Experimental Observation of Quantum Reflection in the High Energy Limit
Abstract
We present first experimental data on the high energy behavior of helium atoms quantum reflecting from the nanoscopically disordered surface of a quartz crystal. The use of the light, stable and inert He atom not only opens the unique possibility of measuring quantum reflectivity in the thusfar inaccessible limit of high energies, but also allows the determination of the gas-solid interaction potential. The specularly reflected intensity from the rough surface shows a change of 5 orders of magnitude within an incident angular range of less than 6 degrees. By separating out the influence of surface disorder the quantum reflection coefficient for the smooth surface is deduced. Firstly, the data confirm the high energy asymptotic behavior of the reflection, defined by the non-retarded attractive van der Waals potential. The experiment shows very good agreement with our calculations covering the entire energy region, in which also Casimir forces play a role. Parameters for the gas-solid interaction perfectly match those reported in literature in the vicinity of the potential minimum.
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