From a fit to the experimental data on the bbˉ fine structure, the
two-loop coupling constant is extracted. For the 1P state the fitted value is
αs​(μ1​)=0.33±0.01(exp)±0.02(th) at the scale μ1​=1.8±0.1 GeV, which corresponds to the QCD constant Λ(4)(2−loop)=338±30 MeV (n_f = 4) and αs​(MZ​)=0.119±0.002.Forthe2Pstatethevalue\alpha_s(\mu_2) = 0.40 \pm 0.02(exp)\pm 0.02(th)atthescale\mu_2 = 1.02 \pm 0.2GeVisextracted,whichissignificantlylargerthaninthepreviousanalysisofFulcher(1991)andHalzen(1993),butabout30smallerthanthevaluegivenbystandardperturbationtheory.Thisvalue\alpha_s(1.0) \approx 0.40canbeobtainedintheframeworkofthebackgroundperturbationtheory,thusdemonstratingthefreezingof\alpha_s.Therelativisticcorrectionsto\alpha_s$ are found to be about 15%.Comment: 18 pages LaTe
The leptonic widths of high ψ-resonances are calculated in a
coupled-channel model with unitary inelasticity, where analytical expressions
for mixing angles between (n+1)\,^3S_1 and n\,^3D_1 states and
probabilities Zi​ of the ccˉ component are derived. Since these factors
depend on energy (mass), different values of mixing angles
θ(ψ(4040))=27.7∘ and θ(ψ(4160))=29.5∘,
Z1​(ψ(4040))=0.76, and Z2​(ψ(4160))=0.62 are obtained. It gives
the leptonic widths Γee​(ψ(4040))=Z1​1.17=0.89~keV,
Γee​(ψ(4160))=Z2​0.76=0.47~keV in good agreement with
experiment. For ψ(4415) the leptonic width
Γee​(ψ(4415))= 0.55~keV is calculated, while for the missing
resonance ψ(4510) we predict M(ψ(4500))=(4515±5)~MeV and
Γee​(ψ(4510))≅0.50~keV.Comment: 10 pages, 6 references corrected, some new material adde
The masses of higher D(nL) and Ds​(nL) excitations are shown to decrease
due to the string contribution, originating from the rotation of the QCD string
itself: it lowers the masses by 45 MeV for L=2(n=1) and by 65 MeV for L=3(n=1). An additional decrease ∼100 MeV takes place if the current mass
of the light (strange) quark is used in a relativistic model. For
Ds​(13D3​) and Ds​(2P1H​) the calculated masses agree with the
experimental values for Ds​(2860) and Ds​(3040), and the masses of
D(21S0​), D(23S1​), D(13D3​), and D(1D2​) are in
agreement with the new BaBar data. For the yet undiscovered resonances we
predict the masses M(D(23P2​))=2965 MeV, M(D(23P0​))=2880 MeV,
M(D(13F4​))=3030 MeV, and M(Ds​(13F2​))=3090 MeV. We show that
for L=2,3 the states with jq​=l+1/2 and jq​=l−1/2 (J=l) are almost
completely unmixed (ϕ≃−1∘), which implies that the mixing
angles θ between the states with S=1 and S=0 (J=L) are θ≈40∘ for L=2 and ≈42∘ for L=3.Comment: 22 pages, no figures, 4 tables Two references and corresponding
discussion adde
From the fact that the nonperturbative self-energy contribution CSE​
to the heavy meson mass is small: CSE​(bbˉ)=0; CSE​(ccˉ)≅−40 MeV \cite{ref.01}, strong restrictions on the pole
masses mb​ and mc​ are obtained. The analysis of the bbˉ and the
ccˉ spectra with the use of relativistic (string) Hamiltonian gives
mb​(2-loop)=4.78±0.05 GeV and mc​(2-loop)=1.39±0.06 GeV which
correspond to the MSˉ running mass mˉb​(mˉb​)=4.19±0.04 GeV and mˉc​(mˉc​)=1.10±0.05 GeV. The masses ωc​
and ωb​, which define the heavy quarkonia spin structure, are shown to
be by ∼200 MeV larger than the pole ones.Comment: 18 pages, no figures, 8 table
A new physical mechanism is suggested to explain the universal depletion of
