Patent Number: 
Section: claims

1. An ultra-cold-matter (UCM) system comprising:a hermetically-sealed ultra-high-vacuum (UHV) enclosure;a source cell having a source-cell enclosure, the source cell being nested within the UHV enclosure, the source cell being physically attached to and separated from the UHV enclosure so as to be thermally isolated from the UHV enclosure;a source material in a non-vapor phase and disposed within the source cell, said source material being characterized in that vapor-phase source atoms can be released from the source material;a cold-atom trap for cooling at least some of the vapor-phase source atoms to an ultra-cold temperature; andan atom getter for maintaining an ultra-high vacuum within the UHV enclosure at least in part by causing at least some of the vapor-phase source atoms to be sorbed to or into a getter material, the atom getter being disposed within the UHV enclosure and outside the source cell. 2. The UCM system of claim 1 further comprising a laser external to the UHV enclosure that serves as a source of a laser light, the UHV enclosure including a first transparent material that is transparent to the laser beam, the source-cell enclosure including second transparent material that is transparent to the laser beam and that is more resistant to corrosion by the vapor-phase source atoms than is the first transparent material. 3. The UCM system of claim 2 wherein the vapor-phase source atoms are atoms of strontium, the first transparent material is glass and the second transparent material is sapphire. 4. The UCM system of claim 1 wherein the getter material is disposed within the source cell and serves to regulate the amount of vapor-phase source atoms in the source cell by sorbing and releasing source atoms as a function of the partial pressure of the source atoms in the source cell. 5. The UCM system of claim 4 wherein the getter material includes at least one of gold, carbon, and antimony. 6. The UCM system of claim 1 further comprising:a first light-reflecting element set of at least a first reflecting element within the source-cell enclosure arranged to support a two-dimensional atom trap;a second light-reflecting element of at least a second reflecting element located within the enclosure and external to the source-cell enclosure and arranged to support a three-dimensional atom trap. 7. The UCM system of claim 1 wherein the atom getter includes an ion pump that ionizes the source atoms to yield source ions, the ion pump accelerating the source ions so that they contact that getter material. 8. The UCM system of claim 1 further comprising a hot mirror disposed between the source-cell enclosure and the UHV enclosure. 9. The UCM system of claim 8 wherein the hot mirror is formed as a coating on a surface of the source-cell enclosure facing the UHV enclosure. 10. The ultra-cold-matter system of claim 1 further comprising:a heater element disposed within the source-cell interior; andelectrical feed-throughs through the source cell and the UHV enclosure, the electrical feed-throughs providing electrical paths to and from the heater element. 11. The UCM system of claim 1 wherein the source material is an alkaline earth metal and the source cell is predominantly of sapphire or high-alumina-content silicate glass. 12. A process comprising:generating a vapor phase of source particles at least in part by heating a non-vapor-phase material, the generating occurring within a source cell nested within a vacuum enclosure;using a vacuum established between the vacuum enclosure and the source cell, thermally isolating an ultra-cold region within the vacuum enclosure and external to the source cell from heat generated in the source cell;using a laser, pre-cooling source particles within the source cell;transferring pre-cooled source particles from the source cell to the ultra-cold region; andusing a laser, trapping the source particles in the ultra-cold region. 13. The process of claim 12 further comprising regulating a pressure of the source particles in the source cell using getter material in the source cell that sorbs and releases at least some of the source particles. 14. The process of claim 12 further wherein the thermally isolating includes reflecting infrared light exiting the source cell using a hot mirror. 15. The process of claim 12 further wherein the source cell is nested within the vacuum enclosure using standoffs to spatially and thermally isolate the source cell from the vacuum enclosure. 16. The process of claim 12 further wherein the transferring includes gettering off-axis particles between the source cell and the ultra-cold region.