Andere Kunden interessierten sich auch für
![The BCS-BEC Crossover and the Unitary Fermi Gas]( "The BCS-BEC Crossover and the Unitary Fermi Gas")
The BCS-BEC Crossover and the Unitary Fermi Gas88,99 €![Cold Atoms in a Cryogenic Environment]( "Cold Atoms in a Cryogenic Environment")
Cold Atoms in a Cryogenic Environment58,99 €![Theoretical Atomic Physics]( "Theoretical Atomic Physics")
Theoretical Atomic Physics66,99 €![Theoretical Atomic Physics]( "Theoretical Atomic Physics")
Theoretical Atomic Physics97,99 €![Theoretical Atomic Physics]( "Theoretical Atomic Physics")
Theoretical Atomic Physics59,99 €![Frontiers of Optical Spectroscopy]( "Frontiers of Optical Spectroscopy")
Frontiers of Optical Spectroscopy192,99 €![Frontiers of Optical Spectroscopy]( "Frontiers of Optical Spectroscopy")
Frontiers of Optical Spectroscopy272,99 €
A Bose-Einstein condensate (BEC) interferometer on an atom chip is capable of making an absolute force measurement. The author demonstrates this by making an absolute measurement of the gravitational acceleration g. Two interferometer arms are implemented by splitting a BEC into two symmetric wells using radio-frequency (rf) adiabatic potentials. The independent control of the rf currents running through the chip surface allows to change the polarization of the field and hence the orientation of the double well potential. Tilting of the system with respect to the horizontal introduces an energy difference and the relative phase between the BECs starts to evolve. After moving the atoms back to their initial position and overlapping the clouds in free fall the resulting phase exhibits in the interference pattern. In order to derive a number for g from experimental results a detailed analysis and understanding of the interferometer scheme is essential.