Methane Production and Conductive Materials: A Critical Review

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Critical Review

Methane production and conductive materials: a critical review Gilberto Martins, Andreia Filipa Salvador, Luciana Pereira, and Maria Madalena Alves Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b01913 • Publication Date (Web): 17 Aug 2018 Downloaded from http://pubs.acs.org on August 19, 2018

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Methane production and conductive materials: a critical review

2 Gilberto Martins†*, Andreia F. Salvador†, Luciana Pereira† and M. Madalena Alves†

3 4



Centre of Biological Engineering, University of Minho, Campus de Gualtar, 4710-057 Braga, Portugal

5 6

Abstract

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Conductive materials (CM) have been extensively reported to enhance methane production in

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anaerobic digestion processes. The occurrence of direct interspecies electron transfer (DIET) in

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microbial communities, as an alternative or complementary to indirect electron transfer (via

10

hydrogen or formate), is the main explanation given to justify the improvement of methane

11

production. Not disregarding that DIET can be promoted in the presence of certain CM, it surely

12

does not explain all the reported observations. In fact, in methanogenic environments DIET was

13

only unequivocally demonstrated in cocultures of Geobacter metallireducens with

14

Methanosaeta harundinacea or Methanosarcina barkeri and frequently Geobacter sp. are not

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detected in improved methane production driven systems. Furthermore, conductive carbon

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nanotubes were shown to accelerate the activity of methanogens growing in pure cultures,

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where DIET is not expected to occur, and hydrogenotrophic activity is ubiquitous in full-scale

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anaerobic digesters treating for example brewery wastewaters, indicating that interspecies

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hydrogen transfer is an important electron transfer mechanism in those systems. This paper

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presents an overview of the effect of several iron-based and carbon-based CM in bioengineered

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systems, focusing on the improvement in methane production and in microbial communities’

22

changes. Control assays, as fundamental elements to support major conclusions in reported

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experiments, are critically revised and discussed.

24 25 26 27 *

Corresponding author: Gilberto Martins, Tel.:(+351)253601986; email: [email protected]

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Abstract art

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1. Introduction

33

Methane is a renewable energy source that can be produced in controlled bioengineered systems

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from a wide range of organic substrates including diluted industrial wastewater, animal manure

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or the organic fraction of municipal solid waste, through a process generally called anaerobic

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digestion (AD). Fundamental knowledge and technology developments of AD processes have

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evolved significantly and in parallel in the last decades. The fact that the process relies on the

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activity of slow growing anaerobic microorganisms1 results in low nutrient requirements and

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low amounts of sludge produced, which are strong advantages of the anaerobic treatment

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process. These microorganisms grow slowly because the energy gain from the anaerobic

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metabolism is low and has to be divided by different trophic groups, i.e., the bacteria

42

performing hydrolytic, acidogenesis and acetogenesis reactions, and the methanogens

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converting intermediary degradation products into methane.2

44

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Syntrophic interactions between bacteria and methanogens are the basis to maintain an AD

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system working efficiently. These microorganisms, with distinct, but complementary metabolic

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capabilities, exchange electrons for energy purposes, normally through the transfer of small

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soluble chemical compounds, such as hydrogen or formate, that act as electron shuttles. This

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interspecies hydrogen/formate transfer process is very important since the overall

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thermodynamics depends on the capacity of the microbial communities to maintain a low

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hydrogen partial pressure.3 Thus, diffusion limitations of these metabolites, between anaerobic

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bacteria and methanogenic archaea, can be important bottlenecks in the anaerobic conversion

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process.4,5

54 55

Recent studies proposed that interspecies electron transfer (IET) can also be performed directly

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between bacteria and methanogenic archaea, or with the aid of conductive materials (CM),

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being potentially a more energy conserving approach, and thus improving the rate of

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methanogenesis.6,7 However, clear evidence of direct interspecies electron transfer (DIET) was

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only observed in cocultures of electroactive bacteria, namely Geobacter species, and in

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cocultures of G. metallireducens with Methanosaeta harundinacea3,7 or Methanosarcina

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barkeri.8 Moreover, DIET seems to require outer membrane c-type cytochromes and pili,6,7 but

