-
The effective Hamiltonian responsible for nonleptonic
$ \bar{B}^* $ decays can be written as$\begin{split} {{\cal H}_{\rm eff}} = &\frac{{{G_{\rm F}}}}{{\sqrt 2 }}\sum\limits_{p,{\kern 1pt} {p^\prime } = u,{\kern 1pt} c} {\left[ {{V_{pb}}V_{{p^\prime }q}^*\sum\limits_{i = 1}^2 {{C_i}} (\mu ){O_i}(\mu )} \right.}\\&+\left. {V_{pb}}V_{pq}^*\sum\limits_{i = 3}^{10} {{C_i}} (\mu ){O_i}(\mu ) \right] + h.c.,\end{split}$
(1) where
$ G_{\rm F} $ is the Fermi coupling constant,$ V_{pb}V^*_{p^{(\prime)}q}$ $ (q = d,\,s) $ is the product of Cabibbo-Kobayashi-Maskawa (CKM) matrix elements,$ C_{i}(\mu) $ is the Wilson coefficient and can be calculated with the perturbation theory [28, 29],$ O_i $ is local four-quark operator, and its explicit form can be found in, for instance, Refs. [28, 29].To obtain the decay amplitudes, we have to deal with the hadronic matrix elements of local operators,
$ \langle V_1V_2|O_i |B^* \rangle $ , involved in the amplitude. A simple way for this purpose is the naive factorization (NF) scheme [30-34] based on the color transparency mechanism [35, 36]. Within the NF approach, the hadronic matrix element of$ B^*\to V_1V_2 $ decay can be factorized as$H_{{\lambda _1}{\lambda _2}}^{{V_1}{V_2}} \equiv \langle {V_1}{V_2}|{Q_i}|{B^*}\rangle \simeq \langle {V_2}|{J_2}|0\rangle \langle {V_1}|{J_1}|{B^*}\rangle {\mkern 1mu} ,$
(2) where the recoil vector meson that carries away the spectator quark from B* meson is referred to as
$ V_1 $ , and the emission vector is referred to as$ V_2 $ ;$ \lambda_{1(2)} $ is the helicity of$ V_{1(2)} $ meson, and the helicity of initial B* meson satisfies$ \lambda_{B^*} = \lambda_{1}-\lambda_{2} $ . The two current matrix elements$ \langle V_2|J_2|0\rangle $ and$ \langle V_1|J_1|B^*\rangle $ in Eq. (2) can be further parameterized by the decay constant and form factors.In the framework of NF, the non-factorizable contributions dominated by the hard gluon exchange are lost. To evaluate these QCD corrections to the matrix elements and reduce the scale-dependence, the QCDF approach is explored by BBNS [37, 38]. Despite this, the NF approach is employed in this study because of the following reasons: (i) in the framework of QCDF, the amplitude obtained through NF can be treated as the leading-order (LO) contribution of the QCDF result. For the
$ b\to c $ induced tree-dominated nonleptonic$ B^{(*)} $ decays, compared with the LO contribution, the NLO and NNLO non-factorizable QCD corrections generally yield about 4% and 2% contributions [27, 38, 39], respectively. Therefore, for the$ B^*\to D^* V $ decays studied here, the NF can provide relatively reliable predictions, and the small non-factorizable QCD correction is numerically trivial before these B* decay modes are measured precisely. (ii) The QCDF approach is not suitable anymore for the case of the heavy emission meson [38], for instance,$ \bar{B}^*\to D^* \bar{D}^* $ decays.The decay constant and form factors are essential inputs for evaluating current matrix elements in Eq. (2). The former is defined as
$\langle {V_2}({\epsilon _2},{p_2})|\bar q{\gamma ^\mu }q|0\rangle = {f_{{V_2}}}{m_2}\epsilon _2^{*\mu },$
(3) where
$ m_2 $ and$ \epsilon_2 $ denote the mass and the polarization vector of the$ V_2 $ meson, respectively. The form factors for$ B^*\to V_1 $ transition are defined by [40]$\begin{split} {\langle {V_1}({\epsilon _1},{p_1})|\bar c{\gamma _\mu }b|{B^*}(\epsilon ,p)\rangle = }{\epsilon \cdot \epsilon _1^*\left[ { - {P_\mu }{{\tilde V}_1}({q^2}) + {q_\mu }{{\tilde V}_2}({q^2})} \right]}+ \frac{{(\epsilon \cdot q)(\epsilon _1^* \cdot q)}}{{m_{{B^*}}^2 - m_1^2}}\left[ {{P_\mu }{{\tilde V}_3}({q^2}) - {q_\mu }{{\tilde V}_4}({q^2})} \right] { - (\epsilon \cdot q)\epsilon _{1\mu }^*{{\tilde V}_5}({q^2}) + (\epsilon _1^* \cdot q){\epsilon _\mu }{{\tilde V}_6}({q^2}){\mkern 1mu} ,} \end{split}$
(4) $\begin{split} {\langle {V_1}({\epsilon _1},{p_1})|\bar c{\gamma _\mu }{\gamma _5}b|{B^*}(\epsilon ,p)\rangle = }{ - {\rm i}{\varepsilon _{\mu \nu \alpha \beta }}{\epsilon ^\alpha }\epsilon _1^{*\beta }}\times\left[ {{P^\nu }{{\tilde A}_1}({q^2}) - {q^\nu }{{\tilde A}_2}({q^2})} \right] { + \frac{{2{\rm i}}}{{m_{{B^*}}^2 - m_1^2}}{\epsilon _{\mu \nu \alpha \beta }}{p^\alpha }p_1^\beta} \times\left[ {{\epsilon ^\nu }(\epsilon _1^* \cdot q){{\tilde A}_3}({q^2}) - \epsilon _1^{*\nu }(\epsilon \cdot q){{\tilde A}_4}({q^2})} \right] , \end{split}$
(5) where
$ \epsilon_{0123} = -1 $ ,$ P = p+p_1 $ ,$ q = p-p_1 = p_2 $ , and$ \epsilon_{(1)} $ is the polarization vector of the$ B^*(V_1) $ meson.Subsequently, after contracting the current matrix elements, we can obtain the
