Conventional Fenton process operated along with high economic cost due to the requirement of highly acidic pH and an enormous addition of H2O2. And the low conversion rate of Fe(III)/Fe(II) may lead to decline of oxidation performance during the process. Here, we constructed a visible light-induced heterogeneous Fenton-like process on a novel Fenton-like catalyst which consisted of immobilized Fe(III)-TiO2 microspheres as Fenton-like reagent and g-C3N4-porphyrin lamella as in-situ H2O2 donor. The immobilized Fe species showed good stability and reduced the loss of Fe during Fenton-like process. Meanwhile, taking advantage of interfacial charge transfer (IFCT) effect among Fe(III)-TiO2 microspheres, the transformation from Fe(III) to Fe(II) was accelerated by photo-induced electrons from conduction band of the microspheres. And the pi -pi interaction between porphyrin and g-C3N4 also strikingly promoted the in-situ H2O2 production, which also boosted the Fenton-like process along with the IFCT effect. Stronger electron spin resonance signal of center dot OH confirmed the boost mentioned above and indicated that g-C3N4-porphyrin provided H2O2 in abundance for the Fenton-like process. This new Fentonlike catalyst exhibited superior oxidation performance and the optimum catalyst TFMS-CP0.1 achieved the removal of 92.6 % and 84.6 % towards phenol and hydroquinone in 3 h, respectively, and 88.2 % towards MO in 1 h. This work proposed a credible mechanism of visible light-induced Fenton-like process and achieved efficient oxidative degradation of the organic contaminant.

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