V. A. Lyamkin scite author profile

This article reviews the development of various sources for ultracold neutrons (UCNs) at the Petersburg Nuclear Physics Institute (PNPI). For 45 years, PNPI has proposed and manufactured cryogenic devices for neutron conversion to low energies. Based on beryllium, hydrogen and deuterium, they can be operated in the intense radiation fields near the core of a nuclear reactor. A more recently launched UCN source development utilizes superfluid helium (He-II) as conversion medium. Initially proposed and designed for PNPI’s old WWR-M reactor, the project has been reshaped to equip the institute’s PIK reactor with a modern UCN source of this type. The projected UCN density in the closed source chamber is 2.2 × 103 cm−3, which, as calculations of neutron transport show, will provide 200 cm−3 in the chambers of a neutron EDM spectrometer connected to the source by a UCN guide. Experiments at PNPI with a full-scale UCN source model have demonstrated that a heat load of 60 W can be removed from the He-II in the converter at a temperature of 1.37 K. This fact confirms the practical possibility to implement low-temperature converters under “in-pile” conditions with large heat inflows. The review concludes with a presentation of various proposed options for a He-II based UCN source at the European Spallation Source.

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Project of NNbar Experiment at the WWR-M Reactor

Fomin¹,

Serebrov²,

Zherebtsov³

et al. 2018

KEn

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Supersource of ultracold neutrons on the basis of superfluid helium is under construction in PNPI NRC KI. It must provide UCN density 2-3 orders of magnitude higher than existing sources. For the new source we propose an experiment on search for neutron-antineutron oscillations based on the storage of ultracold neutrons in a material trap. The sensitivity of the experiment mostly depends on the trap size and the amount of UCN in it. The results of simulations of the designed experimental scheme show that the sensitivity can be increased by ∼ 10-40 times compared to sensitivity of previous experiment depending on the model of neutron reflection from walls.

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Putting in operation a full-scale ultracold-neutron source model with superfluid helium

et al. 2017

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UCN source with superfluid helium at WWR-M reactor

Serebrov

Lyamkin

Fomin

et al. 2017

J. Phys.: Conf. Ser.

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V. A. Lyamkin

The project of ultracold neutron sources at the PIK reactor with superfluid helium as a moderator

Development of UCN sources at PNPI

Project of NNbar Experiment at the WWR-M Reactor

Putting in operation a full-scale ultracold-neutron source model with superfluid helium

UCN source with superfluid helium at WWR-M reactor

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