$ H_{\lambda_1\lambda_2}^{V_1V_2} $ for the seven allowed helicity states of final mesons, written as$\begin{split} {H_{00}^{{V_1}{V_2}} = }&{{f_{{V_2}}}{m_2}\left[\frac{{{p_c}(m_{{B^*}}^2 + m_1^2 - m_2^2)}}{{{m_1}{m_2}}}{{\tilde V}_1} + \frac{{2m_{{B^*}}^2p_c^3}}{{(m_{{B^*}}^2 - m_1^2){m_1}{m_2}}}{{\tilde V}_3}\right.} \\&\left.- \frac{{{p_c}(m_{{B^*}}^2 - m_1^2 - m_2^2)}}{{2{m_1}{m_2}}}{{\tilde V}_5} + \frac{{{p_c}(m_{{B^*}}^2 - m_1^2 + m_2^2)}}{{2{m_1}{m_2}}}{{\tilde V}_6}\right], \end{split}$
(6) $\begin{split} {H_{ + + }^{{V_1}{V_2}} = }&{f_{{V_2}}}{m_2}{\left[\frac{{3m_{{B^*}}^2 + m_1^2 - m_2^2}}{{2{m_{{B^*}}}}}{{\tilde A}_1} - \frac{{m_{{B^*}}^2 - m_1^2 + m_2^2}}{{2{m_{{B^*}}}}}{{\tilde A}_2}\right.} \\&+ \left.\frac{{2p_c^2{m_{{B^*}}}}}{{m_{{B^*}}^2 - m_1^2}}{{\tilde A}_4} - {p_c}{{\tilde V}_5}\right] , \end{split}$
(7) $\begin{split} {H_{ - - }^{{V_1}{V_2}} = }&{f_{{V_2}}}{m_2}{\left[ - \frac{{3m_{{B^*}}^2 + m_1^2 - m_2^2}}{{2{m_{{B^*}}}}}{{\tilde A}_1} + \frac{{m_{{B^*}}^2 - m_1^2 + m_2^2}}{{2{m_{{B^*}}}}}{{\tilde A}_2}\right.}\\& \left.- \frac{{2p_c^2{m_{{B^*}}}}}{{m_{{B^*}}^2 - m_1^2}}{{\tilde A}_4} - {p_c}{{\tilde V}_5}\right] , \end{split}$
(8) $\begin{aligned} {H_{ + 0}^{{V_1}{V_2}} = }&{{f_{{V_2}}}{m_2}\left[ - \frac{{m_{{B^*}}^2 - m_1^2}}{{{m_2}}}{{\tilde A}_1} + {m_2}{{\tilde A}_2} + \frac{{2{m_{{B^*}}}{p_c}}}{{{m_2}}}{{\tilde V}_1}\right] ,} \end{aligned}$
(9) $\begin{aligned} {H_{ - 0}^{{V_1}{V_2}} = }&{{f_{{V_2}}}{m_2}\left[\frac{{m_{{B^*}}^2 - m_1^2}}{{{m_2}}}{{\tilde A}_1} - {m_2}{{\tilde A}_2} + \frac{{2{m_{{B^*}}}{p_c}}}{{{m_2}}}{{\tilde V}_1}\right] ,} \end{aligned}$
(10) $\begin{split} {H_{0 - }^{{V_1}{V_2}} = }&{f_{{V_2}}}{m_2}{\left[ - \frac{{m_{{B^*}}^2 + 3m_1^2 - m_2^2}}{{2{m_1}}}{{\tilde A}_1} + \frac{{m_{{B^*}}^2 - m_1^2 - m_2^2}}{{2{m_1}}}{{\tilde A}_2}\right.}\\& - {\left.\frac{{2p_c^2m_{{B^*}}^2}}{{(m_{{B^*}}^2 - m_1^2){m_1}}}{{\tilde A}_3} - \frac{{{p_c}{m_{{B^*}}}}}{{{m_1}}}{{\tilde V}_6}\right],} \end{split}$
(11) $\begin{split} {H_{0 + }^{{V_1}{V_2}} = }&{f_{{V_2}}}{m_2}{\left[\frac{{m_{{B^*}}^2 + 3m_1^2 - m_2^2}}{{2{m_1}}}{{\tilde A}_1} - \frac{{m_{{B^*}}^2 - m_1^2 - m_2^2}}{{2{m_1}}}{{\tilde A}_2}\right.} \\&+ \left.\frac{{2p_c^2m_{{B^*}}^2}}{{(m_{{B^*}}^2 - m_1^2){m_1}}}{{\tilde A}_3} - \frac{{{p_c}{m_{{B^*}}}}}{{{m_1}}}{{\tilde V}_6}\right] , \end{split}$
(12) where
$ p_c = \displaystyle\frac{\sqrt{[m_{B^*}^2-(m_{1}+m_{2})^2][m_{B^*}^2-(m_{1}-m_{2})^2]}}{2m_{B^*}} $ .Using the formulas given above, we can finally obtain helicity amplitudes of tree-dominated
$ {\bar{B}_{u,d,s}^*} \to D_{u,d,s}^{*}V $ $ (V = D^{*-},{D}_s^{*-},{K}^{*-}, \rho^-) $ decays, which can be written as$\begin{aligned} {{\cal A}({B^{* - }} \to {D^{*0}}{K^{* - }}) = }&{\frac{{{G_F}}}{{\sqrt 2 }}[H_{{\lambda _{{D^*}}}{\lambda _{{K^*}}}}^{{D^*}{K^*}}{V_{cb}}V_{us}^*{\alpha _1} \!+\! H_{{\lambda _{{K^*}}}{\lambda _{{D^*}}}}^{{K^*}{D^*}}{V_{cb}}V_{us}^*{\alpha _2}]{\mkern 1mu} ,} \end{aligned}$
(13) $\begin{aligned} {{\cal A}({B^{* - }} \to {D^{*0}}{\rho ^ - }) = }&{\frac{{{G_F}}}{{\sqrt 2 }}[H_{{\lambda _{{D^*}}}{\lambda _\rho }}^{{D^*}\rho }{V_{cb}}V_{ud}^*{\alpha _1} \!+\! H_{{\lambda _\rho }{\lambda _{{D^*}}}}^{\rho {D^*}}{V_{cb}}V_{ud}^*{\alpha _2}]{\mkern 1mu} ,} \end{aligned}$
(14) $\begin{split} {{\cal A}({B^{* - }} \to {D^{*0}}{D^{* - }}) = }&{\frac{{{G_F}}}{{\sqrt 2 }}H_{{\lambda _{{D^{*0}}}}{\lambda _{{D^{* - }}}}}^{{D^{*0}}{D^{* - }}}[{V_{cb}}V_{cd}^*({\alpha _1} + {\alpha _4} }\\&+ {\alpha _{4,EW}}) + {V_{ub}}V_{ud}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(15) $\begin{split} {{\cal A}({B^{* - }} \to {D^{*0}}D_s^{* - }) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{{D^*}}}{\lambda _{D_s^*}}}^{{D^*}D_s^*}[{V_{cb}}V_{cs}^*({\alpha _1}+ {\alpha _4} + {\alpha _{4,EW}}) }\\& + {V_{ub}}V_{us}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(16) $\begin{aligned} {{\cal A}({{\bar B}^{*0}} \to {D^{* + }}{K^{* - }}) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{{D^*}}}{\lambda _{{K^*}}}}^{{D^*}{K^*}}{V_{cb}}V_{us}^*{\alpha _1}{\mkern 1mu} ,} \end{aligned}$
(17) $\begin{aligned} {{\cal A}({{\bar B}^{*0}} \to {D^{* + }}{\rho ^ - }) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{{D^*}}}{\lambda _\rho }}^{{D^*}\rho }{V_{cb}}V_{ud}^*{\alpha _1}{\mkern 1mu} ,} \end{aligned}$
(18) $\begin{split} {{\cal A}({{\bar B}^{*0}} \to {D^{* + }}{D^{* - }}) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{{D^{* + }}}}{\lambda _{{D^{* - }}}}}^{{D^{* + }}{D^{* - }}}[{V_{cb}}V_{cd}^*({\alpha _1} + {\alpha _4} + {\alpha _{4,EW}}) }\\&+ {V_{ub}}V_{ud}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(19) $\begin{split} {{\cal A}({{\bar B}^{*0}} \to {D^{* + }}D_s^{* - }) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{{D^*}}}{\lambda _{D_s^*}}}^{{D^*}D_s^*}[{V_{cb}}V_{cs}^*({\alpha _1} + {\alpha _4} + {\alpha _{4,EW}})}\\& + {V_{ub}}V_{us}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(20) $\begin{aligned} {{\cal A}(\bar B_s^{*0} \to D_s^{* + }{K^{* - }}) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{D_s^*{K^*}}}}^{D_s^*{K^*}}{V_{cb}}V_{us}^*{\alpha _1}{\mkern 1mu} ,} \end{aligned}$
