The pion-photon transition form factor (TFF) provides strong constraints on the pion distribution amplitude (DA). We perform an analysis of all existing data (CELLO, CLEO, BaBar, Belle) on the pion-photon TFF by means of light-cone pQCD approach in which we include the next-to-leading order correction to the valence-quark contribution and estimate the non-valence-quark contribution by a phenomenological model based on the TFF's limiting behavior at both Q 2 → 0 and Q 2 → ∞. At present, the pion DA is not definitely determined, it is helpful to have a pion DA model that can mimic all the suggested behaviors, especially to agree with the constraints from the pion-photon TFF in whole measured region within a consistent way. For the purpose, we adopt the conventional model for pion wavefunction/DA that has been constructed in our previous paper [14], whose broadness is controlled by a parameter B. We fix the DA parameters by using the CELLO, CLEO, BABAR and Belle data within the smaller Q 2 region (Q 2 ≤ 15 GeV 2 ), where all the data are consistent with each other. And then the pion-photon TFF is extrapolated into larger Q 2 region. We observe that the BABAR favors B = 0.60 which has the behavior close to the Chernyak-Zhitnitsky DA, whereas the recent Belle favors B = 0.00 which is close to the asymptotic DA. We need more accurate data at large Q 2 region to determine the precise value of B, and the definite behavior of pion DA can be concluded finally by the consistent data in the coming future. The pion-photon transition form factor (TFF), F πγ (Q 2 ), which relates two photons with one lightest meson, provides a good platform to study the property of pion distribution amplitude (DA). Because higher helicity and higher twist structures give negligible contributions to the pion-photon TFF [1, 2], one can extract useful information on the shape of the leading-twist pion DA by comparing the estimated result of F πγ (Q 2 ) with the measured one.Experimentally, the pion-photon TFF is determined by measuring the process e + e − → e + e − π 0 in the singletag mode, where one of the outing electron (tagged) is detected while the other electron (untagged) is scattered at a small angle. The tagged electron emits a highly offshell photon with momentum transfer Q 2 and the momentum transfer to the untagged electron is near zero. The pion-photon TFF has first been measured by the CELLO collaboration with Q 2 < 3 GeV Instead of a pronounced growth of the TFF at high Q 2 region, observed by BABAR, the Belle data are compatible with the well-known asymptotic prediction [7], i.e. Q 2 F πγ (Q 2 ) tends to be a constant (2f π ) for asymptotic DA φ as π (x, Q 2 )| Q 2 →∞ = 6x(1 − x). Here the pion decay constant f π = 92.4 ± 0.25 MeV [8].At present, there is still no definite conclusion on whether pion DA is in asymptotic-like form [7] or in Chernyak-Zhitnitsky (CZ)-like form [9], or in a flat-like form [10]. It would be helpful to have a consistent pion DA model that can mimic all these behaviors and can explain the pion-photon TFF...