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traditional syntrophic fatty acid-degrading bacteria (e.g.: Syntrophomonas wolfei and

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Syntrophus aciditrophicus)9 and most methanogens (e.g.: all members of the orders

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Methanopyrales, Methanococcales, Methanobacteriales and Methanomicrobiales)10 lack the

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genes for these cell components. Another indication that not all syntrophic bacteria are capable

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of DIET is the case of Pelobacter carbinolicus, a known syntrophic ethanol oxidizing

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bacterium, that could only establish syntrophic interactions with Geobacter sulfurreducens via

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interspecies hydrogen transfer or interspecies formate transfer,11 although it has been reported to

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contain c-type cytochromes.12

70 71

Notwithstanding these facts, in the past five years, many studies have reported the improvement

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of methane production in anaerobic reactors amended with CM such as magnetite, granular 3 ACS Paragon Plus Environment

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activated carbon (GAC), carbon nanotubes (CNT), and biochar, among others.1,8,21–27,13–20 In

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general, these CM are highly stable, have large surface area, good adsorption capacity and high

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electric conductivity.28–30 Some of these materials may act as redox mediators in microbial

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catalysis of compounds with electrophilic groups, such as dyes.30

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The role of DIET is discussed in recent papers on anaerobic digestion processes amended with

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CM.31–33 The authors of these papers interpret the enhancement of methane production as a

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direct consequence of DIET promoted by CM. However, exploring the results collected from a

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significant number of studies on this topic, turned clear that the effect of CM goes beyond the

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stimulation of DIET.

83 84

In this review, the recent findings on the effect of CM in AD bioengineered systems is

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summarized, exploring how these materials affect methane production rate and the structure of

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anaerobic microbial communities. This is a recent research field with a relevant impact in

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engineered and natural anaerobic microbial processes. Little is known about the mechanisms

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behind the improvement of methane production rates when CM are present. Apart from DIET,

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other elements of knowledge should be considered, and main interpretations of the researchers

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contributing to the knowledge in this field are herein addressed and discussed.

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2. Electron transfer mechanisms in methanogenic environments

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Anaerobic digestion is a biological process, where complex organic compounds are sequentially

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converted to simple compounds, by a wide variety of microorganisms. The rate and the route

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governing electrons transfer among the microbial community, determines the entire process

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efficiency.34–37 Mineralization of waste to methane is dependent on the activity of hydrolytic,

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acidogenic, and acetogenic bacteria, which generate the substrates (i.e., hydrogen, formate and

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acetate) for methanogenic archaea, which ultimately produce methane in AD processes.37–40 IET

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efficiency between syntrophic partners dictates the rates of conversion bioprocesses when

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methanogenic activity is guaranteed. In methanogenic systems microorganisms can transfer 4 ACS Paragon Plus Environment

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electrons between each other: (1) via soluble chemical compounds (e.g., hydrogen, formate and

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acetate) which act as electron shuttles; (2) via other chemicals (e.g., humic substances); (3) via

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direct electron transfer by electrically conductive pili or direct contact; and (4) by direct electron

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transfer mediated by CM (Figure 1). In the following subsections the fundamentals and

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mechanisms of IET are briefly exposed.33,41–43

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107 108

Figure 1. Possible interspecies electron transfer mechanisms in methanogenic environments.42–

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44

110 111 112

2.1. Interspecies electron transfer via soluble molecules

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The most studied and well known mechanism of electron transfer in methanogenic communities

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is the indirect interspecies electron transfer via hydrogen or formate.9,44–46 Syntrophic bacteria

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produce hydrogen or formate as a way to dissipate the reducing power, i.e., the electrons formed

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during the degradation of organic compounds and, in turn, methanogens utilize those molecules

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as electron donors to reduce CO2 to methane (Figure 1A). Therefore, hydrogen/formate act as

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shuttles

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methanogens. At high hydrogen concentrations (>10 Pa), the hydrogenase activity is inhibited

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and consequently the metabolism of syntrophic bacteria is inhibited as well, while that of the

between

hydrogen/formate-forming

bacteria

and

hydrogen/formate-utilizing

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methanogens is stimulated, and vice versa.3,47–49 Formate formation has been detected

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particularly in cocultures growing on proteins,50 or fatty acids like propionate and butyrate.3,51,52