(21) $\begin{aligned} {{\cal A}(\bar B_s^{*0} \to D_s^{* + }{\rho ^ - }) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{D_s^*}}{\lambda _\rho }}^{D_s^*\rho }{V_{cb}}V_{ud}^*{\alpha _1}{\mkern 1mu} ,} \end{aligned}$
(22) $\begin{split} {{\cal A}(\bar B_s^{*0} \to D_s^{* + }{D^{* - }}) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{D_s^*}}{\lambda _{{D^*}}}}^{D_s^*{D^*}}[{V_{cb}}V_{cd}^*({\alpha _1} + {\alpha _4} + {\alpha _{4,EW}})}\\& + {V_{ub}}V_{ud}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(23) $\begin{split} {{\cal A}(\bar B_s^{*0} \to D_s^{* + }D_s^{* - }) = }&{\frac{{{G_{\rm F}}}}{{\sqrt 2 }}H_{{\lambda _{D_s^{* + }}}{\lambda _{D_s^{* - }}}}^{D_s^{* + }D_s^{* - }}[{V_{cb}}V_{cs}^*({\alpha _1} + {\alpha _4} + {\alpha _{4,EW}})}\\& + {V_{ub}}V_{us}^*({\alpha _4} + {\alpha _{4,EW}})] , \end{split}$
(24) where
$ \alpha_1 = C_1+\displaystyle\frac{C_2}{N_c} $ ,$ \alpha_2 = C_2+\displaystyle\frac{C_1}{N_c} $ ,$ \alpha_4 = C_4+v\displaystyle\frac{C_3}{N_c} $ and$ \alpha_{4,EW} = C_{10}+\displaystyle\frac{C_9}{N_c} $ are effective coefficients, and$ N_c = 3 $ denotes the number of colors.Using the helicity amplitudes given above, one can further obtain the branching fraction of
$ B^*\to D^* V $ decay, defined as${\cal B}({B^*} \to {D^*}V) = \frac{1}{3}\frac{1}{{8\pi }}\frac{{{p_c}}}{{m_{{B^*}}^2{\Gamma _{{\rm{tot}}}}({B^*})}}\sum\limits_{{\lambda _{{B^*}}}{\lambda _{{D^*}}}{\lambda _V}} | A({B^*} \to {D^*}V){|^2},$
(25) where
$ {\Gamma}_{\rm tot}(B^*) $ is the total decay width of B* meson, and the factor 1/3 is caused by averaging over the spins of the initial state. -
Using the theoretical formulas provided in the last section, we present our numerical evaluation and discussions. First, we would like to clarify the values of inputs used in our numerical calculation. For the well-known Fermi coupling constant
$ G_{\rm F} $ and the masses of mesons, we take their central values given by PDG [3]. For the CKM matrix elements, we adopt the Wolfenstein parameterization, and the four parameters A,$ \lambda $ ,$ \rho $ and$ \eta $ are as follows [3]$\begin{split} A =& 0.836_{ - 0.015}^{ + 0.015}{\mkern 1mu} ,\quad \lambda = 0.22453_{ - 0.00044}^{ + 0.00044}{\mkern 1mu} ,\\\bar \rho =& 0.122_{ - 0.017}^{ + 0.018}{\mkern 1mu} ,\quad \bar \eta = 0.355_{ - 0.011}^{ + 0.012}{\mkern 1mu} .\end{split}$
(26) Using these inputs, we can easily obtain the values of CKM elements relevant to this work,
$ V_{ud} = $ $ 0.97448^{+0.00010}_{-0.00010} $ ,$ V_{us} = {0.22453}^{+0.00044}_{-0.00044} $ ,$ V_{ub} = 0.00122^{+0.00018}_{-0.00017}- $ ${\rm i}\, 0.00354^{+0.00014}_{-0.00013} $ ,$ V_{cd}\!\! =\!\! -0.22438^{+0.00044}_{-0.00044}-{\rm i}\, 0.00015^{+0.00001}_{-0.00001} $ ,$ V_{cs} \!\!=\!\! 0.97359^{+0.00010}_{-0.00010} $ , and$ V_{cb} = 0.04215^{+0.00077}_{-0.00077} $ at the level of$ {\cal O}(\lambda^5) $ . For the decay constants of emission mesons, we assume their values extracted from experimental data and predicted by lattice QCD$\begin{split} {f_{{D^*}}} =& 223.5 \pm 8.4{\mkern 1mu} {\rm{MeV}}\;[{\rm{41}}]{\mkern 1mu} , \quad {f_{{D}_{\rm{s}}^{\rm{*}}}}{\rm{ = 268}}.{\rm{8}} \pm {\rm{6}}.{\rm{6}}{\mkern 1mu} {\rm{MeV}}\;[{\rm{41}}]{\mkern 1mu} ,\\ {f_{{K^*}}} =& 204 \pm 7{\mkern 1mu} {\rm{MeV}}\;[{\rm{42}}]{\mkern 1mu} ,\quad {f_\rho }{\rm{ = 210}} \pm {\rm{4}}{\mkern 1mu} {\rm{MeV}}\;[{\rm{43}}]{\mkern 1mu} . \end{split}$
(27) The total decay width of the B* meson represents the essential input for evaluating the branching fraction, however, there is currently no available experimental result. Based on the fact that the radiative process
$ B^*\to B\gamma $ dominates the decays of the B* meson [3], we can take the approximation that$ \Gamma_{\rm tot}(B^*)\simeq \Gamma(B^*\to B\gamma) $ . The predictions for$ \Gamma(B^*\to B\gamma) $ have been obtained in various theoretical models [44-50]. In this study, the light-front quark model (LFQM) is employed to evaluate$ \Gamma(B^*\to B\gamma) $ . The relevant theoretical formulas have been obtained in Ref. [49]. Using the values of the Gaussian parameter$ \beta $ given in Refs. [51, 52], we can obtain the updated LFQM predictions for$ \Gamma(B^*\to B\gamma) $ as follows$\begin{array}{*{20}{l}} {{\Gamma _{{\rm{tot}}}}({B^{* - }})}{ \simeq \Gamma ({B^{* - }} \to {B^ - }\gamma ) = (349 \pm 18){\mkern 1mu} {\rm{eV}},} \end{array}$
(28) $\begin{array}{*{20}{l}} {{\Gamma _{{\rm{tot}}}}({{\bar B}^{*0}})}{ \simeq \Gamma ({{\bar B}^{*0}} \to {{\bar B}^0}\gamma ) = (116 \pm 6){\mkern 1mu} {\rm{eV}},} \end{array}$
(29) $\begin{array}{*{20}{l}} {{\Gamma _{{\rm{tot}}}}(\bar B_s^*)}{ \simeq \Gamma (\bar B_s^* \to {{\bar B}_s}\gamma ) = (84_{ - 9}^{ + 11}){\mkern 1mu} {\rm{eV}},} \end{array}$
(30) which agree with the ones obtained in previous works [44-50].