high meson excitations. It takes into account the appearance of holes inside
the string world sheet due to qqˉ​ pair creation when the length of the
string exceeds the critical value R1​≃1.4 fm. It is argued that a
delicate balance between large Nc​ loop suppression and a favorable gain in
the action, produced by holes, creates a new metastable (predecay) stage with a
renormalized string tension which now depends on the separation r. This results
in smaller values of the slope of the radial Regge trajectories, in good
agreement with the analysis of experimental data in [Ref.3]Comment: 25 pages, 1 figur
Radiative decays of X(3872) are studied in single-channel approximation
(SCA) and in the coupled-channel (CC) approach, where the decay channels DDˉ∗ are described with the string breaking mechanism. In SCA the transition
rate Γ~2​=Γ(23P1​→ψγ)=71.8~keV and
large Γ~1​=Γ(23P1​→J/ψγ)=85.4~keV
are obtained, giving for their ratio the value
Rψγ​~​=Γ~1​Γ~2​​=0.84. In the
CC approach three factors are shown to be equally important. First, the
admixture of the 13P1​ component in the normalized wave function of
X(3872) due to the CC effects. Its weight cX​(ER​)=0.200±0.015 is calculated. Secondly, the use of the multipole function g(r)
instead of r in the overlap integrals, determining the partial widths.
Thirdly, the choice of the gluon-exchange interaction for X(3872), as well as
for other states above threshold. If for X(3872) the gluon-exchange potential
is taken the same as for low-lying charmonium states, then in the CC approach
Γ1​=Γ(X(3872)→J/ψγ)∼3~keV is very small,
giving the large ratio Rψγ​=B(X(3872)→J/ψγ)B(X(3872)→ψ(2S)γ)​≫1.0.
Arguments are presented why the gluon-exchange interaction may be suppressed
for X(3872) and in this case Γ1​=42.7~keV, Γ2​=70.5~keV, and
Rψγ​=1.65 are predicted for the minimal value cX​(min)=0.185, while for the maximal value cX​=0.215 we obtained
Γ1​=30.8~keV, Γ2​=73.2~keV, and Rψγ​=2.38, which
agrees with the LHCb data.Comment: 12 pages, no figure
The time evolution of a many-fermion system can be described by a Green's
function corresponding to an effective potential, which takes
anti-symmetrization of the wave function into account, called the
Pauli-potential. We show that this idea can be combined with the Green's
Function Monte Carlo method to accurately simulate a system of many
non-relativistic fermions. The method is illustrated by the example of systems
of several (2-9) fermions in a square well.Comment: 12 pages, LaTeX, 4 figure
A universal description of the hyperfine splittings (HFS) in bottomonium and
the Bq​(q=n,s,c) mesons is obtained with a universal strong coupling
constant αs​(μ)=0.305(2) in a spin-spin potential. Other
characteristics are calculated within the Field Correlator Method, taking the
freezing value of the strong coupling independent of nf​. The HFS M(B∗)−M(B)=45.3(3) MeV, M(Bs∗​)−M(Bs​)=46.5(3) MeV are obtained in full
agreement with experiment both for nf​=3 and nf​=4. In bottomonium,
M(Υ(9460))−M(ηb​)=70.0(4) MeV for nf​=5 agrees with the BaBar
data, while a smaller HFS, equal to 64(1) MeV, is obtained for nf​=4. We
predict HFS M(Υ(2S))−M(ηb​(2S))=36(1) MeV, M(Υ(3S))−M(η(3S))=27(1) MeV, and M(Bc∗​)−M(Bc​)=57.5(10) MeV, which gives
M(Bc∗​)=6334(1) MeV, M(Bc​(21S0​))=6865(5) MeV, and M(Bc∗​(2S3S1​))=6901(5) MeV.Comment: 5 pages revtex