The stellar occultation spectrometer GOMOS (Global Ozone Monitoring by Occultation of Stars) on ESA's Envisat satellite measures vertical profiles O₃ , NO₂ and NO₃ with a high long-term stability due to the self-calibrating nature of the technique. More than 6 years of GOMOS data from August 2002 to end 2008 have been analysed to study the inter-annual variation of O₃ , NO₂ and NO₃ in the tropics. It is shown that the QBO of the equatorial wind induces variations in the local concentration larger than 10% for O₃ and larger than 25% for NO₂ .

Quasi-Biennial Oscillation signals can be found in the evolution of the three constituents up to at least 40 km. We found that NO₃ is positively correlated with temperature up to 45 km in the region where it is in chemical equilibrium with O₃ . Our results confirm the existence of a transition from a dynamical control of O₃ below 28 km with O₃ correlated with temperature and a chemical/temperature control between 28 and 38 km with O₃ anti-correlated with NO₂ and temperature. Above 38 km and up to 50 km a different regime is found with O₃ and NO₂ correlated with each other and anti-correlated with temperature. For the NO₂ /temperature anti-correlation in the upper stratosphere, our proposed explanation is the modulation of the N₂ O ascent by the QBO up to 45 km. The oxidation of N₂ O is the main source of NO_y in this altitude region. An enhancement of the ascending motion will cool adiabatically the atmosphere and will increase the amount of N₂ O concentration available for NO_y formation.