This paper demonstrates a high-performance hybrid mode-locked fiber laser utilizing a novel copper oxide-doped zinc oxide (CuO-ZnO) saturable absorber integrated with nonlinear polarization rotation (NPR). The hybrid approach combines the advantages of the CuO-ZnO saturable absorber (SA) for self-starting passive mode-locking with the benefit of NPR for spectral broadening and stability enhancement. This enabled 98 fs pulses with 682 mW average power, the shortest and highest from a 1 mm hybrid ytterbium-doped fiber laser (YDFL). The YDFL exhibits excellent pulse stability, having a high signal-to-noise ratio (SNR) of 51 dB. The high optical damage threshold of the CuO-ZnO SA facilitated robust ultrashort pulse generation at peak powers not achievable with semiconductor saturable absorber mirrors (SESAMs). The femtosecond fiber laser demonstrates significant performance improvements over previous hybrid and standalone mode-locked fiber lasers.

The investigation of a fiber laser utilizing ytterbium-doped hybrid passively mode-locking, featuring a novel copper oxide-doped zinc oxide saturable absorber (CuO-ZnO SA), has been realized. The hybrid mode-locked (hybrid-ML) fiber laser integrates the nonlinear polarization rotation (NPR) technology with the CuO-ZnO-SA, producing remarkable characteristics with a central wavelength of 1045 nm, a 3-dB bandwidth spanning 18.26 nm, an ultra-short pulse width of 98 fs, a repetition frequency of 1.96 MHz, and an impressive signal-to-noise ratio of 51 dB. This research demonstrates a substantial enhancement in laser performance compared to NPR mode-locking alone. Notably, the pulse width experiences a significant compression, reduced by 39 fs, while the signal-to-noise ratio sees a noteworthy improvement of 11 dB. Furthermore, when contrasted with passively mode-locked pulse lasers relying solely on NPR technology, the hybrid passively mode-locked fiber laser attains a substantial reductio...