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Abstract

Addition of nanoscale zero valent iron (NZVI) to anaerobic batch reactors to enhance methanogenic activity is described. Two NZVI systems were tested: a commercially available NZVI (cNZVI) slurry and a freshly synthesized NZVI (sNZVI) suspension that was prepared immediately before addition to the reactors. In both systems, the addition of NZVI increased pH and decreased oxidation/reduction potential compared with unamended control reactors. Biodegradation of a model brewery wastewater was enhanced as indicated by an increase in chemical oxygen demand removal with both sNZVI and cNZVI amendments at all concentrations tested (1.25–5.0 g Fe/L). Methane production increased for all NZVI-amended bioreactors, with a maximum increase of 28% achieved on the addition of 2.5 and 5.0 g/L cNZVI. Addition of bulk zero-valent iron resulted in only a 5% increase in methane, indicating the advantage of using the nanoscale particles. NZVI amendments further improved produced biogas by decreasing the amount of CO₂ released from the bioreactor by approximately 58%. Overall, addition of cNZVI proved more beneficial than the sNZVI at equal iron concentrations, due to decreased colloidal stability and larger effective particle size of sNZVI. Although some have reported cytotoxicity of NZVI to anaerobic microorganisms, work presented here suggests that NZVI of a certain particle size and reactivity can serve as an amendment to anaerobic digesters to enhance degradation and increase the value of the produced biogas, yielding a more energy-efficient anaerobic method for wastewater treatment.

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References

Auffan

, Achouak

, Rose

, Roncato

M.-A.

, Chanéac

, Waite

D.T.

, Masion

, Woicik

J.C.

, Wiesner

M.R.

, and Bottero

J.-Y.

(2008). Relation between the redox state of iron-based nanoparticles and their cytotoxicity toward Escherichia coli. Environ. Sci. Technol., 42, 6730.

Batstone

D.J.

, and Virdis

(2014). The role of anaerobic digestion in the emerging energy economy. Curr. Opin. Biotechnol., 27, 142.

Cirtiu

C.M.

, Raychoudhury

, Ghoshal

, and Moores

(2011). Systematic comparison of the size, surface characteristics and colloidal stability of zero valent iron nanoparticles pre- and post-grafted with common polymers. Colloids Surf. A, 390, 95.

Diao

, and Yao

(2009). Use of zero-valent iron nanoparticles in inactivating microbes. Water Res., 43, 5243.

Fajardo

, Ortíz

L.T.

, Rodríguez-Membibre

M.L.

, Nande

, Lobo

M.C.

, and Martin

(2012). Assessing the impact of zero-valent iron (ZVI) nanotechnology on soil microbial structure and functionality: A molecular approach. Chemosphere, 86, 802.

Haohao

, Jun-Jie

, Wamer

W.G.

, Mingyong

, and Martin Lo

(2014). Reactive oxygen species-related activities of nano-iron metal and nano-iron oxides. J. Food Drug Anal., 22, 86.

Heuer

J.K.

, and Stubbins

J.F.

(1999). An XPS characterization of FeCO₃ films from CO₂ corrosion. Corrosion Sci., 41, 1231.

Kim

J.Y.

, Park

H.J.

, Lee

, Nelson

K.L.

, Sedlak

D.L.

, and Yoon

(2010). Inactivation of Escherichia coli by nanoparticulate zerovalent iron and ferrous ion. Appl. Environ. Microbiol., 76, 7668.

Lee

, Kim

J.Y.

, Lee

W.I.

, Nelson

K.L.

, Yoon

, and Sedlak

D.L.

(2008). Bactericidal effect of zero-valent iron nanoparticles on Escherichia coli. Environ. Sci. Technol., 42, 4927.

10.

Liu

, Zhang

, Quan

, Chen

, and Zhao

(2011). Applying an electric field in a built-in zero valent iron—Anaerobic reactor for enhancement of sludge granulation. Water Res., 45, 1258.

11.

Mueller

N.C.

