Investigating the nature of N(1535) and (1405) in a quenched chiral quark model

Abstract

In this work, we systematically study N(1440), N(1535), and (1405) in both the quenched three-quark and five-quark frameworks using the Gaussian Expansion Method (GEM) within the chiral quark model. Our calculations show that N(1535) can be reproduced as a three-quark state (N(1P)), while N(1440) and (1405) cannot be accommodated as the three-quark candidates, (N(2S) and (1P)), respectively. In the five-quark framework, we find that the K state for N(1535) can not form a bound state, while in the NK channel there will (1405) form a shallow bound state. Based on the complex-scaling method, we performed complete coupled-channels calculations and obtained six resonance states with energies ranging from 1.8 GeV to 2.2 GeV, in addition with one bound state located around π channel. However, neither molecular candidates in K channel for N(1535) nor NK for (1405) are included in these states. This is because the strong coupling between NK and π will make the NK unbound, while the weak coupling between K and K can not help form a stable structure around K threshold. Thus, under the quenched quark model, our results support N(1535) as a three-quark state, while N(1440) is neither a three-quark nor a five-quark state. In addition, we find that although (1405) can be primarily a five-quark state, it requires a mixture of three-quark and five-quark components for stability. In the future, an exploration on the mixing effects between bare baryons with these relevant two-body hadronic channel components will be carried out to further test our conclusions.

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