Charmed baryon 
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 in nuclear matter

Ohtani, Kazuhiro; Araki, Ken-Ji; Oka, M.

doi:10.1103/physrevc.96.055208

Cited by 14 publications

(21 citation statements)

References 88 publications

(147 reference statements)

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“…In Ref. [357] the sum rules were improved by taking into account α s corrections to the Wilson coefficients and employing the parity projected sum rules with a Gaussian kernel. In the same work, the treatment of the density dependence of four-quark condensates was studied in detail.…”

Section: Heavy Baryonsmentioning

confidence: 99%

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Recent progress in QCD condensate evaluations and sum rules

Gubler

Satow

2019

Progress in Particle and Nuclear Physics

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We review the recent status of the QCD sum rule approach to study the properties of hadrons in vacuum and in hot or dense matter. Special focus is laid on the progress made in the evaluation of the QCD condensates, which are the input of all QCD sum rule calculations, and for which much new information has become available through high precision lattice QCD calculations, chiral perturbation theory and experimental measurements. Furthermore, we critically examine common analysis methods for QCD sum rules and contrast them with potential alternative strategies. The status of QCD sum rule studies investigating the modification of hadrons at finite density as well as recent derivations of exact sum rules applicable to finite temperature spectral functions, are also reviewed.

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Section: Heavy Baryonsmentioning

confidence: 99%

“…It was therefore concluded in Ref. [357] that only the PCQM prescription is suitable for this specific sum rule and hence also for the one of the Λ c . This then leads to an about 20 MeV attraction of the Λ c at normal nuclear matter density.…”

Section: Heavy Baryonsmentioning

confidence: 99%

Recent progress in QCD condensate evaluations and sum rules

Gubler

Satow

2019

Progress in Particle and Nuclear Physics

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“…with the vector-type self-energy Σ v (T, µ), the effective mass M * (T, µ), q the three-dimensional momentum of the Λ c baryon [47] (see also Ref. [62].).…”

Section: Change Of Number Density Of Nucleonsmentioning

confidence: 99%

Fate of the charm baryon Λc in cold and hot nuclear matter

Yasui

2019

Phys. Rev. C

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We discuss the properties of the Λc baryon in nuclear matter at zero or finite temperature. Starting from the Lagrangian based on the heavy quark effective theory, we derive the effective Lagrangian for the Λc baryon existing as an impurity particle. Adopting the one-loop calculation for nucleons, we derive the effective potential as the quantity for measuring the stability of the Λc baryon in nuclear matter. The parameters in the Lagrangian are used by estimations in the lattice QCD simulations and the chiral extrapolations. We present that the Λc baryon is bound in nuclei with the binding energy of about 20 MeV at normal nuclear matter density. We discuss the case that the Λc baryon moves with constant velocity in nuclear matter. We also discuss the change of nucleon number density near the Λc baryon in nuclear matter, and show that the Λc baryon is a useful probe to research the higher density state in nuclear matter. * yasuis@keio.jp arXiv:1811.07286v1 [hep-ph]

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“…The prospect of an ample production of baryons with charm offered by facilities such as the LHC at CERN [1][2][3], RHIC at BNL [4], J-PARC and KEK in Japan [5,6], or FAIR in Germany [7][8][9] has led to a renewed interest in the in-medium properties of such baryons [10][11][12][13] and also in the question whether they, and notably the lightest charmed baryon, the Λ c (2286), could form bound states with ordinary matter [14][15][16][17][18][19]. In fact, there is a long history of speculations about possible bound systems involving the Λ c [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] that started soon after the discovery of charmed baryons [36,37] (see also the recent reviews [38,39]).…”

Section: Introductionmentioning

confidence: 99%

Predictions for charmed nuclei based on $Y_c N$ forces inferred from lattice QCD simulations

Haidenbauer,

Nogga,

Vidaña

2020

Preprint

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Charmed nuclei are investigated utilizing ΛcN and ΣcN interactions that have been extrapolated from lattice QCD simulations at unphysical masses of mπ = 410-570 MeV to the physical point using chiral effective field theory as guideline. Calculations of the energies of Λc single-particle bound states for various charmed nuclei from 5Λc Li to 209 Λc Bi are performed using a perturbative many-body approach. This approach allows one to determine the finite nuclei Λc self-energy from which the energies of the different bound states can be obtained. Though the ΛcN interaction inferred from the lattice results is only moderately attractive, it supports the existence of charmed nuclei. Already the lightest nucleus considered is found to be bound. The spin-orbit splitting of the p-and d-wave states turns out to be small, as in the case of single Λ hypernuclei. Additional calculations based on the Faddeev-Yakubovsky equations suggest that also A = 4 systems involving a Λc baryon are likely to be bound, but exclude a bound 3 Λc He state.

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Charmed baryon Λc in nuclear matter

Cited by 14 publications

References 88 publications

Recent progress in QCD condensate evaluations and sum rules

Recent progress in QCD condensate evaluations and sum rules

Fate of the charm baryon Λc in cold and hot nuclear matter

Predictions for charmed nuclei based on $Y_c N$ forces inferred from lattice QCD simulations

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