Besides the input parameters given above, the transition form factors
$ \tilde V_{1-6}^{B^*\to V_1}(m_2^2) $ ,$ \tilde A_{1- 4}^{B^*\to V_1}(m_2^2) $ are also essential ingredients for the estimation of certain nonleptonic B* decay. However, there is currently no available result. In this work, we adopt the CLFQM [53–55] to evaluate their values. Our theoretical results for$ \tilde V_{1-6}(q^2) $ and$ \tilde A_{1-4}(q^2) $ defined by Eqs. (4) and (5) are given explicitly in the appendix. The convenient Drell-Tan-West frame,$ q^{+} = 0 $ , is used in the CLFQM [53–55]. This implies that the form factors are known only for space-like momentum transfer, because$ q^2 = -{q}_\bot^2\leqslant 0 $ , using the formulas given in the appendix. Meanwhile, the ones in the time-like region need an additional$ q^2 $ extrapolation. The momentum dependences of form factors in the space-like region can be efficiently parameterized and reproduced via the three parameter form (dipole approximation),$F({q^2}) = \frac{{F(0)}}{{1 - a{\mkern 1mu} ({q^2}/m_{{B^*}}^2) + b{\mkern 1mu} {{({q^2}/m_{{B^*}}^2)}^2}}}{\mkern 1mu} ,$
(31) where,
$ F = \tilde V_{1-6} $ and$ \tilde A_{1- 4} $ . The parameters a, b, and$ F(0) $ can be first determined in the space-like region. Subsequently, we employ these results to evaluate$ F(q^2) $ at$ q^2\geqslant 0 $ via Eq. (31). Using the best-fit values of constituent quark masses and Gaussian parameter obtained in Refs. [51, 52], we provide our numerical results for the form factors of$ {B}^{*}\to (D^{*},\,K^*,\,\rho) $ and$ {B}^{*}_{s}\to D^{*}_s $ transitions in Table 1. In the following numerical calculation, these values and their 10% are treated as default inputs and uncertainties, respectively.$ F^{B^* \to D^*}(0) $ a b $ F^{B^* \to K^*}(0) $ a b $ F^{B^* \to \rho}(0) $ a b $ F^{B_s^* \to D_s^*}(0) $ a b $ \tilde A_1 $ 0.66 1.31 0.42 0.33 1.75 0.89 0.27 1.79 0.97 0.65 1.42 0.64 $ \tilde A_2 $ 0.35 1.32 0.42 0.27 1.75 0.88 0.25 1.80 0.97 0.38 1.47 0.67 $ \tilde A_3 $ 0.07 1.79 1.10 0.07 2.28 2.20 0.07 2.39 2.37 0.10 1.89 1.33 $ \tilde A_4 $ 0.08 1.81 1.15 0.07 2.29 2.33 0.06 2.35 2.46 0.09 1.88 1.36 $ \tilde V_1 $ 0.67 1.31 0.43 0.33 1.74 0.96 0.28 1.79 0.01 0.66 1.43 0.64 $ \tilde V_2 $ 0.36 1.32 0.42 0.27 1.74 0.95 0.25 1.80 1.02 0.38 1.48 0.67 $ \tilde V_3 $ 0.13 1.72 1.01 0.11 2.16 2.04 0.11 2.23 2.16 0.15 1.79 1.20 $ \tilde V_4 $ 0.00 –0.08 1.24 –0.01 2.91 4.24 –0.03 2.77 3.74 –0.02 2.22 1.92 $ \tilde V_5 $ 1.17 1.30 0.40 0.68 1.71 0.90 0.60 1.76 0.95 1.19 1.41 0.61 $ \tilde V_6 $ 0.48 1.29 0.40 0.16 1.67 0.81 0.14 1.70 0.82 0.53 1.35 0.56 Table 1. Form factors of
$ {B}^{*}\to (D^{*},\,K^*,\,\rho) $ and$ {B}^{*}_{s}\to D^{*}_s $ transitions in CLFQM.Using theoretical formulas given in the last section and the inputs given above, we present our predictions for the branching fractions of
$ \bar{B}^{*}_q\to D^{*}_q V $ decays in Table 2, where the first theoretical error is caused by the uncertainties of CKM parameters, decay constants, and total decay width. The second theoretical error, in turn, is caused by the form factors. Moreover, to clearly show the relative strength of each helicity amplitude, we list the numerical results for the helicity fraction defined asDecay mode $ {\cal B}\, $ $ f_{00} $ $ f_{ - - } $ $ f_{++} $ $ f_{-0} $ $ f_{+0} $ $ f_{0-} $ $ f_{0+} $ $ {B}^{*-} \to D^{*0} K^{*-} $ $ 1.10^{+0.01+0.19}_{-0.01-0.17}\times10^{-9} $ 24.4 4.5 0.3 69.2 0.0 1.4 0.2 $ {B}^{*-} \to D^{*0} \rho^{-} $ $ 2.23^{+0.04+0.39}_{-0.04-0.35}\times10^{-8} $ 24.1 3.3 0.2 71.0 0.0 1.2 0.2 $ {B}^{*-} \to D^{*0} D^{*-} $ $ 1.44^{+0.11+0.24}_{-0.11-0.22}\times10^{-9} $ 12.9 13.1 1.8 56.6 0.4 13.8 1.5 $ {B}^{*-} \to D^{*0} D_s^{*-} $ $ 3.71^{+0.18+0.64}_{-0.18-0.57}\times10^{-8} $ 12.1 14.1 2.0 54.8 0.5 14.7 1.8 $ \bar{B}^{*0} \to D^{*+} K^{*-} $ $ 3.40^{+0.24+0.58}_{-0.23-0.52}\times10^{-9} $ 19.7 3.2 0.3 73.2 0.0 3.4 0.2 $ \bar{B}^{*0} \to D^{*+} \rho^- $ $ 6.85^{+0.26+1.17}_{-0.26-1.05}\times10^{-8} $ 20.1 2.5 0.2 74.4 0.0 2.6 0.2 $ \bar{B}^{*0} \to D^{*+} D^{*-} $ $ 4.33^{+0.33+0.74}_{-0.32-0.66}\times10^{-9} $ 12.9 13.1 1.8 56.6 0.4 13.8 1.5 $ \bar{B}^{*0} \to D^{*+} D_s^{*-} $ $ 1.11^{+0.06+0.19}_{-0.05-0.17}\times10^{-7} $ 12.1 14.1 2.0 54.8 0.5 14.7 1.8 $ \bar{B}_s^{*0} \to D_s^{*+} K^{*-} $ $ 4.80^{+0.34+0.83}_{-0.32-0.74}\times10^{-9} $ 20.2 3.2 0.3 72.7 0.0 3.5 0.2 $ \bar{B}_s^{*0} \to D_s^{*+} \rho^- $ $ 9.39^{+0.36+1.63}_{-0.35-1.46}\times10^{-8} $ 20.4 2.5 0.2 74.1 0.0 2.7 0.2 $ \bar{B}_s^{*0} \to D_s^{*+} D^{*-} $ $ 6.10^{+0.47+1.03}_{-0.45-0.92}\times10^{-9} $ 13.3 13.0 1.7 56.2 0.3 14.1 1.4 $ \bar{B}_s^{*0} \to D_s^{*+} D_s^{*-} $ $ 1.54^{+0.08+0.26}_{-0.07-0.24}\times10^{-7} $ 12.9 13.9 1.9 54.4 0.4 15.1 1.5 Table 2. Branching fractions and helicity fractions (%) of
$ \bar{B}^{*}_q\to D^{*}_q V $ decays.${f_{{\lambda _1}{\lambda _2}}}(\bar B_q^* \to D_q^*V) = \frac{{{{\left| {{{\cal A}_{{\lambda _1}{\lambda _2}}}(\bar B_q^* \to D_q^*V)} \right|}^2}}}{{\displaystyle\sum\nolimits_{{\lambda _1},{\lambda _2}} {{{\left| {{{\cal A}_{{\lambda _1}{\lambda _2}}}(\bar B_q^* \to D_q^*V)} \right|}^2}} }}$
(32) in Table 2. The following are some discussions.
