Electric quadrupole transitions in the a1Dg2X3Sg band of 16O2 near 1.27 µm are reported for the first time. They were first detected in atmospheric solar spectra acquired with a ground-based Fourier transform spectrometer (FTS) in ParkFalls, WI. Subsequently high-sensitivity CW—cavity ringdown spectroscopy (CW-CRDS) experiments were carried out at Grenoble University in the 7717–7917cm1 region in order to provide quantitative intensity information for the electric quadrupole transitions. Measured intensities were used as input data for the calculation of the complete list of electric quadrupole transitions with DJ=72, 71 and 0. The calculation was carried out for the intermediate coupling case and assuming that these transitions are possible only through mixing of the O=0 component of the ground electronic state and b1Sþg state induced by spin–orbit coupling. The calculated line list agrees well with experimental measurements and was used to improve the residuals of the fitted solar atmospheric spectrum. Emission probability for the electric quadrupole band was determined to be (1.0270.10)106 s1.