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Under certain conditions, interspecies formate transfer may prevail because formate has a higher

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diffusion coefficient, comparing to hydrogen.53,54 Syntrophic interactions involving hydrogen or

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formate as electron shuttles are well described in cocultures degrading common compounds

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formed during the AD process such as butyrate,55 propionate,56 ethanol,57 and acetate.58

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2.2. Interspecies electron transfer via extracellular compounds

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In numerous anaerobic environments, the interspecies electron transfer can be mediated also by

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insoluble compounds, such as humic acids present in humus.59–62 Unlike soluble electron

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shuttles, such as hydrogen or formate, that can diffuse in and out of the cell,63 insoluble

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compounds do not penetrate the cell surface. Lovley and co-workers64 demonstrated that humus

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can mediate electron transfer between humics-reducing and humics-oxidizing microorganisms

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(Figure 1B). The electron acceptor properties have been related mainly with the redox active

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quinone moieties present in humic substances.65 Several microorganisms were found to reduce

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humic acids or anthraquinone-2,6-disulphonate (AQDS) using hydrogen as electron donor (e.g.,

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the halorespiring bacterium, Desulfitobacterium PCE1, the sulfate-reducing bacterium,

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Desulfovibrio G11 and the methanogenic archaea, Methanospirillum hungatei JF1) or lactate

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(Desulfitobacterium dehalogenans and Desulfitobacterium PCE1).59

140 141

Humus can also be re-oxidized and act as an electron donor. For example, humic acids can be

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redox mediators in the anaerobic substrate oxidation coupled to the abiotic reduction of metal

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oxides such as Fe(III) and Mn(IV), being re-oxidized and participating in many cycles.59 Some

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bacteria of the genus Geobacter have been reported as quinone-reducing microorganisms using

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Fe(III) as the terminal electron acceptor66–69 but other microorganisms share this ability, such as

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some Shewanella, Desulfitobacterium, Desulphuromonas, Geospirillum, Wolinella and

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Geothrix69 and the methanogenic archaea Methanopyrus kandleri, Methanobacterium

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thermoautotrophicum.70 The anaerobic oxidation of lactate and hydrogen by Desulfitobacterium

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dehalogenans was obtained with AQDS as mediator, associated to the reduction of goethite.59

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2.3. Direct interspecies electron transfer

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Recently, DIET has been described in anaerobic environments, involving the formation of an

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electric current between electron-donating and electron-accepting microbes (Figure 1C)42,43,71,72

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and without the need to produce and exchange electron carriers (i.e., hydrogen and formate).

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DIET is analogous to direct extracellular electron transfer, which consists in the electron

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transfer between cells and a solid-state electron acceptor such as iron and manganese oxides or

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electrodes.73 DIET is well studied in bacteria belonging to the genera Shewanella and

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Geobacter,42,43,71,72 which are highly efficient in dealing with solid extracellular electron

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acceptors. DIET was first described in defined cocultures of G. metallireducens, an ethanol

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oxidizing bacteria, and G. sulfurreducens, a fumarate reducing bacteria.71

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microorganisms establish a syntrophic relationship, via hydrogen interspecies electron transfer,

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with G. metallireducens converting ethanol to hydrogen and G. sulfurreducens using hydrogen

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as electron donor for fumarate reduction. The ability of this culture for performing DIET was

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discovered when cocultures formed with G. sulfurreducens strains lacking the hyb gene (thus

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unable to utilize hydrogen), were able to oxidize ethanol and to reduce fumarate. Under these

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conditions, interspecies electron exchange between G. metallireducens and G. sulfurreducens

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occurred directly via conductive pili and without the formation of soluble intermediates.71

These

168 169

More recently, it was shown that DIET can occur in cocultures of Geobacter species and

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acetoclastic methanogens (i.e., Methanosaeta and Methanosarcina species).6,8 Rotaru and co-

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workers6 showed that Methanosaeta harundinacea, a strictly acetoclastic methanogen, can

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receive electrons directly from G. metallireducens to produce methane. The idea that

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Methanosaeta species are acetoclastic specialists, only producing methane from acetate,

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changed from this point on, since it seems to be able to activate the CO2 reduction pathway for

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methane production. In this context, the electrons released by Geobacter species are transferred, 7 ACS Paragon Plus Environment

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via pili, directly to Methanosaeta, but the cell machinery involved in electrons uptake by the

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methanogen is not yet known.6 These findings gave a new perspective on the interspecies

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interactions taking place in anaerobic bioreactors producing methane.

