Statistical learnability of nuclear masses

After more than 80 years from the seminal work of Weizs\"acker and the liquid drop model of the atomic nucleus, deviations from experiments of mass models ($\sim$ MeV) are orders of magnitude larger than experimental errors ($\lesssim$ keV). Predicting the mass of atomic nuclei with precision is extremely challenging. This is due to the non--trivial many--body interplay of protons and neutrons in nuclei, and the complex nature of the nuclear strong force. Statistical theory of learning will be used to provide bounds to the prediction errors of model trained with a finite data set. These bounds are validated with neural network calculations, and compared with state of the art mass models. Therefore, it will be argued that the nuclear structure models investigating ground state properties explore a system on the limit of the knowledgeable, as defined by the statistical theory of learning

Ab initio optical potentials and nucleon scattering on medium mass nuclei

We show the first results for the elastic scattering of neutrons off oxygen and calcium isotopes obtained from ab initio optical potentials. The potential is derived using self consistent Green's function theory (SCGF) with the saturating chiral interaction NNLO$_{\textrm{sat}}$. Our calculations are compared to available scattering data and show that it is possible to reproduce low energy scattering observables in medium mass nuclei from first principles.Comment: 6 pages, 4 figures, Zakopane conference on nuclear physic

Cooper pair transfer in nuclei

The second order DWBA implementation of two-particle transfer direct reactions which includes simultaneous and successive transfer, properly corrected by non-orthogonality effects is tested with the help of controlled nuclear structure and reaction inputs against data spanning the whole mass table, and showed to constitute a quantitative probe of nuclear pairing correlations

Testing two-nucleon transfer reaction mechanism with elementary modes of excitation in exotic nuclei

Nuclear Field Theory of structure and reactions is confronted with observations made on neutron halo dripline nuclei, resulting in the prediction of a novel (symbiotic) mode of nuclear excitation, and on the observation of the virtual effect of the halo phenomenon in the apparently non-halo nucleus $^7$Li. This effect is forced to become real by intervening the virtual process with an external (t,p) field which, combined with accurate predictive abilities concerning the absolute differential cross section, reveals an increase of a factor 2 in the cross section due to the presence of halo ground state correlations, and is essential to reproduce the value of the observed $d \sigma(^7$Li(t,p)$^9$Li)/d$\Omega$.Comment: Submitted to CERN proceedings for the 14th International Conference on Nuclear Reaction mechanisms, Varenna, June 15 - 19, 201

Unified description of structure and reactions: implementing the Nuclear Field Theory program

The modern theory of the atomic nucleus results from the merging of the liquid drop (Niels Bohr and Fritz Kalckar) and of the shell model (Marie Goeppert Meyer and Axel Jensen), which contributed the concepts of collective excitations and of independent-particle motion respectively. The unification of these apparently contradictory views in terms of the particle-vibration (rotation) coupling (Aage Bohr and Ben Mottelson) has allowed for an ever increasingly complete, accurate and detailed description of the nuclear structure, Nuclear Field Theory (NFT, developed by the Copenhagen-Buenos Aires collaboration) providing a powerful quantal embodiment. In keeping with the fact that reactions are not only at the basis of quantum mechanics (statistical interpretation, Max Born) , but also the specific tools to probe the atomic nucleus, NFT is being extended to deal with processes which involve the continuum in an intrinsic fashion, so as to be able to treat them on an equal footing with those associated with discrete states (nuclear structure). As a result, spectroscopic studies of transfer to continuum states could eventually use at profit the NFT rules, extended to take care of recoil effects. In the present contribution we review the implementation of the NFT program of structure and reactions, setting special emphasis on open problems and outstanding predictions.Comment: submitted to Physica Scripta to the Focus Issue on Nuclear Structure: Celebrating the 1975 Nobel Priz

Presenza di un «Potyvirus» sul Carciofo (<i>Cynara scolymus</i> L.) in Sardegna

A latent virus of artichoke has been isolated in Sardinia (Italy). The virus causes characteristic local lesions on Gomphrena globosa L. and Chenopodium amaranticolor Coste et Reyn., and systemic symptoms on Nicotiana benthamiana Domin. and N. clevelandii Gray. In artichoke crude sap the virus has a longevity in vitro of 20-30 hours, a dilution-end point between 10-3 and 10-4 and a thermal inactivation point between 55 and 60°C. The purification of the virus has been obtained from artichoke with two cicles of differential centrifugation followed by sucrose density gradient centrifugation. The purified suspensions had an ultraviolet light (UV) ab sorption spectrum typical of the nucleoproteins with Emax = 260-262 nm; Emin = 246 nm; and a ratio E280/E260 of 0,85 which suggests a RNA content of the virus of about 5,5%. Electron microscope observation showed that negative stained partially purified virus suspensions are composed of filamentous parti cles with a normal lenght (NL) of 730 nm and a mode of the lenght distributions of 729 nm; moreover, ultrathin sections of tissue fragments from leaves of mechanically inocu1ated Nicotiana benthamiana contained cytoplasmic inclusions of the pinwheel type. In serological tube tests, partially purified virus suspensions reacted with homologous serum (titre 1 : 1024) and a serum immune to an ALV (Artichoke Latent Virus) from Bari. These results have been substantially confirmed by serological tests with the method of «antibody coating of virus parti cles » by immune electron microscopy. I t is obvious that a latent potyvirus is widespread in artichoke growing in Sardinia. However, it cannot be exc1uded the possible occurrence in artichoke plants of a latent carlavirus too

Reperimento del virus dell'«arricciamento maculato» il del carciofo (AMCV) in Sardegna

A virus disease of «Masedu» of artichoke has been observed, in a serious form, in southern Sardinia (Italy). Affected plants are stunted with leaves heavily mottled, crinkled and laciniated. On the basis of the herbaceous hosts reactions, physical properties «in vitro», spectrophotometry, electron microscopy and serology, the virus recovered from diseased plants is identified as an isolate of AMCV, belonging to «Tombusvirus» group, serologically undistinguishable from the italian type isolate

Pairing interaction and two-nucleon transfer reactions

Making use of the fact that the collective modes associated with the spontaneous (static and dynamic) violation of gauge invariance in atomic nuclei (pairing rotations and pairing vibrations) are amenable to a simple, quite accurate nuclear structure description (BCS and QRPA respectively), it is possible to quantitatively test the reaction mechanism which is at the basis of two-nucleon transfer reactions, specific probe of pairing in nuclei. With the help of the static and dynamic mean field spectroscopic amplitudes, taking into account successive and simultaneous transfer channels properly corrected because of non-orthogonality effects, as well as describing the associated elastic channels in terms of experimentally determined optical potentials, one obtains absolute, two-particle transfer differential cross sections which provide an overall account of the data within experimental errors. One of the first results connected with such quantitative studies of pairing correlations in nuclei is the observation of phonon mediated pairing in the exotic halo nucleus 11Li, and the associated discovery of a new mechanism to break nuclear gauge symmetry: bootstrap, pigmy-resonance-mediated Cooper pair binding.Comment: Extended version of the article appeared in Nuclear Physics News 24:1, p. 19, 201