Research team for the first time observed a neutral nucleus: the Tetra Neutron
From: TECHNISCHE UNIVERSITAT DARMSTADT [in Germany]
June 22, 2022 -- The
experiment has been carried out at the Radioactive Ion Beam Factory RIBF at
RIKEN (Japan) by a large international research team. Significantly involved
were besides TU Darmstadt, scientists from TU Munich, the RIKEN Nishina
Center, and the GSI Helmholtz Center for Heavy-ion Research. The experiment
yielded an unambiguous signal for the first observation of the Tetra Neutron.
The result has been published in the current issue of “Nature”.
The building blocks of
atomic nuclei are nucleons, which exist as two kinds, the neutral neutrons and
the charged protons, representing the two isospin states of the nucleon. To our
present knowledge, nuclei made of neutrons only are not existing as bound
nuclei. The only bound systems known made of almost only neutrons are neutron
stars, which are very compact high-density objects in the universe bound by the
gravitational force with typical diameters of around 10 kilometers. Atomic
nuclei are bound by the nuclear strong force with a preference to balance
neutrons and protons, as known for the stable nuclei we find on earth.
The study of pure
neutron systems is of particular importance since they provide the only means
to extract experimental information on the interaction among several neutrons
and thereby on the nuclear force. If multi-neutron systems do exist as
resonances or even bound states has been a long-standing quest in nuclear
physics. The exploration of the so far hypothetical particles might furthermore
provide information helping for a better understanding of neutron-star
properties. If multi-neutron systems do exist as unbound resonant states or
even bound states has been a long-standing quest in nuclear physics. A research
team lead by scientists from TU Darmstadt set out to undertake a new attempt by
using a different experimental technique as compared to previous attempts. This
work was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research
Foundation) via the SFB 1245.
“This experimental
break-through provides a benchmark to test the nuclear force with a pure system
made of neutrons only", says Dr. Meytal Duer from Institute for Nuclear
Physics at the TU Darmstadt. “The nuclear interaction among more than two
neutrons could not be tested so far, and theoretical predictions yield a wide
scatter concerning the energy and width of a possible tetra neutron state. We
are currently planning to a next-generation experiment at R3B at FAIR, which
will detect directly the correlations among the four neutrons with the R3B
NeuLAND detector, which will give deeper insight to the nature of this
four-neutron system”.
The experimental study
of pure neutron systems is challenging because neutron targets do not exist. In
order to create multi-neutron systems in a volume where the neutrons can
interact via the short-range nuclear force (few femto-meter, 10-15 meter),
nuclear reactions have to be used. Here, the interaction of the neutrons with
other particles involved in the reaction process poses a major problem, which
can mask the properties of the pure neutron interaction. The scientists have
overcome this problem by shooting out the compact alpha core from 8He
instantaneously induced by a proton of the liquid hydrogen target. The
remaining four neutrons are suddenly free and left alone and can interact among
each other.
“Key for the successful
observation of the Tetra Neutron was the chosen reaction, which isolates the
four neutrons in a fast (compared to the nuclear scale) process, and the chosen
kinematics of large momentum-transfer, which separates the neutrons from the
charged particles in momentum space”, says Professor Dr. Thomas Aumann from the
Institute for Nuclear Physics at TU Darmstadt. “The extreme kinematics resulted
in an almost background-free measurement. We now plan to employ the same
reaction in an experiment at the RIBF to make a precision measurement of the
low-energy neutron-neutron interaction. A dedicated neutron detector for this
experiment is currently being built at our university”.
https://www.eurekalert.org/news-releases/956785
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