Difference between revisions of "Iron filings (ZVI)"

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===Benefits===
 
===Benefits===
 
A study was done that compared the phosphorus reduction capabilities of ZVI, [[biochar]], biochar-supported ZVI (ZVI/BC), and biochar-supported nZVI (nZVI/BC) (Rossetti, 2017)<ref name=Rossetti/>. It was found that nZVI/BC had the highest phosphorus reduction. Using biochar-supported ZVI or nZVI improves the dispersion and stability of the iron filings. Biochar is fine-grained and highly porous, providing a large surface area to support nZVI.
 
A study was done that compared the phosphorus reduction capabilities of ZVI, [[biochar]], biochar-supported ZVI (ZVI/BC), and biochar-supported nZVI (nZVI/BC) (Rossetti, 2017)<ref name=Rossetti/>. It was found that nZVI/BC had the highest phosphorus reduction. Using biochar-supported ZVI or nZVI improves the dispersion and stability of the iron filings. Biochar is fine-grained and highly porous, providing a large surface area to support nZVI.
Another paper reports that ZVI can remove up to 98% of influent phosphorus at low input concentrations, and at high concentrations is shown to remove up to 36% of incoming phosphorus. The phosphorus retained in the soil is mostly iron-bound, which will not be easily leached out of the system because it is very stable (Lechner, 2016).<ref name = Lechner></ref>  
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Another paper reports that ZVI can remove up to 98% of influent phosphorus at low input concentrations, and at high concentrations is shown to remove up to 36% of incoming phosphorus. The phosphorus retained in the soil is mostly iron-bound, which will not be easily leached out of the system because it is very stable (Lechner, 2016)<ref name = Lechner></ref>.
 
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Back to [[additives]].
 
Back to [[additives]].

Latest revision as of 15:38, 19 August 2025

ZVI

What is it?[edit]

Iron filings or zero-valent iron (ZVI) is the elemental form of iron with a zero charge carried by each atom – a result of the outer valence level being filled. ZVI is able to remove dissolved phosphorus (phosphate) from solution through precipitation (Rossetti, 2017)[1]. Zero-valent iron nanoparticles (nZVI) are also used for phosphorus removal.

How is it being used?[edit]

  • A field study in Maplewood, Minnesota used an iron-enhanced (5% iron filings) ditch check sand filter for installation in swales to provide treatment of dissolved heavy metals and dissolved phosphorous in stormwater runoff from highways (Ahmed at el., 2014) [2].
  • In Ajax, Ontario, iron filings were tested as an additive in bioretention areas and compared against two alternatives: a bioretention area with 5% sorbtive media, and a typical engineered media bed consisting of a shredded hardwood mulch layer over a sand–soil–organic mixture. Phosphorus concentrations were lowest in the sorbtive media mix, followed by the iron filing mix, while the typical media bed had the poorest removal performance (Aquafor Beech, 2018)[3].
Bioretention schematic, with circles highlighting ZVI addition and phosphorus removal (Lechner, 2016)[4].

Benefits[edit]

A study was done that compared the phosphorus reduction capabilities of ZVI, biochar, biochar-supported ZVI (ZVI/BC), and biochar-supported nZVI (nZVI/BC) (Rossetti, 2017)[1]. It was found that nZVI/BC had the highest phosphorus reduction. Using biochar-supported ZVI or nZVI improves the dispersion and stability of the iron filings. Biochar is fine-grained and highly porous, providing a large surface area to support nZVI. Another paper reports that ZVI can remove up to 98% of influent phosphorus at low input concentrations, and at high concentrations is shown to remove up to 36% of incoming phosphorus. The phosphorus retained in the soil is mostly iron-bound, which will not be easily leached out of the system because it is very stable (Lechner, 2016)[4].

Back to additives.

  1. 1.0 1.1 Rossetti M. 2017. Evaluation of phosphorous removals by biochar supported nano-scale zero-valent iron. Chemical Engineering Undergraduate Honors Thesis.
  2. Ahmed, F., Natarajan, P., Gulliver, J., Weiss, P., Nieber, J. 2014. Assessing and Improving Pollution Prevention by Swales. https://www.lrrb.org/pdf/201430.pdf
  3. Aquafor Beech Ltd. 2018. Monitoring Report (2015–2017): Rain Garden Performance Monitoring Program: Lake Driveway. https://www.ajax.ca/en/get-involved/resources/Stormwater/Rain-Garden-Performance-Monitoring-Program-Lake-Driveway.pdf
  4. 4.0 4.1 Lechner L. 2016. Phosphorus Removal From Stormwater Using Zero-Valent Iron. Applied Science Masters Thesis.

Any form of rain or snow.

A long narrow trench or furrow dug in the ground, as for irrigation, drainage, or a boundary line.

Mineral particles which are smaller than 2 mm, and which are free of appreciable quantities of clay and silt. Coarse sand usually designates sand grains with particle size between 0.2 and 0.02 mm.

A shallow excavated surface depression containing prepared filter media, mulch, and planted with selected vegetation.

a top dressing over vegetation beds that provides suppresses weeds and helps retain soil moisture in bioretention cells, stormwater planters and dry swales.

A shallow constructed channel, often grass-lined, which is used as an alternative to curb and channel, or as a pretreatment to other measures. Swales are generally characterized by a broad top width to depth ratio and gentle grades.

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