Biological methanation (also: biological hydrogen methanation (BHM) or microbiological methanation) is a conversion process to generate

methane Methane ( , ) is a chemical compound with the chemical formula (one carbon atom bonded to four hydrogen atoms). It is a group-14 hydride, the simplest alkane, and the main constituent of natural gas. The abundance of methane on Earth makes ...

by means of highly specialized microorganisms (

Archaea Archaea ( ) is a Domain (biology), domain of organisms. Traditionally, Archaea only included its Prokaryote, prokaryotic members, but this has since been found to be paraphyletic, as eukaryotes are known to have evolved from archaea. Even thou ...

) within a technical system. This process can be applied in a

power-to-gas Power-to-gas (often abbreviated P2G) is a technology that uses electric power to produce a gaseous fuel. Most P2G systems use electrolysis to produce hydrogen. The hydrogen can be used directly, or further steps (known as two-stage P2G systems) ...

system to produce biomethane and is appreciated as an important storage technology for

variable renewable energy Variable renewable energy (VRE) or intermittent renewable energy sources (IRES) are renewable energy sources that are not dispatchable due to their fluctuating nature, such as wind power and solar power, as opposed to controllable renewable ener ...

in the context of

energy transition An energy transition (or energy system transformation) is a major structural change to energy supply and consumption in an energy system. Currently, a transition to sustainable energy is underway to limit climate change. Most of the sustainab ...

. This technology was successfully implemented at a first power-to-gas plant of that kind in the year 2015.

Disambiguation

Biological methanation contains the principle of the so-called

methanogenesis Methanogenesis or biomethanation is the formation of methane coupled to energy conservation by microbes known as methanogens. It is the fourth and final stage of anaerobic digestion. Organisms capable of producing methane for energy conservation h ...

, a specific, anaerobic metabolic pathway where

hydrogen Hydrogen is a chemical element; it has chemical symbol, symbol H and atomic number 1. It is the lightest and abundance of the chemical elements, most abundant chemical element in the universe, constituting about 75% of all baryon, normal matter ...

and carbon dioxide are converted into methane. By analogy with the biological process, a chemical-catalytic process, also known as

Sabatier reaction The Sabatier reaction or Sabatier process produces methane and water from a reaction of hydrogen with carbon dioxide at elevated temperatures (optimally 300–400 °C) and pressures (perhaps ) in the presence of a nickel catalyst. It was di ...

, exists.

Principle of function

Numerous and common microorganisms within the domain Archaea convert the compounds hydrogen (H₂) and carbon dioxide (CO₂) into methane in a bio-catalytic way. The therefore relevant metabolic processes run under strictly anaerobic conditions and in an aqueous environment. :

\mathrm \qquad \Delta G^ = -1360 \, \frac

Suitable Archaea for this process are so called Methanogens with a hydrogenotrophical metabolism. They are primary to be allocated among the order of

Methanopyrales ''Methanopyrus'' is a genus of methanogen, with a single described species, ''Methanopyrus kandleri''. It is a rod-shaped hyperthermophile, discovered on the wall of a black smoker from the Gulf of California at a depth of 2,000 m, at temper ...

Methanobacteriales Methanobacteriales is an order of archaeans in the class Methanobacteria. Species within this order differ from other methanogens in that they can use fewer catabolic substrates and have distinct morphological characteristics, lipid compositions ...

Methanococcales Methanococcales is an order of archaeans in the class Methanococci. Phylogeny The currently accepted taxonomy is based on the List of Prokaryotic names with Standing in Nomenclature (LPSN) and National Center for Biotechnology Information (NCBI ...

and Methanomicrobiales. These Methanogens are naturally adapted for different anaerobic environments and conditions. Basically, the Methanogens need aqueous, anoxic conditions with min. 50% water and a redox potential of less than −330 mV. The Methanogens prefer lightly acidic to alkali living conditions and are found in a very wide temperature range from 4 to 110 °C.

Reactor types

The most common utilized reactor type for biological methanation is the stirred-tank reactor in which the mass transfer is influenced by several factors such as geometry of the reactor, impeller configuration, the agitation speed and the gas flow rate. Additionally, less investigated reactor types like Trickle-bed reactors, bubble-column reactors and gas-lift reactors have specific drawbacks and advantages regarding the abovementioned limitations.

Potential applications of biological methanation

Biological methanation can take place as an

in-situ is a Latin phrase meaning 'in place' or 'on site', derived from ' ('in') and ' ( ablative of ''situs'', ). The term typically refers to the examination or occurrence of a process within its original context, without relocation. The term is use ...

process within a fermenter (see fig. 3.1) or as an ex-situ process in a separate reactor (see fig. 3.2 to 3.4). Biological methanation in a biogas or clarification plant with a gas processing system (in-situ process) Hydrogen is added directly to the fermentation material during a fermentation process and the biological methanation takes place subsequently in the thoroughly gassed fermentation material. The gas is, depending on its pureness, cleaned up to methane before the infeed into the gas grid. Biological methanation takes place in a separate methanation plant. The gas is completely converted into methane before the infeed into the gas grid. The carbon dioxide, produced in a gas processing system, is converted into methane in a separate methanation plant, by adding hydrogen and can then be fed into the gas grid. Biological methanation in combination with an arbitrary carbon dioxide source (ex-situ process) In a separate methanation plant the hydrogen is converted into methane together with carbon dioxide and then fed into the gas grid (stand-alone solution). Biological methanation in a pressurized reactor vessel (in-situ process). Pressure allows for better hydrogen solubility and therefore easier conversion into methane by microorganisms. A possible reactor configuration can be Autogenerative high-pressure digestion. Research in Korea has demonstrated that 90% > CH4, 180 MJ/m3 biogas can be produced in this way.

Implementation in the field

Since March 2015 the first power-to-gas plant globally is feeding synthetical bio methane, generated by means of biological methanation, into the public gas grid in

Allendorf (Eder) Allendorf (Eder) () is a municipality which situated in the north west of Hesse, Germany. The municipality is within the Waldeck-Frankenberg district in a rural region called the upper Eder (Fulda), Eder Valley. The Burgwald range is located wes ...

, Germany. The plant runs with an output rate of 15 Nm3/h, which corresponds to 400,000 kWh per year. With this amount of gas a distance of 750,000 kilometers per year with a CNG-vehicle can be achieved.

References

{{Reflist Biogas technology Methane