C. Carasco scite author profile

We have carried out an (e,e'p) experiment at high momentum transfer and in parallel kinematics to measure the strength of the nuclear spectral function S(k, E) at high nucleon momenta k and large removal energies E. This strength is related to the presence of short-range and tensor correlations, and was known hitherto only indirectly and with considerable uncertainty from the lack of strength in the independent-particle region. This experiment locates by direct measurement the correlated strength predicted by theory.PACS numbers: 21.10. Jx, 25.30.Fj Introduction. The concept of independent particle (IP) motion has been rather successful in the description of atomic nuclei; the shell model, based on the assumption that nucleons move, independently from each other, in the average potential created by the interaction with all other nucleons, has been able to explain many nuclear properties. This success often comes at the expense of the need to use effective operators that implicitly account for the shortcomings of the IP basis.A more fundamental approach to the understanding of nuclei has to start from the underlying nucleon-nucleon (N-N) interaction. This N-N interaction is well known from many experiments on N-N scattering, and several modern parameterizations are available. The N-N interaction exhibits a strongly repulsive central interaction at small internucleon distances, and at medium distances a strong tensor component. These features lead to properties of nuclear wave functions that are beyond what is describable in terms of an IP model. In particular, strong short-range correlations (SRC) are expected to occur.The effects of the short-range correlations were studied for systems where the Schrödinger equation can be solved for a realistic N-N interaction [1]. Very light nuclei (today up to A≤10) and infinite nuclear matter are amongst the systems where this is feasible [2,3,4]. The corresponding calculations show that in a microscopic description of nuclear systems the short-range and tensor parts of the N-N interaction have a very important, not to say dominating, influence without which not even nuclear binding can be explained.The consequences of these short-range correlations are that the momentum distributions of nucleons acquire a tail extending to very high momenta k and at the same

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Proton Spin Structure in the Resonance Region

Wesselmann¹,

Slifer²,

Tajima³

et al. 2007

Phys. Rev. Lett.

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ProtonGE/GMfrom beam-target asymmetry

Jones¹,

Aghalaryan²,

Ahmidouch³

et al. 2006

Phys. Rev. C

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Nuclear transparency from quasielasticC12(e,e'p

Rohe¹,

Benhar²,

Armstrong³

et al. 2005

Phys. Rev. C

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We studied the reaction 12 C(e,e'p) in quasielastic kinematics at momentum transfers between 0.6 and 1.8 (GeV/c) 2 covering the single-particle region. From this the nuclear transparency factors are extracted using two methods. The results are compared to theoretical predictions obtained using a generalization of Glauber theory described in this paper. Furthermore, the momentum distribution in the region of the 1s-state up to momenta of 300 MeV/c is obtained from the data and compared to the Correlated Basis Function theory and the Independent-Particle Shell model.

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C. Carasco

The neutron charge form factor and target analyzing powers from 3He(e→,e′n) scattering

Correlated Strength in the Nuclear Spectral Function

Proton Spin Structure in the Resonance Region

ProtonGE/GMfrom beam-target asymmetry

Nuclear transparency from quasielasticC12(e,e'p

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