From Table 2, there is a very clear hierarchy of the branching fractions indicating that
$ {\cal B}(\bar{B}^*_q\!\to\! D^*_q\rho^-)\!>\!{\cal B}(\bar{B}^*_q\!\to\! $ $D^*_qK^{*-}) $ and$ {\cal B}(\bar{B}^*_q\to D^*_qD_s^{*-})>{\cal B}(\bar{B}^*_q\to D^*_qD^{*-}) $ , which is mainly caused by CKM factors$V_{cb}V_{ud}:V_{cb}V_{us}\approx $ $ V_{cb}V_{cs}:V_{cb}V_{cd} \approx 1/\lambda $ . Meanwhile,$ {\cal B}(\bar{B}^*_q\to D^*_qD_s^{*-})> $ ${\cal B}(\bar{B}^*_q\to D^*_q\rho^-) $ and$ {\cal B}(\bar{B}^*_q\to D^*_qD^{*-})>{\cal B}(\bar{B}^*_q\to D^*_qK^{*-}) $ because$ f_{D_s^*}>f_\rho $ and$ f_{D^*}>f_{K^*} $ , respectively. The CKM favored$ \bar{B}^*_q\to D^*_q \rho^{-} $ and$ D^*_q \bar{D}_s^* $ decays have relatively large branching fractions,$ \gtrsim {\cal O}(10^{-8}) $ , and therefore it might be possible to observe them by LHC and Belle-II experiments.The
$ \bar{B}^*\to V_LV_L $ ($ V_L $ denotes light vector meson) decay modes should have much smaller branching fraction,$ < {\cal O}(10^{-9}) $ , because they are suppressed at least by the CKM factor and relatively small form factors. They are generally out of the scope of LHC and Belle-II experiments, and thus are not considered in this study.The SU(3) flavor symmetry acting on the spectator quark requires that
${\cal A}({B^{* - }} \to {D^{*0}}V) \approx {\cal A}(\bar B_d^{*0} \to {D^{* + }}V) \approx {\cal A}(\bar B_s^{*0} \to D_s^{* + }V){\mkern 1mu} ,$
(33) which implies the relation that
$\begin{split} &{\cal B}({B^{* - }} \to {D^{*0}}V):{\cal B}(\bar B_d^{*0} \to {D^{* + }}V):{\cal B}(\bar B_s^{*0} \to D_s^{* + }V) \\&\quad\approx \frac{1}{{{\Gamma _{{\rm{tot}}}}({B^{* - }})}}:\frac{1}{{{\Gamma _{{\rm{tot}}}}({{\bar B}^{*0}})}}:\frac{1}{{{\Gamma _{{\rm{tot}}}}(\bar B_s^*)}}{\mkern 1mu} .\end{split}$
(34) From Eqs. (28)–(30) and Table 2, it can be easily found that our numerical results agree well with such relation required by the SU(3) flavor symmetry.
• There is also a clear hierarchy of helicity amplitudes for a given
$ \bar{B}^{*}_q\to D^{*}_qV $ decay. The helicity picture for the case of$ \lambda_{B^{*}} = 0 $ is similar to the case of$ \bar{B}_q\to D^{*}_qV $ decay [56–58], and the only difference is the helicity of the spectator quark. As shown in Table 3, relative to the$ (\lambda_{D^{*}},\lambda_{V}) = (0,0) $ helicity state, the contribution of the$ (-,-) $ state,$ H_{ - - } $ , is suppressed, because the b quark has to flip its spin in the interaction. For the contribution of the$ (+,+) $ state, besides of the spin flip, it is also suppressed by the$ (V-A) $ interaction, because the final quark in the$ (V-A) $ interaction appears in the "wrong'' helicity. Therefore, the helicity amplitudes,$ H_{00} $ ,$ H_{ - - } $ , and$ H_{++} $ , should satisfy the relationHelicity state $ (0,0)_1 $ $ (0,0)_2 $ $ (-,-) $ $ (+,+) $ Helicity diagram $ (V-A) $ /spin flipF/F S/F F/S S/S Helicity state $ (-,0) $ $ (+,0) $ $ (0,-) $ $ (0,+) $ Helicity diagram $ (V-A) $ /spin flipF/F S/F F/S S/S Table 3. Helicity diagrams for helicity states of
$ \bar{B}^*\to V_1 V_2 $ decay,$ (\lambda_{1},\lambda_{2}) $ . Initial B* meson is at rest and appears at the top left diagrams. S(F) denotes that the corresponding contribution of helicity state is suppressed (favored) by$ (V-A) $ interaction and/or spin flip. See text for further explanation.$\begin{array}{*{20}{l}} {|{H_{00}}|}&{ > |{H_{ - - }}|}&{ > |{H_{ + + }}|{\mkern 1mu} .} \end{array}$
(35) More explicitly, for the case of the light V meson, the relation
$ |H_{00}|:|H_{ - - }|:|H_{++}|\approx 1:2m_V/m_{B^*}:2m_Vm_{D^*}/m_{B^*}^2 $ expected in the$ \bar{B}_q\to D^{*}_qV_L $ decay [56–58] is also satisfied by the$ \bar{B}^{*}_q\to D^{*}_qV_L $ decay. For the case of the heavy V meson, the suppression caused by the spin flip is not as strong as the case of light V meson, therefore the$ f_{00} $ is relatively small. Our numerical results in Table 2 are consistent with the analyses mentioned above.Similar analyses can be further applied to the cases
$ \lambda_{B^{*}} = - $ and +. Hence, it is expected that$ |H_{-0}|>|H_{0+}| $ and$ |H_{+0}|\gtrsim|H_{0-}| $ . However, the later is not satisfied numerically, even though they follow$ |H_{+0}|:|H_{0-}|\approx m_{D^{*}}/m_{V} $ in form. This is caused by the fact that the main contributions related to$ \tilde V_1 $ and$ \tilde A_1 $ in$ H_{+0} $ , Eq. (9), almost completely cancel each other out, because$ (\tilde V_1-\tilde A_1)\lesssim {\cal O}(10^{-2}) $ is predicted by CLFQM.After making some comparisons on the helicity states:
$ (0,0) $ vs.$ (-,0) $ ,$ (-,-) $ vs.$ (0,-) $ and$ (+,+) $ vs.$ (0,+) $ in Table 3, we find that their helicity diagrams are the same except for the helicity of the spectator quark, which is trivial for analyzing the suppressions induced by the$ (V-A) $ interaction and spin flip. Therefore, it is expected that$|{H_{ - 0}}| \approx 2|{H_{00}}|{\mkern 1mu} ,\quad |{H_{0 - }}| \approx |{H_{ - - }}|{\mkern 1mu} ,\quad |{H_{0 + }}| \approx |{H_{ + + }}|{\mkern 1mu} .$
(36) The factor 2 in the first relation is because the vector state
$ |J,J_z\rangle = |1,0\rangle $ can be expanded in terms of its constituent (anti-)quark’s spin states as$ |1,0\rangle = \displaystyle\frac{1}{\sqrt{2}} \left(|\displaystyle\frac{1}{2},-\displaystyle\frac{1}{2}\rangle\right. |\displaystyle\frac{1}{2},\displaystyle\frac{1}{2}\rangle+$ $\left.|\displaystyle\frac{1}{2},\displaystyle\frac{1}{2}\rangle|\displaystyle\frac{1}{2},-\frac{1}{2}\rangle\right) $ , in which the first and second terms correspond to the B* meson, as well as the recoil vector meson, in$ (0,0)_1 $ and$ (0,0)_2 $ states (see Table 3), respectively. Meanwhile, for the B* and recoil vector mesons in the$ (-,0) $ helicity state, we have$ |1,-1\rangle = |\dfrac{1}{2},-\dfrac{1}{2}\rangle|\dfrac{1}{2},-\dfrac{1}{2}\rangle $ . Therefore, the contribution of$ (0,0)\approx(0,0)_1 $ helicity state receives an additional factor 1/2 relative to the contribution of the$ (-,0) $ state. The effect of such a normalization factor results in a significant difference between the$ B^{*} \to VV $ and$ B \to VV $ decay modes, where the former is dominated by the$ (-,0) $ state, whereas the latter is dominated by the$ (0,0) $ state.The findings given by Eq. (36) can be easily confirmed by our numerical results listed in Table 2. Taking
$ \bar{B}^{*0} \to D^{*+} K^{*-} $ decay as an example, we obtain$ \begin{split} &|{H_{ - 0}}|:|{H_{00}}| = 1.93\;{\rm{vs}}.\;2{\mkern 1mu} ,\quad |{H_{0 - }}|:|{H_{ - - }}| = 1.03\;{\rm{vs}}.\;1,\\& |{H_{0 + }}|:|{H_{ + + }}| = 0.89\;{\rm{vs}}.\;1{\mkern 1mu} ,\end{split}$
(37) where, for the two values in each relation, the former is our numerical result, and the latter is the expectation of Eq. (36).
