Three-phase interface of SnO2 nanoparticles loaded on hydrophobic MoS2 enhance photoelectrochemical N2 reduction.

Photoelectrochemical nitrogen reduction (PEC NRR) provides a clean and sustainable method for the production of NH 3 under environmental conditions. However, low reaction efficiency remains a major challenge due to the presence of competitive hydrogen evolution reactions (HER). Herein, nanocomposites (SNP/MSO) with three-phase interface were prepared by loading hydrophilic SnO 2 nanoparticles (SNP) on hydrophobic MoS 2 (MSO) obtained by surface modification with silicomolybdic acid. The hydrophobic interface eliminated the transport barrier of N 2 in the liquid phase to the reaction center, inhibiting HER since the lowered contact area with the liquid proton. Meanwhile, the heterojunction structure formed between MSO and SNP accelerated the effective electron transfer. The synergistic effect of the triphase interface structure and electron transfer structure contributed to the high NH 3 yield (19.6 μg h−1 mg−1) and FE (40.34%) of SNP/10MSO in the photoelectrochemical system. Compared with the nanocomposites (SNP/MSI) prepared by hydrophilic MoS 2 , FE was significantly increased by 10 percentage points. [Display omitted] Three-phase interface of SNP/MSO enhance photoelectrochemical N 2 reduction. [ABSTRACT FROM AUTHOR]