, Braun

, Bruns

, Černík , Rissing

, Rickerby

, and Nowack

(2013). Application of nanoscale zero valent iron (NZVI) for groundwater remediation in Europe. Environ. Sci. Pollut. Res. Int., 19, 550.

12.

Němeček

, Lhotský

, and Cajthaml

(2014). Nanoscale zero-valent iron application for in situ reduction of hexavalent chromium and its effects on indigenous microorganism populations. Sci. Total Environ. 485–486, 739.

13.

Park

S.K.

, Jang

H.M.

, Ha

J.H.

, and Park

J.M.

(2014). Sequential sludge digestion after diverse pre-treatment conditions: Sludge removal, methane production and microbial community changes. Bioresour. Technol., 162, 331.

14.

Phenrat

, Liu

, Tilton

R.D.

, and Lowry

G.V.

(2009). Adsorbed polyelectrolyte coatings decrease Fe(0) nanoparticle reactivity with TCE in water: Conceptual model and mechanisms. Environ. Sci. Technol., 43, 1507.

15.

Phenrat

, Saleh

, Sirk

, Tilton

R.D.

, and Lowry

G.V.

(2007). Aggregation and sedimentation of aqueous zerovalent iron dispersions. Environ. Sci. Technol., 41, 284.

16.

Pobeheim

, Munk

, Johansson

, and Guebitz

G.M.

(2010). Influence of trace elements on methane formation from a synthetic model substrate for maize silage. Bioresour. Technol., 101, 836.

17.

Rajeshwari

K.V.

, Balakrishnan

, Kansal

, Lata

, and Kishore

V.V.N.

(2000). State-of-the-art anaerobic digestion technology for industrial wastewater treatment. Renew. Sustain. Energy Rev., 4, 135.

18.

Shah

F.A.

, Mahmood

, Rashid

, Pervez

, Raja

I.A.

, and Shah

M.M.

(2015). Co-digestion, pretreatment and digester design for enhanced methanogenesis. Renew. Sustain. Energy Rev., 42, 627.

19.

Teo

C.W.

, and Wong

P.C.Y.

(2014). Enzyme augmentation of an anaerobic membrane bioreactor treating sewage containing organic particulates. Water Res., 48, 335.

20.

Wang

, Kanel

, Park

, Ryu

, and Choi

(2009). Controllable synthesis, characterization, and magnetic properties of nanoscale zerovalent iron with specific high Brunauer–Emmett–Teller surface area. J. Nanopart. Res., 11, 749.

21.

Xiu

Z.M.

, Jin

Z.H.

, Li

T.L.

, Mahendra

, Lowry

G.V.

, and Alvarez

P.J.J.

(2010). Effects of nano-scale zero-valent iron particles on a mixed culture dechlorinating trichloroethylene. Bioresour. Technol., 101, 1141.

22.

Yan

, Lien

H.-L.

, Koel

B.E.

, and Zhang

W.-X.

(2013). Iron nanoparticles for environmental clean-up: Recent developments and future outlook. Environ. Sci. Process Impacts, 15, 63.

23.

Yan

, Ramos

M.A.V.

, Koel

B.E.

, and Zhang

W.-X.

(2012). As(III) sequestration by iron nanoparticles: Study of solid-phase redox transformations with x-ray photoelectron spectroscopy. J. Phys. Chem. C, 116, 5303.

24.

Yang

, Guo

, and Hu

(2013). Impact of nano zero valent iron (NZVI) on methanogenic activity and population dynamics in anaerobic digestion. Water Res., 47, 6790.

25.

Zhang

, He

, Tian

, Mao

, Tang

, Zhang

, and Zhang

(2011a). Enhancement of methane production from cassava residues by biological pretreatment using a constructed microbial consortium. Bioresour. Technol., 102, 8899.

26.

Zhang

, Jing

, Quan

, Liu

, and Onu

(2011b). A built-in zero valent iron anaerobic reactor to enhance treatment of azo dye wastewater. Water Sci. Technol., 63, 741.

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Enhanced Biogas Production from Nanoscale Zero Valent Iron-Amended Anaerobic Bioreactors

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