Ramsey-bordé ion frequency-reference apparatus, and methods of making and using the same

What is claimed is: 1. An interferometric frequency-reference apparatus, said apparatus comprising: a vacuum chamber; an atom source configured to supply neutral atoms to be ionized; an ionizer configured to excite said neutral atoms to form ionized atoms; an ion collimator configured to form a collimated beam of said ionized atoms; one or more probe lasers; and a readout laser configured to determine a ground-state population of said ionized atoms, wherein said atom source, said ionizer, and said ion collimator are disposed within said vacuum chamber. 2. The interferometric frequency-reference apparatus of claim 1 , wherein said atom source is a solid-state electrochemical atom source. 3. The interferometric frequency-reference apparatus of claim 1 , wherein said ionizer is disposed inside said ion collimator. 4. The interferometric frequency-reference apparatus of claim 1 , wherein said ionizer is disposed outside said ion collimator. 5. The interferometric frequency-reference apparatus of claim 1 , wherein said ion collimator is a linear collimator. 6. The interferometric frequency-reference apparatus of claim 5 , wherein said linear collimator is selected from the group consisting of a linear quadrupole trap, a Penning trap, a surface ion trap, and a mass filter. 7. The interferometric frequency-reference apparatus of claim 1 , wherein said ion collimator is a non-linear collimator. 8. The interferometric frequency-reference apparatus of claim 7 , wherein said non-linear collimator is in a recirculating configuration. 9. The interferometric frequency-reference apparatus of claim 1 , wherein said ion collimator is configured such that said collimated beam of said ionized atoms has a beam waist selected from about 10 nanometers to about 10 meters. 10. The interferometric frequency-reference apparatus of claim 1 , wherein said ion collimator is configured such that said collimated beam of said ionized atoms has a beam velocity selected from about 1 micron/second to about 0.99c, where c is the speed of light in vacuum. 11. The interferometric frequency-reference apparatus of claim 1 , wherein said one or more probe lasers are configured for Ramsey spectroscopy on said ionized atoms. 12. The interferometric frequency-reference apparatus of claim 1 , wherein said one or more probe lasers is two or more probe lasers. 13. The interferometric frequency-reference apparatus of claim 1 , wherein said one or more probe lasers are configured to probe quadrupole or both dipole and quadrupole transitions of said ionized atoms. 14. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus further comprises a cooling laser. 15. The interferometric frequency-reference apparatus of claim 1 , wherein said readout laser is further configured for cooling. 16. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus further comprises an injection electrode. 17. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus further comprises an ion sink configured to collect said ionized atoms exiting said ion collimator, and wherein said ion sink is disposed within said vacuum chamber. 18. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus further comprises an imaging system configured to focus fluorescence from said ionized atoms. 19. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus provides an optical frequency reference. 20. The interferometric frequency-reference apparatus of claim 1 , wherein said interferometric frequency-reference apparatus provides a microwave frequency reference. 21. A method of creating a stable frequency reference, said method comprising: (a) creating an atomic vapor; (b) ionizing at least some atoms in said atomic vapor, to form ionized atoms; (c) collimating said ionized atoms in an ion collimator, to form a collimated beam of said ionized atoms; (d) optionally, illuminating some of said ionized atoms with a cooling laser; (e) illuminating at least some of said ionized atoms with a first probe laser at a first-probe-laser frequency; (f) illuminating at least some of said ionized atoms with a second probe laser at a second-probe-laser frequency; (g) adjusting said first-probe-laser frequency and said second-probe-laser frequency using Ramsey spectroscopy to an S→D transition of at least some of said ionized atoms; and (h) illuminating at least some of said ionized atoms with a readout laser to determine a ground-state population of said ionized atoms. 22. The method of claim 21 , wherein said atomic vapor and/or said ionized atoms are obtained from a solid-state electrochemical atom source. 23. The method of claim 21 , wherein said ionized atoms are Ca + and/or Sr + . 24. The method of claim 21 , wherein said ionized atoms provided in step (b) are formed within said ion collimator provided in step (c). 25. The method of claim 21 , wherein said ionized atoms provided in step (b) are injected into said ion collimator. 26. The method of claim 21 , wherein step (d) is conducted to cool said ionized atoms in preparation for said Ramsey spectroscopy. 27. The method of claim 21 , wherein said ion collimator is a linear collimator. 28. The method of claim 27 , wherein said linear collimator is selected from the group consisting of a linear quadrupole trap, a Penning trap, a surface ion trap, and a mass filter. 29. The method of claim 21 , wherein said ion collimator is a non-linear collimator. 30. The method of claim 29 , wherein said non-linear collimator is in a recirculating configuration. 31. The method of claim 21 , wherein said collimated beam of said ionized atoms has a beam waist selected from about 10 nanometers to about 10 meters. 32. The method of claim 21 , wherein said collimated beam of said ionized atoms has a beam velocity selected from about 1 micron/second to about 0.99c, where c is the speed of light in vacuum. 33. The method of claim 21 , wherein said method further comprises illuminating at least some of said ionized atoms with a third probe laser. 34. The method of claim 33 , wherein said method further comprises illuminating at least some of said ionized atoms with a fourth probe laser after said illuminating at least some of said ionized atoms with said third probe laser. 35. The method of claim 21 , wherein said method is continuous. 36. The method of claim 21 , wherein said stable frequency reference is an optical frequency reference. 37. The method of claim 21 , wherein said stable frequency reference is a microwave frequency reference. 38. The method of claim 21 , wherein said method utilizes the interferometric frequency-reference apparatus according to claim 1 .