在QCD和规则下具有两个重夸克的四夸克态之间的混合角

IF 1.4 Q3 PHYSICS, MULTIDISCIPLINARY

Turkish Journal of Physics Pub Date : 2021-01-01 DOI:10.3906/fiz-2111-14

Selçuk Bi̇lmi̇ş

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引用次数: 2

摘要

LHCb合作最近宣布观测到双粲四夸克$T_{cc \bar{u} \bar{d}}^+$态，自旋宇称$J^P = 1^+$。这种奇异态可以解释为具有小结合能的分子态。根据传统的夸克模型，$D^+ D^{0\ast}$和$(D^0 D^{+\ast})$两种多夸克态在$SU(3)$对称下都具有相同的质量和风味。然而，由于夸克质量不同，$SU(3) (SU(2))$对称性被破坏，因此，质量和风味本征态不重合。质量本征态可以表示为风味本征态的线性组合，其特征为混合角$\theta$。在本工作中，计算了$T_{cc}$状态之间可能的混合角。此外，该分析扩展到分子图像中所有可能的四夸克状态，其中两个重夸克和两个轻夸克，尽管这些状态尚未被观察到。我们对双粲四夸克态混合角的预测表明，$SU(3)$对称破缺最大发生在$7\%$附近。

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Mixing angles between the tetraquark states with two heavy quarks within QCD sum rules

LHCb Collaboration has recently announced the observation of a doubly charmed tetraquark $T_{cc \bar{u} \bar{d}}^+$ state with spin parity $J^P = 1^+$. This exotic state can be explained as a molecular state with small binding energy. According to conventional quark model, both $D^+ D^{0\ast}$ and $(D^0 D^{+\ast})$ multiquark states are expected to have the same mass and flavor in the exact $SU(3)$ symmetry. However, since the quark masses are different, $SU(3) (SU(2))$ symmetry is violated, hence, the mass and flavor eigenstates do not coincide. The mass eigenstates can be represented as a linear combination of the flavor eigenstates, which is characterized by the mixing angle $\theta$. In the present work, the possible mixing angles between the $T_{cc}$ states are calculated. Moreover, the analysis are extended for all the possible tetraquarks scenarios with two heavy and two light quarks within the molecular picture although those states have not been observed yet. Our prediction on mixing angle between doubly charmed tetraquark states shows that $SU(3)$ symmetry breaking is around $7\%$ maximally.

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来源期刊

Turkish Journal of Physics PHYSICS, MULTIDISCIPLINARY-

CiteScore

3.50

自引率

0.00%

发文量

期刊介绍： The Turkish Journal of Physics is published electronically 6 times a year by the Scientific and Technological Research Council of Turkey (TÜBİTAK) and accepts English-language manuscripts in various fields of research in physics, astrophysics, and interdisciplinary topics related to physics. Contribution is open to researchers of all nationalities.