The coloured lines represent the spatio-temporal description of various trajectories; each colour encodes a recolliding energy, increasing from red to blue. The black dashed line shows the electric field along the cycle. arb. u., arbitrary units.

a, b, Displacement gate. Different electron trajectories are separated along the ionization time axis (a). The displacement gate induces a lateral shift that suppresses the return probability. Only a narrow region in time is selected by the gate (shaded red). As the two-colour delay is changed, the gate is shifted within the optical cycle; a delayed ionization window is selected (b). c, d, Velocity gate. The different trajectories are separated in recombination time (c). The velocity gate controls the lateral velocity and, hence, the angle at recombination. A narrow region in time corresponds to the maximal recombination angle, selected by the gate (shaded red). Modifying the two-colour delay shifts the velocity gate within the optical cycle, thereby choosing a delayed recombination window (d).

a, Displacement gate: normalized harmonic signal (colour scale) as a function of harmonic order and two-colour delay (φ) for helium. (For each harmonic order the signal is divided by the maximal signal for that harmonic. Colour scale shows the relative strength of the normalized signal.) b, Velocity gate: normalized recollision angle (colour scale) as a function of harmonic order and φ . (For each harmonic order the angle is divided by the maximal angle for that harmonic. Colour scale shows the relative strength of the normalized signal.) c, Reconstructed ionization and recollision times extracted from a and b (red dots). The pink shaded areas represent the uncertainty in the reconstruction procedure. The extracted times are compared to the calculated times according to the semiclassical model (grey curves) and the quantum stationary solution (black curves). The reconstructed ionization times using the combined ionization–displacement gate (green curve) are also shown (Supplementary Information).

a, Two stationary solutions associated with the HOMO (red curve) and HOMO−2 (grey curve) orbitals, calculated for I = 1.3 × 10¹⁴ W cm⁻². b, Calculation of |G⁽¹⁾|² and |G⁽²⁾|² as functions of the two-colour delay (φ). The black dashed lines indicate for each channel. c, Calculation of G_N for constructive (black curve) and destructive (blue curve) interference. d, Theoretical calculation of the normalized harmonic signal for a carbon dioxide molecule aligned at an angle of ±35° to the 40-fs, 800-nm, I = 1.3 × 10¹⁴ W cm⁻² fundamental field, using the second-harmonic field at a 2% intensity level. e, f, Normalized measured harmonic spectra (colour scale) as functions of harmonic order and φ for carbon dioxide molecules aligned at 90° (e) and 0° (f). The white curves follow the phases ( ) that maximize the harmonic signal. The two colour phase was shifted by 0.3 rad in panels d–f to show the full extent of the phase shift.