In order to explain the observed rate of expansion, dark energy must account for about 70% of all energy in the universe. But physicists still need a direct confirmation of its existence.
(photo of Dan Kapner, lead author of the paper; courtsey: the Eöt-Wash group )In a recent paper in Physical Review Letters, a team of physicists from the Eöt-Wash group at the Center for Experimental Nuclear Physics and Astrophysics, University of Washington, Seattle reported their measurement of the force of gravity down to 55 micrometres and their conclusion that the inverse-square law remained valid well below 85 micrometres with 95% confidence. In a laboratory set-up, the scientists made very precise measurement of the gravitational attraction between two plates placed upon a torsion pendulum. Although a few other groups in various countries are engaged in such measurements, according to the Eöt-Wash researchers, their experiment offers the highest sensitivity at the length-scale associated with dark energy because it employs more interacting mass at the required separations than other setups.
Those who are familiar with such type of precision measurement will know that this puts a limit on the length-scale of any new type of interaction that can be theoretically predicted to exist. The experiment still does not rule out the existence of dark energy. But the potential implication of this experiment is very significant -- it's indeed a set-back for the theory of dark energy that could explain the increasing expansion of the universe.
Reference:
"Tests of the Gravitational Inverse-Square Law below the Dark-Energy Length Scale"
D. J. Kapner, T. S. Cook, E. G. Adelberger, J. H. Gundlach, B. R. Heckel, C. D. Hoyle, and H. E. Swanson,
D. J. Kapner, T. S. Cook, E. G. Adelberger, J. H. Gundlach, B. R. Heckel, C. D. Hoyle, and H. E. Swanson,
Phys. Rev. Lett. 98, 021101 (8th January issue, 2007) Link to Abstract
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