Shen712 said:
The composition of the π0 is (uu_bar - dd_bar/√2; while the composition of the η meson is (uu_bar + dd_bar)/√2. Why is there a - sign in π0 while is there a + sign in η? How are the signs determined?
By the way, can I type Latex symbols on this site? I tried to type the anti up quark by typing \overline{u}, but it did not show what I wanted. How should I type it?
Where is the [itex]s \bar{s}[/itex] component of your [itex]\eta[/itex]? Scalar mesons (i.e., the [itex]J^{P} = 0^{-}[/itex] representation of the Lorentz group) contain 2 [itex]\eta[/itex]-particles: the [itex]T = S = 0[/itex] member of the [itex]SU(3)[/itex] octet, usually denoted by [itex]\eta_{8}[/itex] and having the quarks content [tex]\eta_{8} = \frac{1}{\sqrt{6}} (u \bar{u} + d \bar{d} - 2 s \bar{s}) ,[/tex] and there is the [itex]SU(3)[/itex] singlet (invariant) state [tex]\eta_{1} = \frac{1}{\sqrt{3}} \sum_{i = u,d,s} q^{i} \ \bar{q}_{i} = \frac{1}{\sqrt{3}} (u \bar{u} + d \bar{d} + s \bar{s}) \ .[/tex] The exact quark content follows from the [itex]SU(3)[/itex] decomposition [itex]3 \otimes \bar{3} = 8 \oplus 1[/itex], which you can represent as follow [tex]q^{i} \bar{q}_{j} = \left( q^{i} \bar{q}_{j} - \frac{1}{3} \delta^{i}_{j} \sum_{k = u,d,s} q^{k} \bar{q}_{k}\right) + \frac{1}{3} \delta^{i}_{j} \sum_{k} q^{k}\bar{q}_{k} \ .[/tex] The first term on the right hand side is the [itex]3 \times 3[/itex] traceless hermitian mesons matrix [tex]\{8\}^{i}_{j} = q^{i} \bar{q}_{j} - \frac{1}{3} \delta^{i}_{j} \sum_{k = u,d,s} q^{k} \bar{q}_{k} \ .[/tex] For the [itex]0^{-}[/itex] (i.e., scalar) mesons, the off-diagonal matrix elements are easily recognised, for example [itex]\{8\}^{2}_{3} = d \bar{s} = K^{0} \ , \{8\}^{3}_{1} = s \bar{u} = K^{-}[/itex] and the two charged pions [itex]\{8\}^{1}_{2} = u \bar{d} = \pi^{+} \ , \{8\}^{2}_{1} = d \bar{u} = \pi^{-}[/itex]. Now, before considering the diagonal elements of the [itex]SU(3)[/itex] meson matrix [itex]\{8\}^{i}_{j}[/itex], and in order to settle the sign issue for [itex]\pi^{0}[/itex], let us repeat the same thing for the iso-spin group [itex]SU(2)[/itex]. That is decomposing the tensor product [itex]2 \otimes 2 = 3 \oplus 1[/itex] by subtracting the [itex]SU(2)[/itex]-invariant trace. So, in terms of quarks [tex]q^{m} \bar{q}_{n} = \left( q^{m} \bar{q}_{n} - \frac{1}{2} \delta^{m}_{n} \sum_{l = u,d} q^{l}\bar{q}_{l} \right) + \frac{1}{2} \delta^{m}_{n} \sum_{l = u,d} q^{l} \bar{q}_{l} \ .[/tex] From this we identify the triplet (i.e., iso-spin one) pion states which are contained in the matrix [itex]\{3\}^{m}_{n}[/itex]:[tex]\pi^{+} = |1 , +1\rangle = \{3\}^{1}_{2} = u \bar{d} \ ,[/tex][tex]\pi^{0} = |1 , 0 \rangle = \sqrt{2} \{3\}^{1}_{1} = \frac{1}{\sqrt{2}} (u \bar{u} - d \bar{d}) \ ,[/tex][tex]\pi^{-} = |1 , -1 \rangle = \{3\}^{2}_{1} = d \bar{u} \ .[/tex] Now, you know the exact form of [itex]\pi^{0}[/itex] state, go back to consider the diagonal elements of the [itex]SU(3)[/itex] matrix [itex]\{8\}^{i}_{j}[/itex]: [tex]\{8\}^{1}_{1} = u \bar{u} - \frac{1}{3} \sum_{j = u,d,s} q^{j}\bar{q}_{j} = \frac{1}{\sqrt{2}} \pi^{0} + \frac{1}{6} \left( u \bar{u} + d \bar{d} - 2 s \bar{s} \right) \ ,[/tex] [tex]\{8\}^{2}_{2} = - \frac{1}{\sqrt{2}} \pi^{0} + \frac{1}{6} \left( u \bar{u} + d \bar{d} - 2 s \bar{s} \right) \ ,[/tex][tex]\{8\}^{3}_{3} = - \frac{2}{6} \left( u \bar{u} + d \bar{d} - 2 s \bar{s}\right) \ .[/tex] This led to the identification of [itex]\eta_{8}[/itex] with the state [tex]\eta_{8} = \frac{1}{\sqrt{6}} \left( u \bar{u} + d \bar{d} - 2 s \bar{s}\right) \ .[/tex]