The electrochemical nitrate reduction
to ammonia reaction (NO3RR) has emerged as an appealing
route for achieving both wastewater
treatment and ammonia production. Herein, sub-nm RuO
x
clusters anchored on a Pd metallene (RuO
x
/Pd) are reported as a highly effective NO3RR catalyst,
delivering a maximum NH3-Faradaic efficiency of 98.6% with
a corresponding NH3 yield rate of 23.5 mg h–1 cm–2 and partial a current density of 296.3 mA
cm–2 at −0.5 V vs RHE. Operando spectroscopic characterizations combined with theoretical computations
unveil the synergy of RuO
x
and Pd to enhance
the NO3RR energetics through a mechanism of hydrogen spillover
and hydrogen-bond interactions. In detail, RuO
x
activates NO3
– to form intermediates,
while Pd dissociates H2O to generate *H, which spontaneously
migrates to the RuO
x
/Pd interface via
a hydrogen spillover process. Further hydrogen-bond interactions between
spillovered *H and intermediates makes spillovered *H desorb from
the RuO
x
/Pd interface and participate
in the intermediate hydrogenation, contributing to the enhanced activity
of RuO
x
/Pd for NO3
–-to-NH3 conversion.