Combining the findings given above, we can finally conclude the hierarchy of contributions of helicity states as follows:
$\begin{array}{*{20}{l}} {|{H_{ - 0}}| \approx 2|{H_{00}}|}&{ > |{H_{0 - }}| \approx |{H_{ - - }}|}&{ > |{H_{0 + }}| \approx |{H_{ + + }}|{\mkern 1mu} .} \end{array}$
(38) -
Using the theoretical formalism of the CLFQM detailed in Refs. [53–55], we obtain the form factors of the
$ V'\to V'' $ transition written as$\tag{A1} \begin{split} {{{\tilde A}_1}({q^2}) = }&\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}( - 4)\left[ - 2A_1^{(2)} + \frac{1}{4}({m'_1}^2 + {m''_1}^2 - {q^2}\right. \\ &+ \hat N_1^\prime + \hat N_1^{\prime \prime }) - \frac{1}{2}{m'_1}{m''_1}+ {A_1^{(1)}\left(m_2^2 - \frac{{{{M'}^2} + {{M''}^2}}}{2} + \frac{1}{2}{q^2} + {m'_1}{m''_1} \right.}\\ &- {m'_1}{m_2} - {m''_1}{m_2}\bigg)+ {\left.\left(\frac{1}{{{D_{V'}}}} + \frac{1}{{{D_{V''}}}}\right)({m'_1} + {m''_1})A_1^{(2)}\right] ,} \end{split}$
(A1) $\tag{A2} \begin{split} {{{\tilde A}_2}({q^2}) = }&{\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}4\left[{m'_1}{m_2} - \frac{1}{2}{m'_1}{m''_1} - \frac{1}{4}({m'_1}^2 + {m''_1}^2\right.}\\& - {q^2} + \hat N_1^\prime + \hat N_1^{\prime \prime }) + {\frac{x}{2}({{M'}^2} + {{M''}^2} - {q^2}) - \frac{{{k_ \bot } \cdot {q_ \bot }}}{{2{q^2}}}({{M'}^2} - {{M''}^2} - {q^2}) }\\&+ A_1^{(2)}\frac{{{{M'}^2} - {{M''}^2}}}{{{q^2}}} + {A_2^{(1)}\bigg(m_2^2 - \frac{{{{M'}^2} + {{M''}^2}}}{2} + {Z_2} + \frac{1}{2}{q^2} + {m'_1}{m''_1}}\\& - {m'_1}{m_2}\! -\! {m''_1}{m_2}\bigg) \!+\! {\left(\frac{{ - {m'_1}\! +\! {m''_1}\! -\! 2{m_2}}}{{{D_{V'}}}} + \frac{{ - {m'_1} \!+\! {m''_1} \!+\! 2{m_2}}}{{{D_{V''}}}}\right)A_1^{(2)}\bigg] ,} \end{split}$
(A2) $\tag{A3}\begin{split} {{{\tilde A}_3}({q^2}) = }&{\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}( - 4)({{M'}^2} - {{M''}^2})\bigg[(A_4^{(2)} + A_1^{(1)} - A_2^{(2)} - A_2^{(1)})}\\ &+{\frac{{{m'_1}}}{{{D_{V''}}}}( - A_4^{(2)} - 2A_3^{(2)} - A_2^{(2)} + 2A_2^{(1)} + 2A_1^{(1)} - 1) + \frac{{{m''_1}}}{{{D_{V''}}}}( - A_4^{(2)}}\\& + A_2^{(2)} + A_2^{(1)} - A_1^{(1)}) +{\frac{{2{m_2}}}{{{D_{V''}}}}(A_3^{(2)} + A_2^{(2)} - A_1^{(1)}) }\\&+ \frac{2}{{{D_{V'}}{D_{V''}}}}( - A_2^{(3)} - A_1^{(3)} + A_1^{(2)})\bigg] , \end{split}$
(A3) $\tag{A4}\begin{split} {{{\tilde A}_4}({q^2}) = }&{\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}4({{M'}^2} - {{M''}^2})\bigg[( - A_4^{(2)} - A_1^{(1)} + A_2^{(2)} + A_2^{(1)})}\\ &+{\frac{{{m'_1}}}{{{D_{V'}}}}(A_4^{(2)} - A_2^{(2)} - A_2^{(1)} + A_1^{(1)}) + \frac{{{m''_1}}}{{{D_{V'}}}}(A_4^{(2)} - 2A_3^{(2)} + A_2^{(2)})}\\& + \frac{{2{m_2}}}{{{D_{V'}}}}(A_3^{(2)} - A_2^{(2)}) + {\frac{2}{{{D_{V'}}{D_{V''}}}}(A_1^{(3)} - A_2^{(3)})\bigg]{\mkern 1mu} ,} \end{split}$
(A4) $\tag{A5}\begin{split} {{{\tilde V}_1}({q^2}) = }&{\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}( - 1)\bigg\{ [ - 16A_1^{(3)} - 2f(x,{k_ \bot },{q_ \bot })}\\& - 4x({m'_1} + {m''_1}){m_2}] + {\frac{4}{{{D_{V'}}}}[{m'_1}(4A_1^{(3)} - A_1^{(2)}) + {m''_1}A_1^{(2)} + 4{m_2}A_1^{(3)}]}\\& + \frac{4}{{{D_{V''}}}}[{m'_1}A_1^{(2)} + {m''_1}(4A_1^{(3)} - A_1^{(2)}) + {4{m_2}A_1^{(3)}]}\\& + \frac{8}{{{D_{V'}}{D_{V''}}}}f(x,{k_ \bot },{q_ \bot })A_1^{(2)}\bigg\}, \end{split}$
