Abstract

The performance of a mixed microbial community was tested in lab-scale power-to-methane reactors at 55 °C. The main aim was to uncover the responses of the community to starvation and stoichiometric H2/CO2 supply as the sole substrate. Fed-batch reactors were inoculated with the fermentation effluent of a thermophilic biogas plant. Various volumes of pure H2/CO2 gas mixtures were injected into the headspace daily and the process parameters were followed. Gas volumes and composition were measured by gas-chromatography, the headspace was replaced with N2 prior to the daily H2/CO2 injection. Total DNA samples, collected at the beginning and end (day 71), were analyzed by metagenome sequencing. Low levels of H2 triggered immediate CH4 evolution utilizing CO2/HCO3− dissolved in the fermentation effluent. Biomethanation continued when H2/CO2 was supplied. On the contrary, biomethane formation was inhibited at higher initial H2 doses and concomitant acetate formation indicated homoacetogenesis. Biomethane production started upon daily delivery of stoichiometric H2/CO2. The fed-batch operational mode allowed high H2 injection and consumption rates albeit intermittent operation conditions. Methane was enriched up to 95% CH4 content and the H2 consumption rate attained a remarkable 1000 mL·L−1·d−1. The microbial community spontaneously selected the genus Methanothermobacter in the enriched cultures.

Highlights

  • The energy needs of civilized human lifestyle and the global population are increasing rapidly

  • The gas composition in the reactor head-space was determined daily by gas chromatography (GC) and after the measurements the reactors were degassed by purging with N2 for 5 min and the internal pressure was adjusted to atmospheric level

  • 3.1.TMheetmhainxoegdenAeDsiscboymHm2uannidtyHw2 a+sCfiOrs2t supplied with various amounts of H2 in order to eleimliminiaTnthaeetethmtehixedeiddsissAosloDvlevcdeodmCCOmO2u/H2n/iCtHyOCw3O−ai3ns−fithirnsettAshuDepAfpeDlriemfdeerwnmtiatehtniotvanatrieoifonfuluesfeaflnmut eo(nFuitng(tuFsrigoeuf1Hr)e.21i)n. order to (FH=i(Fr2g4=,eiu3rdge4.ru5edc3ruv.1ec5/r.uvv1vC%r.e/vu)Cve,Hmu%)4,2m0u,4Hbl0muallm2taaLi,ctvLiknbvelonecabmuocbiormkiivonmicmeanue)laetraHhtlvnhHae2dan)n2vecaevoopnolpnudrlrcuomoomdcdmeouuen(icc=t(ctta=iio3oon31mnn1t.s5.ssi5ttiviaonvn/ni/ctvvttihim%%msitoeoHeHmfirfc22eor,h,otbmibrmolilucm2ue02Cee0cmOcturmu2Lri.rcvLvTneCehon))Omeaoanmc2inno.ddiannT6lt6a0hrH0loem2Hlm,cvLi2oL.oevnnl.nuoo,tromlomuomnelmi,lniy(niea=.dael1(l.Ha=8,Hi1.0lo28y2vnv.0No/lvylvvo2u%/ldgmvuaa%mHeisl2ye, N2 gas replacement of the head-space, is shown in green

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Summary

Introduction

The energy needs of civilized human lifestyle and the global population are increasing rapidly. The majority of this energy is provided currently from fossil energy carriers. Exploitation of fossil sources is associated with greenhouse gas (GHG) emission, which is the primary source of global climate change endangering the biosphere and overall quality of life on Earth. These are the driving forces for the increase of the contribution of renewable energy in the overall energy spectrum. Smart electricity grids and flexible storage technologies are being developed to balance the energy losses and grid imbalances due to the deranged production and utilization of electricity [5]

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