Interfacial Engineering of Fe–Zr Bimetallic Oxides Boosts Phenolic Pollutants Removal in Heterogeneous Fenton–Like Process

Yue Yin; Zekun Dong; Jibin Li; Jiao Yang; Jingqing Gao

doi:10.1002/eem2.70073

Energy & Environmental Materials ›› 2026, Vol. 9 ›› Issue (1) :e70073 DOI: 10.1002/eem2.70073

RESEARCH ARTICLE

Interfacial Engineering of Fe–Zr Bimetallic Oxides Boosts Phenolic Pollutants Removal in Heterogeneous Fenton–Like Process

Yue Yin ¹^,²^,³
, Zekun Dong ⁴
, Jibin Li ¹
, Jiao Yang ¹^,²
, Jingqing Gao ¹^,²

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Abstract

Fenton technology has garnered significant attention for the deep removal of low-concentration emerging contaminants due to its remarkable oxidation performance. However, the traditional mineralization process for emerging contaminants requires a substantial amount of hydroxyl radicals (HO˙), leading to excessive consumption of H₂O₂. Through interfacial engineering of Fe–Zr bimetallic catalysts (FeZrO_x), this study demonstrates synergistic enhancement of phenolic pollutant removal at heterojunction interfaces while achieving an 80% reduction in H₂O₂ dosage compared to traditional Fe₂O₃ systems. The chemical states of Fe and Zr at the (104)/(111) heterojunction interface in FeZrO_x exhibit marked modifications relative to their monometallic Fe₂O₃ and ZrO₂ counterparts. The elevated charge density at interfacial Fe sites in FeZrO_x promotes HO˙ generation, while optimized antibonding orbital composition below the Fermi level in bisphenol A adsorbed on Zr sites enhances hydrogen abstraction and subsequent polymerization. This Fe–Zr synergy at the (104)/(111) heterojunction concurrently suppresses HO˙ diffusion losses and directs phenolic pollutant (e.g., phenol and bisphenol A) polymerization within the reactive interface, thereby reducing H₂O₂ consumption compared to monometallic systems.

Keywords

bimetallic oxide / Fenton-like process / H₂O₂ consumption / heterojunction / polymerization

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Yue Yin, Zekun Dong, Jibin Li, Jiao Yang, Jingqing Gao. Interfacial Engineering of Fe–Zr Bimetallic Oxides Boosts Phenolic Pollutants Removal in Heterogeneous Fenton–Like Process. Energy & Environmental Materials, 2026, 9(1): e70073 DOI:10.1002/eem2.70073

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