(A5) $\tag{A6}\begin{split} {{{\tilde V}_2}({q^2}) = }&{\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}\Bigg\{ - 16A_2^{(3)} + 8A_1^{(2)} - {m'_1}^2 + {m''_1}^2 - 2m_2^2 - {q^2}}\\& + 2{{M'}^2} - 2{Z_2} - \hat N_1^\prime + {\hat N_1^{\prime \prime } - 2{m'_1}{m''_1} + 4{m'_1}{m_2} + 4A_2^{(1)}\bigg(m_2^2}\\& - \frac{{{{M'}^2} + {{M''}^2}}}{2}+ \frac{1}{2}{q^2} + {m'_1}{m''_1} - {m'_1}{m_2} - {m''_1}{m_2}\bigg) + {4\bigg(A_2^{(1)}{Z_2}}\\& + \frac{{{{M'}^2} - {{M''}^2}}}{{{q^2}}}A_1^{(2)}\bigg) + 16 \left(\frac{{{m'_1} + {m_2}}}{{{D_{V'}}}} + \frac{{{m''_1} + {m_2}}}{{{D_{V''}}}}\right)A_2^{(3)} \\&+ 4 \left(\frac{{ - 3{m'_1} + {{m''}_1} - 2{m_2}}}{{{D_{V'}}}} + \frac{{ - {m'_1} - {m''_1} - 2{m_2}}}{{{D_{V''}}}}\right)A_1^{(2)}\\& - \left(m_2^2 - \frac{{{{M'}^2} + {{M''}^2}}}{2} + \frac{1}{2}{q^2} + {m'_1}{m''_1} - {m'_1}{m_2} - {m''_1}{m_2}\right)\\&\times\frac{{16}}{{{D_{V'}}{D_{V''}}}} {A_2^{(3)} - \frac{{16}}{{{D_{V'}}{D_{V''}}}}\left[A_2^{(3)}{Z_2} + \frac{{{{M'}^2} - {{M''}^2}}}{{3{q^2}}}{{(A_1^{(2)})}^2}\right]} \\&+ ({m'_1}^2 - {m''_1}^2 + 2m_2^2 + {q^2} - 2{{M'}^2} + \hat N_1^\prime - \hat N_1^{\prime \prime } + 2{{m'}_1}{m''_1} \\&- 4{m'_1}{m_2})\frac{4}{{{D_{V'}}{D_{V''}}}}A_1^{(2)} + \frac{8}{{{D_{V'}}{D_{V''}}}}A_1^{(2)}{Z_2}\Bigg\} , \end{split}$
(A6) $\tag{A7}\begin{split} {{\tilde V}_3}({q^2}) = &\frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}({{M'}^2} - {{M''}^2})\Bigg\{ 8x(A_2^{(2)} - A_4^{(2)} + A_2^{(1)} - A_1^{(1)}) \\&+ \frac{4}{{{D_{V'}}}}[{m'_1}(1 - 2x)(A_2^{(2)} - A_4^{(2)} + A_2^{(1)} - A_1^{(1)}) + {m''_1}(A_2^{(2)} + A_4^{(2)} - 2A_3^{(2)}) \\&+ {m_2}x(2A_4^{(2)} - 2A_2^{(2)} + A_1^{(1)} - A_2^{(1)})]\\ &+\frac{4}{{{D_{V''}}}}[{m'_1}(A_2^{(2)} + 2A_3^{(2)} + A_4^{(2)} - 2A_2^{(1)} - 2A_1^{(1)} + 1) \\&+ {m''_1}(1 - 2x)(A_2^{(2)} - A_4^{(2)} + A_2^{(1)} - A_1^{(1)})\\ &+2{m_2}(2A_5^{(3)} - 2A_3^{(3)} + A_2^{(2)} - 3A_3^{(2)} + A_1^{(1)})]\\ &-\frac{8}{{{D_{V'}}{D_{V''}}}}(A_2^{(2)} - A_4^{(2)} + A_2^{(1)} - A_1^{(1)})f(x,{k_ \bot },{q_ \bot })\Bigg\} , \end{split}$
(A7) $\tag{A8}\begin{split} {{\tilde V}_4}({q^2}) =& \frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}({{M''}^2} - {{M'}^2})\bigg\{ 8(2A_4^{(3)} - 2A_6^{(3)} - 2A_3^{(2)} \\&+ 3A_4^{(2)} + A_1^{(1)} - A_2^{(1)} - A_2^{(2)}) + 4\frac{{{m'_1}}}{{{D_{V'}}}}( - 4A_4^{(3)} + 4A_6^{(3)} + 4A_3^{(2)} + 3A_2^{(2)} \\&- 7A_4^{(2)} - 3A_1^{(1)} + 3A_2^{(1)}) + 4\frac{{{m''_1}}}{{{D_{V'}}}}(2A_3^{(2)} - A_4^{(2)} - A_2^{(2)})\\& + 8\frac{{{m_2}}}{{{D_{V'}}}}( - 2A_4^{(3)} + 2A_6^{(3)} + A_3^{(2)} + A_2^{(2)} - 2A_4^{(2)}) \\&+ 4\frac{{{m'_1}}}{{{D_{V''}}}}(1 - 2A_1^{(1)} - 2A_2^{(1)} + A_2^{(2)} + 2A_3^{(2)} + A_4^{(2)})\\& + 4\frac{{{m''_1}}}{{{D_{V''}}}}( - A_1^{(1)} + 2A_2^{(1)} + A_2^{(2)} + 4A_3^{(2)} + 4A_6^{(3)} - 4A_4^{(3)} - 5A_4^{(2)}) \\&+ 8\frac{{{m_2}}}{{{D_{V''}}}}( - A_1^{(1)} + 2A_2^{(1)} + A_2^{(2)} + A_3^{(2)} + 2A_6^{(3)} - 2A_4^{(3)} - 4A_4^{(2)}) \\&+ \frac{{16}}{{{D_{V'}}{D_{V''}}}}( - A_3^{(2)} + A_4^{(2)} + A_4^{(3)} - A_6^{(3)})\bigg(m_2^2 - \frac{{{{M'}^2} + {{M''}^2}}}{2}\\& + \frac{1}{2}{q^2} + {m'_1}{m''_1} + {m'_1}{m_2} + {m''_1}{m_2}\bigg) - \frac{8}{{{D_{V'}}{D_{V''}}}}(A_2^{(1)} - 3A_4^{(2)} \\&+ 2A_6^{(3)}){Z_2} - \frac{4}{{{D_{V'}}{D_{V''}}}}(A_1^{(1)} - A_2^{(1)} - A_2^{(2)} + A_4^{(2)})[2{{M'}^2} + {({m_{1'}} - {m_{1''}})^2}\\& - 2{({m_{1'}} + {m_2})^2} - {q^2} - {{\hat N}_{1'}} + {{\hat N}_{1''}}]\\& - \frac{8}{{{D_{V'}}{D_{V''}}}}\left[A_1^{(2)} - 6A_1^{(2)}A_2^{(1)} + 6A_2^{(1)}A_2^{(3)} - 2\frac{{{{(A_1^{(2)})}^2}}}{{{q^2}}}\right]\frac{{{{M'}^2} - {{M''}^2}}}{{{q^2}}}\bigg\} , \end{split}$
