Demand for ammonia continues to increase to sustain the growing global population. The direct electrochemical N
2
reduction reaction (NRR) powered by renewable electricity offers a promising carbon-neutral and sustainable strategy for manufacturing NH
3
, yet achieving this remains a grand challenge. Here, we report a synergistic strategy to promote ambient NRR for ammonia production by tuning the Te vacancies (V
Te
) and surface hydrophobicity of two-dimensional TaTe
2
nanosheets. Remarkable NH
3
faradic efficiency of up to 32.2% is attained at a mild overpotential, which is largely maintained even after 100 h of consecutive electrolysis. Isotopic labeling validates that the N atoms of formed NH
4
+
originate from N
2
.
In situ
X-ray diffraction indicates preservation of the crystalline structure of TaTe
2
during NRR. Further density functional theory calculations reveal that the potential-determining step (PDS) is ∗NH
2
+ (H
+
+ e
–
) → NH
3
on V
Te
-TaTe
2
compared with that of ∗ + N
2
+ (H
+
+ e
–
) → ∗N–NH on TaTe
2
. We identify that the edge plane of TaTe
2
and V
Te
serve as the main active sites for NRR. The free energy change at PDS on V
Te
-TaTe
2
is comparable with the values at the top of the NRR volcano plots on various transition metal surfaces.
Photocatalytic nitrogen reduction reaction (NRR) to ammonia holds a great promise for substituting the traditional energy-intensive Haber–Bosch process, which entails sunlight as an inexhaustible resource and water as a hydrogen source under mild conditions. Remarkable progress has been achieved regarding the activation and solar conversion of N2 to NH3 with the rapid development of emerging photocatalysts, but it still suffers from low efficiency. A comprehensive review on photocatalysts covering tungsten and related metals as well as their broad ranges of alloys and compounds is lacking. This article aims to summarize recent advances in this regard, focusing on the strategies to enhance the photocatalytic performance of tungsten and related metal semiconductors for the NRR. The fundamentals of solar-to-NH3 photocatalysis, reaction pathways, and NH3 quantification methods are presented, and the concomitant challenges are also revealed. Finally, we cast insights into the future development of sustainable NH3 production, and highlight some potential directions for further research in this vibrant field.
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