Observation of the Efimov state of the helium trimer

Achim Czasch; Anton Kalinin; D\"orte Blume; J\"org Voigtsberger; Lothar Ph. H. Schmidt; Maksim Kunitski; Markus Sch\"offler; Reinhard D\"orner; Robert E. Grisenti; Stefan Zeller

arxiv: 1512.02036 · v1 · pith:IV3D2KHEnew · submitted 2015-12-07 · ⚛️ physics.atm-clus · cond-mat.quant-gas· nucl-ex· nucl-th· quant-ph

Observation of the Efimov state of the helium trimer

Maksim Kunitski , Stefan Zeller , J\"org Voigtsberger , Anton Kalinin , Lothar Ph. H. Schmidt , Markus Sch\"offler , Achim Czasch , Wieland Sch\"ollkopf

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Robert E. Grisenti Till Jahnke D\"orte Blume Reinhard D\"orner

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classification ⚛️ physics.atm-clus cond-mat.quant-gasnucl-exnucl-thquant-ph

keywords efimovpredictedstatethree-bodyatomsheliumobservationspatial

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Quantum theory dictates that upon weakening the two-body interaction in a three-body system, an infinite number of three-body bound states of a huge spatial extent emerge just before these three-body states become unbound. Three helium atoms have been predicted to form a molecular system that manifests this peculiarity under natural conditions without artificial tuning of the attraction between particles by an external field. Here we report experimental observation of this long predicted but experimentally elusive Efimov state of $^{4}$He$_{3}$ by means of Coulomb explosion imaging. We show spatial images of an Efimov state, confirming the predicted size and a typical structure where two atoms are close to each other while the third is far away.

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