Redox Behavior of Secondary Solid Iron Species and the Corresponding Effects on Hydroxyl Radical Generation during the Pyrite Oxidation Process

Zhao, Zhenyu; Peng, Shaoyi; Ma, Canming; Yu, Chao; Wu, Deli

doi:10.1021/acs.est.2c04624

Cited by 36 publications

(13 citation statements)

References 52 publications

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“…Redox oscillations could activate thermodynamically stable pyrite to produce RAMPs. Given that the crystallinity of iron mineral controls the redox activity following the order of adsorbed Fe > amorphous Fe > crystalline Fe, the above results suggest that redox fluctuations likely promote the production of reactive Fe(II) and amorphous Fe on the surface of pyrite . Specifically, the abiotic oxidation of pyrite by air and hydrogen peroxide could produce metastable secondary ferric oxyhydroxides coated on the surface of native pyrite at low tide .…”

Section: Resultsmentioning

confidence: 92%

“…Given that the crystallinity of iron mineral controls the redox activity following the order of adsorbed Fe > amorphous Fe > crystalline Fe, 39 the above results suggest that redox fluctuations likely promote the production of reactive Fe(II) and amorphous Fe on the surface of pyrite. 40 Specifically, the abiotic oxidation of pyrite by air and hydrogen peroxide could produce metastable secondary ferric oxyhydroxides coated on the surface of native pyrite at low tide. 40 Afterward, the amorphous ferric precipitates were readily reduced into dissolved ferrous ions by microbial anaerobic respiration at high tide.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…40 Specifically, the abiotic oxidation of pyrite by air and hydrogen peroxide could produce metastable secondary ferric oxyhydroxides coated on the surface of native pyrite at low tide. 40 Afterward, the amorphous ferric precipitates were readily reduced into dissolved ferrous ions by microbial anaerobic respiration at high tide. The dissolved ferrous ions could be reoxidized into metastable ferric oxyhydroxides precipitates upon shifting to low tide.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Redox Oscillations Activate Thermodynamically Stable Iron Minerals for Enhanced Reactive Oxygen Species Production

Zhao

Tan

et al. 2023

Environ. Sci. Technol.

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Reactive oxygen species (ROS) play key roles in driving biogeochemical processes. Recent studies have revealed nonphotochemical electron transfer from redox-active substances (e.g., iron minerals) to oxygen as a new route for ROS production. Yet, naturally occurring iron minerals mainly exist in thermodynamically stable forms, restraining their potential for driving ROS production. Here, we report that tide-induced redox oscillations can activate thermodynamically stable iron minerals for enhanced ROS production. • OH production in intertidal soils (15.8 ± 0.5 μmol/m 2 ) was found to be 5.9-fold more efficient than those in supratidal soils. Moreover, incubation of supratidal soils under tidal redox fluctuations dramatically enhanced • OH production by 4.3fold. The tidal hydrology triggered redox alternation between biotic reduction and abiotic oxidation and could accelerate the production of reactive ferrous ions and amorphous ferric oxyhydroxides, making thermodynamically stable iron minerals into redoxactive metastable iron phases (RAMPs) with reduced crystallinity and promoting surface electrochemical activities. Those RAMPs displayed enhanced redox activity for ROS production. Investigations of nationwide coastal soils verified that tide-induced redox oscillations could ubiquitously activate soils for enhanced ROS production. Our study demonstrates the effective formation of RAMPs from redox oscillations by hydrological perturbations, which provides new insights into natural ROS sources.

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Section: Resultsmentioning

confidence: 92%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

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Redox Oscillations Activate Thermodynamically Stable Iron Minerals for Enhanced Reactive Oxygen Species Production

Zhao

Tan

et al. 2023

Environ. Sci. Technol.

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“…Huminicki and Rimstidt 21 proposed that the formation of iron oxide surface layers during pyrite oxidation is originated from the growth of deposited Fe oxyhydroxide colloids and it occurs only if the growth rate of these colloids exceeds approximately ∼10 −8 mol•s −1 , which is consistent with our recent study. 22 Accordingly, the modification of iron oxide shell layers on pyrite surfaces is inseparable from necessary artificial intervention.…”

Section: Introductionmentioning

confidence: 99%

“…Note: Unless otherwise specified, all experiments were repeated three times and error bars in all figures represented the standard error between the results of parallel experiments. The determination of the characteristic peak in XPS S2p and Fe 2p 3/2 spectra and the corresponding reference is presented in our previous study 22.…”

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confidence: 99%

Surface-Modified Pyrite with a Schwertmannite Shell: Enhancing the Application Performance of Pyrite-Mediated Advanced Oxidation Processes in a Continuous-Flow System

Zhao

Liu

et al. 2023

ACS EST Eng.

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Most of the current pyrite-based advanced oxidation processes (AOPs) rely on a homogeneous catalytic mechanism mediated by leached Fe 2+ /Fe 3+ from pyrite oxidation. While in continuous-flow water treatment processes, the continual Fe 2+ /Fe 3+ efflux limits pyrite dissolution and the corresponding hydroxyl radical ( • OH) generation for contaminant degradation. To solve this bottleneck problem, a pyrite−schwertmannite (Sch) binary mineral named Sch@py(1:5) was prepared through a simple chemical method where Sch serves as a surface shell coating on the pyrite core. Compared to the pyrite−H 2 O 2 system, the Sch@py(1:5)−H 2 O 2 system exhibits significantly slighter iron leaching and was verified to possess a heterogeneous Fenton process dominant • OH generation pathway, thereby eliminating the reliance of the Sch@py(1:5)−H 2 O 2 system on Fe 2+ /Fe 3+ concentrations in water. Through shielding H 2 O 2 from being directly decomposed by pyrite and the associated Fenton sludge, the Sch−pyrite core−shell structure improves the utilization efficiency of H 2 O 2 5.18 times and 1.15 times than that of the pyrite−H 2 O 2 system in the presence and absence of 0.21 g of Fe•L −1 Fenton sludge, respectively. Furthermore, the Sch shell endows pyrite with the coupling oxidation and adsorption capacity for organoarsenic-bearing contaminants, thus enabling the Sch@py(1:5)-filled fixed bed to purify 2451 BV of highly concentrated (0.1 mg of As•L −1 ) organoarsenic wastewater at a flow rate of 30 BV•h −1 . This study provides a novel strategy to improving the application potential of pyrite, the commonly existing but underutilized mineral resource, in practical water treatment processes.

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Photo-transformation of nitrate and fulvic acid driven by guest iron minerals

Huang,

Chen,

Yuan

et al. 2024

Front. Environ. Sci. Eng.

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Redox Behavior of Secondary Solid Iron Species and the Corresponding Effects on Hydroxyl Radical Generation during the Pyrite Oxidation Process

Cited by 36 publications

References 52 publications

Redox Oscillations Activate Thermodynamically Stable Iron Minerals for Enhanced Reactive Oxygen Species Production

Redox Oscillations Activate Thermodynamically Stable Iron Minerals for Enhanced Reactive Oxygen Species Production

Surface-Modified Pyrite with a Schwertmannite Shell: Enhancing the Application Performance of Pyrite-Mediated Advanced Oxidation Processes in a Continuous-Flow System

Photo-transformation of nitrate and fulvic acid driven by guest iron minerals

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