179 180

2.4. DIET promoted by conductive materials

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The presence of CM such as GAC, carbon cloth and biochar appears to promote DIET via a

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conduction-based mechanism, in which electrons migrate through the CM from electron-

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donating to electron-accepting cells.20,22,74

184 185

Surprisingly, it was observed that the lack of pili and other cell component involved in the

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exogenous electron transfer can be compensated by the presence of CM, namely GAC,8 carbon

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cloth74 and biochar.22 This was verified in defined cocultures of pilA-deficient strains of G.

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metallireducens with Methanosarcina barkeri, which could not convert ethanol to methane

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unless in the presence of CM. This methanogenic coculture in the presence of biochar were able

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to utilize 86% of the electrons released from ethanol oxidation for methane production, but

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without biochar no ethanol was consumed and no methane was produced.22 Similarly, the lack

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of the pilin-associated c-type cytochrome (OmcS), necessary for extracellular electron transfer

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in Geobacter species, could be compensated by magnetite, another conductive material.75

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Without magnetite Geobacter strains lacking genes for OmcS were ineffective in forming viable

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cocultures,71 but in the presence of magnetite, the OmcS-deficient mutants performed similarly

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to the wild type.75

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2.5. Hydrogen and formate IET versus DIET

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An interesting approach towards the clarification of the importance of DIET in methanogenesis

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was presented by Storck and co-workers73 who proposed a mechanistic framework that enabled

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the direct assessment of the relative feasibility of DIET, and mediated interspecies electron

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transfer (MIET) in a thermodynamically restricted syntrophic system (propionate conversion to

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acetate and methane), through mathematical modelling. They found that DIET could be more 8 ACS Paragon Plus Environment

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favorable than hydrogen-MIET, but substantially less favorable than formate-MIET (1 order of

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magnitude rate difference), assuming a default parameter set based on literature data. The model

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results also suggested that DIET may be a thermodynamically more feasible alternative to

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MIET for disperse communities limited by diffusion, which is contrary to experimental

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observations where nanowire-DIET is commonly observed in dense aggregates,6,8,71 possibly

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indicating that co-evolution and co-metabolism are more important than external limitations in

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the simulated system.73 These authors also suggested that CM reduce resistivity, and leave only

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activation losses, making long-range transport even more feasible.

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3. Effect of conductive materials on methane production

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3.1. CM improving methane production

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Several strategies have been implemented to improve AD. Empirical modification of process

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design, operational conditions, and application of substrate pre-treatments, such as

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microaeration, thermal and mechanical treatments are some examples.1,76,77 Recently, several

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authors have been reporting the enhancement of methane production by the use of CM (Figure

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2a), which is now considered a strategy to improve methane production efficiency and stability

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of anaerobic reactors.7,20 The type of conductive material, the microbial substrates, the mode of

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operation and the main results reported in scientific communications are summarized in Table 1

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and Table S1. In general, lag phases preceding methane production are reduced and methane

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production rates increase when CM are added to batch experiments.8,16,18–20,27,74,78,79 In

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continuous anaerobic digesters, CM also accelerate methane production and contribute for a

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more stable operation, allowing higher applied organic loading rates while maintaining high

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COD removal rates.21,80–83

228 229

Table 1. Summary of the studies reporting the enhancement of methane production by CM Conductive material

Particle size / µm

Applied concentration / g/L

Common substrates

Methane improvement*

Reference

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Conductive material

Particle size / µm

Applied concentration / g/L

Common substrates

Methane improvement*

Ferric oxyhydroxide

1 to 2

1.8

Real dairy wastewater

2.0

1

Magnetite

0.01 to 0.3

0.01 to 25

1.3 to 3.6

24, 25, 27, 78,

Iron oxide nanoparticles Ferroferric oxide Ferrihydrite

0.02

0.8

0.01 to 0.3 ~0.03

10 3.4 to 4.2

Hematite

0.02 to 0.3

0.022 to 10.9

Iron powder Nanoscale zero valent iron

0.001 to 0.1

10

Acetate, Ethanol, Benzoate, Butyrate, Propionate, Real and synthetic dairy wastewater Beet sugar industrial wastewater Synthetic wastewater Acetate, Ethanol Acetate, Ethanol, Benzoate, Sludge Sludge

