Electromethanogenesis is a form of

electrofuel Electrofuels, also known as e-fuels, are a class of synthetic fuels which function as drop-in replacement fuels for internal combustion engines. They are manufactured using captured carbon dioxide or carbon monoxide, together with Hydrogen fuel, ...

production where

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 ...

is produced by direct biological conversion of

electrical current Electricity is the set of physical phenomena associated with the presence and motion of matter possessing an electric charge. Electricity is related to magnetism, both being part of the phenomenon of electromagnetism, as described by Maxwel ...

and

carbon dioxide Carbon dioxide is a chemical compound with the chemical formula . It is made up of molecules that each have one carbon atom covalent bond, covalently double bonded to two oxygen atoms. It is found in a gas state at room temperature and at norma ...

. Methane producing technologies garnered interest from the scientific community prior to 2000, but electromethanogenesis did not become a significant area of interest until 2008. Publications concerning catalytic methanation increased from 44 to over 130 between 2008 and 2017. Electromethanogenesis has drawn more research due to its proposed applications. The production of methane from electrical current may provide an approach to renewable energy storage. Electrical current produced from

renewable energy sources Renewable energy (also called green energy) is energy made from renewable natural resources that are replenished on a human timescale. The most widely used renewable energy types are solar energy, wind power, and hydropower. Bioenergy and ...

may, through electromethanogenesis, be converted into methane which may then be used as a

biofuel Biofuel is a fuel that is produced over a short time span from Biomass (energy), biomass, rather than by the very slow natural processes involved in the formation of fossil fuels such as oil. Biofuel can be produced from plants or from agricu ...

. It may also be a useful method for the capture of carbon dioxide which may be used for air purification. In nature, methane formation occurs biotically and abiotically. Abiogenic methane is produced on a smaller scale and the required chemical reactions do not necessitate

organic materials Organic matter, organic material or natural organic matter is the large source of carbon-based compounds found within natural and engineered, terrestrial, and aquatic environments. It is matter composed of organic compounds that have come fro ...

. Biogenic methane is produced in

anaerobic Anaerobic means "living, active, occurring, or existing in the absence of free oxygen", as opposed to aerobic which means "living, active, or occurring only in the presence of oxygen." Anaerobic may also refer to: *Adhesive#Anaerobic, Anaerobic ad ...

natural environments where methane forms as the result of the breakdown of organic materials by

microbes A microorganism, or microbe, is an organism of microscopic size, which may exist in its single-celled form or as a colony of cells. The possible existence of unseen microbial life was suspected from antiquity, with an early attestation in ...

—or microorganisms. Researchers have found that the biogenic methane production process can be replicated in a laboratory environment through electromethanogenesis. The reduction of CO₂ in electromethanogenesis is facilitated by an electrical current at a biocathode in a microbial electrolysis cell (MEC) and with the help of microbes and electrons (Equation 1) or abiotically produced hydrogen (Equation 2). (1) CO₂ + 8H⁺ + 8e⁻ ↔ CH₄ + 2H₂O (2) CO₂ + 4H₂ ↔ CH₄ + 2H₂O

Biocathode

A biocathode is a cathode used in a microbial electrolysis cell during electromethanogenesis that utilizes microorganisms to catalyze the process of accepting electrons and protons from the anode. A biocathode is usually made of a cheap material, such as carbon or graphite, like the anode in the MEC. The microbe population that is placed on the biocathode must be able to pick up electrons from the electrode material (carbon or graphite) and convert those electrons to hydrogen.

Mechanism

The mechanism of electromethanogenesis is outlined in Figure 1. Water is introduced into the system with the anode, biocathode, and microbes. At the anode, microbes attract H₂O molecules which are then oxidized after an electrical current is turned on from the power source. Oxygen is released from the anode side. The protons and electrons oxidized from the H₂O move across the membrane where they move into the material that makes up the biocathode. The new microbe on the biocathode has the ability to transfer the new electrons from the biocathode material and convert them into protons. These protons are then used in the major pathway that drives methane production in electromethanogenesis—CO₂ reduction. CO₂ is brought in on the biocathode side of the system where it is reduced by the protons produced by the microorganisms to yield H₂O and methane (CH₄⁺). Methane is produced and can then be released from the biocathode side and stored.

Limitations

One limitation is the energy loss in methane-producing bioelectrochemical systems. This occurs as a result of

overpotential In electrochemistry, overpotential is the potential difference (voltage) between a half-reaction's thermodynamically determined reduction potential and the potential at which the redox event is experimentally observed. The term is directly r ...

s occurring at the

anode An anode usually is an electrode of a polarized electrical device through which conventional current enters the device. This contrasts with a cathode, which is usually an electrode of the device through which conventional current leaves the devic ...

, membrane, and biocathode. The energy loss reduces efficiency significantly. Another limitation is the biocathode. Because the biocathode is so important in electron exchange and methane formation, its make-up can have a dramatic effect on the efficiency of the reaction. Efforts are being made to improve the biocathodes used in electromethanogenesis through combining new and existing materials, reshaping the materials, or applying different "pre-treatments" to the biocathode surface, thereby increasing biocompatibility.

References

{{reflist Environmental engineering Electrochemistry Biotechnology Bioelectrochemistry Electrochemical engineering

Biocathode

Mechanism

Limitations

See also

References