Abstract
Developing effective electrocatalysts for the nitrate reduction reaction (NO(3)RR) is a promising alternative to conventional industrial ammonia (NH(3)) synthesis. Herein, starting from a flexible laser-induced graphene (LIG) film with hierarchical and interconnected macroporous architecture, a binder-free and free-standing Ru-modified LIG electrode (Ru-LIG) is fabricated for electrocatalytic NO(3)RR via a facile electrodeposition method. The relationship between the laser-scribing parameters and the NO(3)RR performance of Ru-LIG electrodes is studied in-depth. At -0.59 V(RHE), the Ru-LIG electrode exhibited the optimal and stable NO(3)RR performance (NH(3) yield rate of 655.9 µg cm(-2) h(-1) with NH(3) Faradaic efficiency of up to 93.7%) under a laser defocus setting of +2 mm and an applied laser power of 4.8 W, outperforming most of the reported NO(3)RR electrodes operated under similar conditions. The optimized laser-scribing parameters promoted the surface properties of LIG with increased graphitization degree and decreased charge-transfer resistance, leading to synergistically improved Ru electrodeposition with more exposed NO(3)RR active sites. This work not only provides a new insight to enhance the electrocatalytic NO(3)RR performance of LIG-based electrodes via the coordination with metal electrocatalysts as well as identification of the critical laser-scribing parameters but also will inspire the rational design of future advanced laser-induced electrocatalysts for NO(3)RR.