Field evaporation of silver and field desorption of silver surface compounds were investigated by analysing positive ions with a mass spectrometer. In particular, the well known adsorption states of oxygen, and further the interactions of H 2 O, NH 3 , H 2 , CO and CH 4 were measured in the field ion mass spectrometer under steady state fields of > 0.1 V/Å with a sensitivity of < 0.1 ions s −1 and at temperatures between 80 °K and 425 °K. Although oxygen is usually chemisorbed at Ag surfaces, no AgO + , AgO + 2 or other Ag-O compounds could be detected as positive ions, Ag + and O 2 + are the only observed ions at best image fields in oxygen up to fields of field evaporation of Ag + (≈ 2.2 V/Å). Even after the actual adsorption of oxygen with zero-field (6 × 10 5 Langmuir at 10 −3 Torr) at 323 °K and 473 °K and subsequent application of the desorption field at 210°K no silver-oxygen compounds were found in positive ionic form. Small quantities of AgO + and AgO + 2 were only formed — besides Ag(H 2 O) x + complexes — if atomic oxygen was supplied by the field induced dissociation of water. Gases which do not adsorb on silver under zero-field conditions (H 2 , CO, CH 4 , N 2 ) yield the ions Ag(H 2 ) n , Ag(CO) n + , n =1, 2; AgCH 4 + , AgN 2 + . The situation with H 2 O and NH 3 is more complicated: Molecular ions [Ag(H 2 O) n ] + · m H 2 O, n =1,…, 4, m =1,…, 8 and [Ag(NH 3 ) n ] + · m NH 3 , n =1, 2, m =1,…, 6 are found besides Ag + . From the temperature and field dependence conclusions are drawn about the mechanisms of evaporation and formation of ionic surface complexes. The activation energies of evaporation of Ag + are found to depend on the square root of the field strength. In general, the generation of surface compounds can be described by field induced reactions rather than usual gas adsorption.