摘要： Mode-locking (ML) is an established technique used to generate high-power, ultrashort (from ps to fs) light pulses in lasers. Mode-locking techniques could be classified into two broad categories: active mode-locking (AML), for example achieved by an external periodic (in time) modulation of the loss coefficient, or passive mode-locking (PML), for example via a saturable absorber. Active mode-locking could be achieved by a periodic (in time) modulation of the loss coefficient, or phase mode-locking (PML), via a periodic modulation of the length of the cavity. In an amplitude mode-locking (AML) the periodic modulation of the loss coefficient synchronizes the phases of the cavity modes, resulting in a train of pulses. In a phase mode-locking (PML), the periodic modulation of the cavity length results in a phase modulation of the cavity modes, leading to a frequency comb. In this sense, the phase mode-locking is a particular case of the more general frequency comb generation in lasers. In the case of the non-Hermitian mode-locking the periodic modulation of the loss coefficient is replaced by a periodic modulation of the non-Hermitian potential, which can be achieved by a periodic (in time) modulation of the loss coefficient, or by a periodic modulation of the gain coefficient. The non-Hermitian mode-locking could be achieved by a periodic modulation of the non-Hermitian potential, which can be achieved by a periodic (in time) modulation of the loss coefficient, or by a periodic modulation of the gain coefficient. The non-Hermitian mode-locking is a particular case of the more general frequency comb generation in lasers with non-Hermitian potentials. In this paper we propose a new type of mode-locking – non-Hermitian mode-locking (NML) – realized in frequency domain. Non-Hermitian unidirectional coupling between the modes in frequency domain can be achieved by a simultaneous amplitude and phase mode-locking with the phases of both modulations properly shifted one with respect to another. The NML regime is fixed at λ=1.55 μm.