What question did this study set out to answer?

The aim is to compare the electrocatalytic and thermodynamic performance of gCN, Cu/gCN, and CuO/gCN in water splitting.

March 25, 2026Open Access

Enhanced electrocatalytic performance and thermodynamic insights of gCN, Cu-doped gCN nanocomposites for efficient overall water splitting

Key Points

The aim is to compare the electrocatalytic and thermodynamic performance of gCN, Cu/gCN, and CuO/gCN in water splitting.
Compared pristine gCN, Cu-doped gCN, and CuO-decorated gCN
Employed two synthesis strategies to incorporate copper into gCN
Measured electrocatalytic activity using Tafel slope and activation energy analysis
Cu/gCN and CuO/gCN exhibited improved electrocatalytic performance compared to pristine gCN
CuO/gCN achieved the best results with Tafel slopes of 91 mV dec⁻¹ (OER) and 73 mV dec⁻¹ (HER)
Reduced activation energies of 43.29 kJ mol⁻¹ for OER and 30.57 kJ mol⁻¹ for HER were observed

Abstract

This study comparatively investigates the electrocatalytic and thermodynamic performance of pristine graphitic carbon nitride (gCN), copper-doped gCN (Cu/gCN), and copper oxide–decorated gCN (CuO/gCN) for overall water splitting. Two synthesis strategies were employed to incorporate copper species into the gCN framework, enabling the assessment of their influence on electrochemical activity. The first approach involved direct Cu doping, while the second produced CuO nanoparticles supported on the gCN matrix. X-ray photoelectron spectroscopy revealed distinct copper chemical states, with Cu⁰/Cu⁺ species in Cu/gCN and Cu²⁺ species with characteristic satellite features in CuO/gCN, indicating strong metal–support interactions that contribute to improved catalytic performance. Pristine gCN exhibited limited activity due to poor intrinsic conductivity, whereas both Cu modification strategies significantly enhanced electrocatalytic performance. Both Cu/gCN and CuO/gCN showed promising activity for overall water splitting, with CuO/gCN delivering superior results. This material achieved lower Tafel slopes of 91 mV dec⁻¹ for OER and 73 mV dec⁻¹ for HER, along with reduced activation energies of 43.29 kJ mol⁻¹ (OER) and 30.57 kJ mol⁻¹ (HER). The novelty of this work lies in the systematic comparison of two eco-friendly and scalable modification routes, revealing the distinct contributions of Cu doping and CuO incorporation to catalytic enhancement. The improved kinetics, coupled with high thermal and operational stability, highlight Cu/gCN and CuO/gCN as cost-effective and sustainable electrocatalysts for water-splitting applications. • Developed noble metal-free Cu/gCN catalyst for water splitting • Used low-temp calcination to synthesize modified g-C₃N₄ materials • Cu and CuO boosted g-C₃N₄ conductivity and catalytic performance • CuO/gCN showed best results with low Tafel slopes and activation energies • Study compares two eco-friendly copper incorporation methods in g-C₃N₄

Enhanced electrocatalytic performance and thermodynamic insights of gCN, Cu-doped gCN nanocomposites for efficient overall water splitting

Key Points

Abstract

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