At the soft-x-ray free-electron laser FLASH in Hamburg, we have studied multiphoton ionization on neon and helium by ion mass-to-charge spectroscopy. The experiments were performed in a focused beam at 42.8 and 38.4 eV photon energy and irradiance levels up to 10 14 W/cm 2 . Direct, sequential, and resonant two-, three-, and four-photon excitations were investigated by quantitative measurements as a function of the absolute photon intensity. The atomic and ionic photoionization cross sections derived indicate a clear dominance of sequential compared to direct multiphoton processes. DOI: 10.1103/PhysRevA.75.051402 PACS number͑s͒: 32.80.Rm, 32.80.Fb, 42.50.Hz Recent progress has been achieved in generating soft-xray pulses of high power by means of free-electron lasers ͑FELs͒ ͓1-4͔ and higher-harmonics generation technique ͓5͔. In the near future, several large x-ray FEL facilities will be realized to study fast processes in materials and chemical reactions by ultrashort laser shots ͓1,2,6͔. However, highly intense soft x rays ͑xuv͒ and vacuum-ultraviolet radiation cause nonlinear response of matter such as atomic multiphoton ionization ͓7-13͔ which has to be taken into consideration in any FEL experiment. In this context, we report on the strength of two-, three-, and four-photon multiple ionization obtained by quantitative measurements of ion time-offlight ͑TOF͒ spectroscopy at the new xuv Free-electronLASer in Hamburg ͑FLASH͒ ͓4͔. In order to distinguish and compare different sequential and direct multiphoton excitation schemes, our experiments were performed on neon ͑Ne͒ and helium ͑He͒ atoms at two different photon energies, namely 42.8 and 38.4 eV, i.e., just above and below the threshold for sequential two-photon double ionization of Ne via Ne + at 41.0 eV. Significant differences in the respective nonlinear dependences on photon intensity could be observed. Figure 1 summarizes the multiphoton processes we discuss here. They refer to sequential ͓Fig. 1͑d͔͒ and direct ͓Fig. 1͑g͔͒ two-photon processes, a combination of both, i.e., a four-photon excitation ending up in a triply charged ion ͓Fig. 1͑e͔͒, and three-photon double ionization via virtual and resonance states ͓Figs. 1͑b͒ and 1͑c͔͒. The investigations were performed at the microfocus beamline BL2 at FLASH with an experimental setup described in detail previously ͓12,15,16͔. It consists of a calibrated online gas-monitor photodetector and a conventional ion TOF spectrometer. In order to avoid effects due to space charge and secondary ionization, the pressure of the target gas homogeneously filling the vacuum chamber was controlled below 2 ϫ 10 −4 Pa. The FEL radiation was distributed among subsequent photon pulses separated by 200 ms with up to 3 ϫ 10 12 photons per pulse and a pulse duration of ⌬t = ͑25± 8͒ fs ͓4,17͔. A focal spot size of A = ͑5.0± 0.7͒ ϫ 10 −6 cm 2 was realized by means of an ellipsoidal mirror ͓16͔. Ions generated in the focus were extracted toward the TOF spectrometer by a static electric field parallel to the polarization vect...