0.02 to 10.9

Red mud

-

Reference

1, 16, 17, 23,

83, 84, 85, 86

1.3

87

1.2 to 1.8 1.1

14, 88

1.3 to 2.2

24, 25, 84, 89

1.4

90

Sludge

1.3 to 2.2

89, 90

20

Activated sludge from municipal WWTP

1.4

91

24

500 to 2000 0.07 to 1.5

25.7

Synthetic wastewater

1.3

92

2 to 8

Synthetic wastewater

4.4

93

0.25 to 3

1.2

Sucrose

2.0

94

-

0.03 to 2.0

1.2 to 1.5

95, 96

Multi-walled CNT

0.010 to 0.2

0.1 to 5.0

Ethanol, Synthetic wastewater H2/CO2, Acetate, Butyrate, Beet sugar industrial wastewater

1.1 to 17

16, 18, 87

Single-walled CNT

0.001

1.0

Sucrose, Glucose

1.8 to 2

79, 97

Graphite

6 to 25

12 to 132 graphite rods

1.0 to 1.3

13, 80

GAC

841 to 2000

3.3 to 50

Synthetic complex waste and wastewater Acetate, Ethanol, Butyrate, Propionate, Glucose, Synthetic brewery wastewater, Synthetic dairy wastewater, Activated sludge, Organic fraction of municipal solid waste, Synthetic complex waste

1.1 to 18

20, 21, 79, 83,

Powered activated carbon

149 to 177

5

Synthetic brewery wastewater

n.a.

21

Carbon felt

-

3 to 30 pieces

Synthetic wastewater (glucose), and Synthetic complex waste

1.1

13, 101

Stainless steel Manganese Polyaniline nanorods Graphene

230 231

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Ethanol, Synthetic wastewater, Leachate from municipal solid waste incineration, Carbon cloth 10 to 20 pieces Organic fraction of municipal solid, waste, Synthetic complex waste Ethanol, Butyrate, Propionate, Biochar 60 to 700 0.3 to 42.7 Sludge, Synthetic wastewater * – Number of times that methane production increases relative to the control

8, 13, 15, 19,

98, 99, 100

13, 19, 74, 80,

1.1 to 10

81, 102

22, 80, 82, 103,

1.2 to 1.3

104

232 233

Only few studies used direct methanogenic substrates, such as acetate or H2/CO2,18,24,84,85,98

234

while most studies used volatile fatty acids, such as butyrate and propionate, and alcohols as

235

substrates to promote the syntrophic metabolism within microbial communities.8,16–18,20,22–

236

24,78,79,82,85,96,100

More complex organic matter, such as dairy wastewater,1,83,86 brewery 10 ACS Paragon Plus Environment

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wastewater,20 beet sugar wastewater,87 food waste,13 municipal solid waste,19 waste activated

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sludge89,90,99,103,104 or leachate81 have also been investigated. When compared to control

239

conditions, the addition of CM to bioreactors treating these complex wastewaters resulted in

240

less accumulation of VFAs, thus improving the efficiency of the AD process.

241 242

GAC and magnetite were the most common CM applied in AD systems, followed by CNT,

243

carbon cloth and biochar (Figure 2/Table 1).

244

245 246

Figure 2. Number of studies reporting the effect of different types of CM on methane

247

production.

248 249 250

3.2. CM inhibiting methane production

251

From all CM tested, magnesium oxide, silver nanoparticles, ferrihydrite and carbon black

252

(amorphous carbon) were the only ones inhibiting methanogenesis (Table 2).

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Table 2. Summary of the studies reporting the inhibition of methane production by CM Conductive material

Particle size / µm

Applied concentration / g/L

Substrate

Methane inhibition*

Ferrihydrite

~0.03

2.2 to 4.2

Acetate, Ethanol

1.9 to 4.3

24, 84

Magnesium oxide