(A8) $\tag{A9}\begin{split} {{\tilde V}_5}({q^2}) =& \frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}( - 1)\bigg\{ 16(A_1^{(3)} - A_2^{(3)}) + 2(\hat N_1^\prime + {m'_1}^2 - {M'^2} \\&+ {Z_2} + m_2^2 - 2{m'_1}{m_2}) + 4(A_2^{(1)} - A_1^{(1)})\bigg(\hat N_1^{\prime \prime } + {m''_1}^2 + \frac{{{{M'}^2} - {{M''}^2} - {q^2}}}{2}\\& -\! {m'_1}{m''_1} + {m'_1}{m_2} - {m''_1}{m_2}\bigg) + \frac{4}{{{D_{V'}}}} \times \bigg[{m'_1}\bigg(4(A_2^{(3)} - A_1^{(3)}) + (A_2^{(1)} - A_1^{(1)})\\&\times({{M''}^2} - \hat N_1^{\prime \prime } - {m''_1}^2 - m_2^2) - (A_2^{(1)}{Z_2} + \frac{{{{M'}^2} - {{M''}^2}}}{{{q^2}}}A_1^{(2)})\bigg)\\& + \!{m''_1}\bigg((A_2^{(1)}\! -\! A_1^{(1)})(\hat N_1^\prime\! -\! {{M'}^2} \!+\! {m'_1}^2 \!-\! m_2^2) \!+\! (A_2^{(1)}{Z_2} \!+\! \frac{{{{M'}^2} \!-\! {{M''}^2}}}{{{q^2}}}A_1^{(2)})\bigg)\\& + {m_2}\bigg(4(A_2^{(3)} - A_1^{(3)}) + (A_2^{(1)} - A_1^{(1)})( - \hat N_1^\prime - \hat N_1^{\prime \prime } - {m'_1}^2 - {m''_1}^2 - q_ \bot ^2 \\&+ 2{m'_1}{m''_1})\bigg)\bigg] + \frac{4}{{{D_{V''}}}}\bigg[2{m'_1}A_1^{(2)} + 4{m''_1}4(A_2^{(3)} - A_1^{(3)}) + {m_2}\bigg(4(A_2^{(3)} - A_1^{(3)})\\& - 2A_1^{(2)}\bigg)\bigg] + \frac{{16}}{{{D_{V'}}{D_{V''}}}}\bigg[(A_2^{(3)} - A_1^{(3)})\bigg( - {m'_1}{m''_1} - m_2^2 - {m'_1}{m_2} - {m''_1}{m_2} \\&- \frac{{{{M'}^2} - {{M''}^2} + {q^2}}}{2} + {{M'}^2}\bigg) - A_2^{(3)}{Z_2} - \frac{{{{M'}^2} - {{M''}^2}}}{{3{q^2}}}{(A_1^{(2)})^2}\bigg]\bigg\} {\mkern 1mu} , \end{split}$
(A9) $\begin{split} {{\tilde V}_6}({q^2}) =& \frac{{{N_c}}}{{16{\pi ^3}}}\int {\rm d} x{{\rm d}^2}{k_ \bot }\frac{{h'h''}}{{\bar x\hat N_1^\prime \hat N_1^{\prime \prime }}}\bigg\{ 16(A_1^{(2)} - A_1^{(3)} - A_2^{(3)}) + 2( - 2{m'_1}^2 \\&- {m''_1}^2 - m_2^2 + {q^2} + {{M'}^2} - {Z_2} - 2\hat N_1^\prime - \hat N_1^{\prime \prime } + 2{m'_1}{m''_1} + 2{m'_1}{m_2}) \\&+ 4(A_2^{(1)} + A_1^{(1)})\bigg({m'_1}^2 + \frac{{{{M'}^2} - {{M''}^2}}}{2} + \hat N_1^\prime - \frac{1}{2}{q^2} - {m'_1}{m''_1}\\& - {m'_1}{m_2} - {m''_1}{m_2}\bigg) + \frac{{16}}{{{D_{V'}}}}\bigg[({m'_1} + {m_2})(A_1^{(3)} + A_2^{(3)}) - \bigg({m'_1}\\& + \frac{1}{2}{m''_1} + \frac{1}{2}{m_2}\bigg)A_1^{(2)}\bigg] + 4\frac{{{m'_1}}}{{{D_{V''}}}}( - {m''_1}^2 - m_2^2 + {{M''}^2} - {Z_2} - \hat N_1^{\prime \prime }) \\&+ \frac{{16}}{{{D_{V''}}}}({m''_1} + {m_2})(A_1^{(3)} + A_2^{(3)} - A_1^{(2)}) + \frac{4}{{{D_{V''}}}}[{m''_1}({m'_1}^2 + m_2^2 - {{M'}^2} \\&+ {Z_2} + \hat N_1^\prime ) + {m_2}({m'_1}^2 + {m''_1}^2 - {q^2} + \hat N_1^\prime + \hat N_1^{\prime \prime } - 2{m'_1}{m''_1})] \\& + \frac{4}{{{D_{V''}}}}(A_1^{(1)} + A_2^{(1)})[{m'_1}({m''_1}^2 + m_2^2 - {{M''}^2} + \hat N_1^{\prime \prime }) + {m''_1}( - {m'_1}^2 - m_2^2 \end{split}$
(A10) $\tag{A10}\begin{split} &+ {{M'}^2} - \hat N_1^\prime ) + {m_2}( - {m'_1}^2 - {m''_1}^2 + {q^2} - \hat N_1^\prime - \hat N_1^{\prime \prime } + 2{m'_1}{m''_1})] \\&+ \frac{4}{{{D_{V''}}}}({m'_1} - {m''_1})\left(A_2^{(1)}{Z_2} + \frac{{{{M'}^2} - {{M''}^2}}}{{{q^2}}}A_1^{(2)}\right) - \frac{{16}}{{{D_{V'}}{D_{V''}}}}(A_1^{(3)} + A_2^{(3)} \\&- A_1^{(2)})\left(m_2^2 - \frac{{{{M'}^2} + {{M''}^2}}}{2} + \frac{1}{2}{q^2} + {m'_1}{m''_1} + {m'_1}{m_2} + {m''_1}{m_2}\right)\\& \left.- \frac{{16}}{{{D_{V'}}{D_{V''}}}}\left[A_2^{(3)}{Z_2} + \frac{{{{M'}^2} - {{M''}^2}}}{{3{q^2}}}{(A_1^{(2)})^2} - A_1^{(2)}{Z_2}\right]\right\} , \end{split}$
(A10) where
$ {f}(x,k_\perp,q_\perp) = \displaystyle\frac{x^2}{\bar{x}}m_2^2+\displaystyle\frac{1}{\bar{x}}k_\perp^2-k_\perp\cdot q_\perp+\bar{x}m'_1m''_1-x(m'_1m_2+m''_1m_2) $ and$ D_{V^{\prime(\prime\prime)}} = {M}^{\prime(\prime\prime)}_0+m_1^{\prime(\prime\prime)}+m_2 $ is the factor appearing in the vertex operator. Here, we use the same notation and convention as Refs. [53–55], and the explicit forms of$ Z_2 $ ,$ h^{\prime(\prime\prime)}/\hat{N}_1^{\prime(\prime\prime)} $ and$ A_i^{(j)} $ functions can be easily found therein.
${{\bar{B}_{u,d,s}^* \to D_{u,d,s}^* V\,(V = D_{d,s}^{*-}\,,K^{*-}\,,{\rho}^-)}} $ weak decays
- Received Date: 2019-06-27
- Available Online: 2019-10-01
Abstract: Motivated by the rapid development of heavy flavor physics experiments, we study the tree-dominated nonleptonic