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durham.ac.uk/mark.saunders

Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders. http://massey.dur.ac.uk/index.html. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders. The  -kicked rotor (  kr). Classical  kr. Classical  kr. Classical  kr: Poincaré sections. Quantum  kr.

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durham.ac.uk/mark.saunders

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  1. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

  2. http://massey.dur.ac.uk/index.html

  3. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

  4. The -kicked rotor (kr)

  5. Classical kr

  6. Classical kr

  7. Classical kr: Poincaré sections

  8. Quantum kr

  9. Quantum kr

  10. Quantum kr: Resonance and antiresonance

  11. Quantum kr: Resonance and antiresonance

  12. Quantum kr: Resonance and antiresonance

  13. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

  14. The atom-optical -kicked accelerator

  15. The atom-optical -kicked accelerator

  16. The two-level atom

  17. The two-level atom

  18. The two-level atom

  19. The two-level atom

  20. The two-level atom

  21. The two-level atom

  22. The atom-optical -kicked accelerator

  23. The atom-optical -kicked accelerator

  24. The atom-optical -kicked accelerator

  25. Thermal gas: Initial conditions

  26. Thermal gas: Initial conditions

  27. Thermal gas: Initial conditions

  28. Simulations

  29. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

  30. Experimental accessibility

  31. Applications

  32. Application 1: Velocity selection

  33. Application 1: Velocity selection

  34. Application 2: Gyroscopes

  35. Application 2: Gyroscopes

  36. Application 2: Gyroscopes

  37. Application 3: Accelerometry

  38. Applications

  39. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

  40. Inertial sensitivity: Zero Temperature limit

  41. Inertial sensitivity: Zero Temperature limit

  42. Inertial sensitivity: Zero Temperature limit

  43. Inertial sensitivity: Zero Temperature limit

  44. Inertial sensitivity: Finite temperatures

  45. Resonance width

  46. Resonance width

  47. Resonance width

  48. Inertial sensing with cold atoms. www.durham.ac.uk/mark.saunders

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