal of producing substantial numbers of sub Kelvin molecules confined in a trap. Here a trap is defined as an apparatus that spatially localizes, in a known location in the laboratory, a sample of molecules whose temperature is below one degree absolute Kelvin. Further, the storage time for the molecules must be sufficient to measure and possibly further cool the molecules. We utilize a technique unique to Sandia to form cold molecules from near mass degenerate collisions between atoms and molecules. This report describes the progress we have made using this novel technique and the further progress towards trapping molecules we have cooled.