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Syngas, or synthesis gas, is a fuel gas mixture consisting primarily of hydrogen, carbon monoxide, and very often some carbon dioxide. The name comes from its use as intermediates in creating synthetic natural gas (SNG)[1] and for producing ammonia or methanol. Syngas is usually a product of gasification and the main application is electricity generation. Syngas is also used as an intermediate in producing synthetic petroleum for use as a fuel or lubricant via the Fischer–Tropsch process and previously the Mobil methanol to gasoline process. Syngas is combustible and often used as a fuel of internal combustion engines.[2][3][4] It has less than half the energy density of natural gas.

Production methods include steam reforming of natural gas or liquid hydrocarbons to produce hydrogen, the gasification of coal,[5] biomass, and in some types of waste-to-energy gasification facilities.


  • Production chemistry 1
  • Alternative technologies 2
    • Biomass catalytic partial oxidation 2.1
    • Carbon dioxide and hydrogen 2.2
      • Microwave energy 2.2.1
      • Solar energy 2.2.2
      • Wind energy 2.2.3
  • Electricity 3
    • Other 3.1
  • Post-treatment 4
  • Energy capacity 5
  • See also 6
  • References 7
  • External links 8

Production chemistry

The main reaction that produces syngas, steam reforming, is an endothermic reaction with 206 kJ/mol methane needed for conversion.

The first reaction, between incandescent coke and steam, is strongly endothermic, producing carbon monoxide (CO), and hydrogen H
(water gas in older terminology). When the coke bed has cooled to a temperature at which the endothermic reaction can no longer proceed, the steam is then replaced by a blast of air.

The second and third reactions then take place, producing an exothermic reaction - forming initially carbon dioxide - raising the temperature of the coke bed - followed by the second endothermic reaction, in which the latter is converted to carbon monoxide, CO. The overall reaction is exothermic, forming "producer gas" (older terminology). Steam can then be re-injected, then air etc., to give an endless series of cycles until the coke is finally consumed. Producer gas has a much lower energy value, relative to water gas, due primarily to dilution with atmospheric nitrogen. Pure oxygen can be substituted for air to avoid the dilution effect, producing gas of much higher calorific value.

When used as an intermediate in the large-scale, industrial synthesis of hydrogen (principally used in the production of ammonia), it is also produced from natural gas (via the steam reforming reaction) as follows:

CH4 + H2OCO + 3 H2

In order to produce more hydrogen from this mixture, more steam is added and the water gas shift reaction is carried out:

CO + H2OCO2 + H2

The hydrogen must be separated from the CO
to be able to use it. This is primarily done by pressure swing adsorption (PSA), amine scrubbing, and membrane reactors.

Alternative technologies

Biomass catalytic partial oxidation[6]

Conversion of biomass to syngas is typically low-yield. The University of Minnesota developed a metal catalyst that reduces the biomass reaction time by up to a factor of 100. The catalyst can be operated at atmospheric pressure and reduces char. The entire process is autothermic and therefore heating is not required.

Carbon dioxide and hydrogen

Microwave energy

CO2 can be split into CO and then combined with hydrogen to form syngas. A method for production of carbon monoxide from carbon dioxide by treating it with microwave radiation is being examined by the solar fuels-project of the Dutch Institute For Fundamental Energy Research.[7] This technique was alleged to have been used during the Cold war in Russian nuclear submarines to allow them to get rid of CO2 gas without leaving a bubble trail.[8]

Solar energy

Heat generated by concentrated solar power may be used to drive thermochemical reactions to split carbon dioxide to carbon monoxide or to make hydrogen.[9] Natural gas may be used as a feedstock in a facility that integrates concentrated solar power with a power plant fueled by natural gas augmented by syngas while the sun is shining.[10][11][12] The Sunshine-to-Petrol project has developed a device allowing for efficient production using this technique. It is called the Counter-Rotating Ring Receiver Reactor Recuperator, or CR5.[13][14][15][16]

Wind energy

An airborne wind energy system has been proposed to supply heat to the steam reforming reaction.[17] This avoids burning natural gas for the heat and radically simplifies the steam reformer.


Use of electricity to extract carbon dioxide from water and then water gas shift to syngas has been trialed by the US Naval Research Lab. This process becomes cost effective if the price of electricity is below $20/MWh.


Coal gasification processes were used for many years to manufacture illuminating gas (coal gas) for gas lighting, cooking and to some extent, heating, before electric lighting and the natural gas infrastructure became widely available. The syngas produced in waste-to-energy gasification facilities can be used to generate electricity.


Syngas can be used in the Fischer–Tropsch process to produce diesel, or converted into e.g. methane, methanol, and dimethyl ether in catalytic processes.

If the syngas is post-treated by cryogenic processing, it should be taken into account that this technology has great difficulty in recovering pure carbon monoxide if relatively large volumes of nitrogen are present due to carbon monoxide and nitrogen having very similar boiling points which are -191.5 °C and -195.79 °C respectively. Certain process technology selectively removes carbon monoxide by complexation/decomplexation of carbon monoxide with cuprous aluminum chloride (CuAlCl
) dissolved in an organic liquid such as toluene. The purified carbon monoxide can have a purity greater than 99%, which makes it a good feedstock for the chemical industry. The reject gas from the system can contain carbon dioxide, nitrogen, methane, ethane, and hydrogen. The reject gas can be further processed on a pressure swing adsorption system to remove hydrogen, and the hydrogen and carbon monoxide can be recombined in the proper ratio for catalytic methanol production, Fischer-Tropsch diesel, etc. Cryogenic purification, being very energy-intensive, is not well suited to simply making fuel, because of the greatly reduced net energy gain.

Energy capacity

Syngas that is not methanized typically has a lower heating value of 120 BTU/scf .[18] Untreated syngas can be run in hybrid turbines that allow for greater efficiency because of their lower operating temperatures, and extended part lifetime.[18]

See also


  1. ^ Beychok, M.R., Process and environmental technology for producing SNG and liquid fuels, U.S. EPA report EPA-660/2-75-011, May 1975
  2. ^ Syngas in Gas Engines,, accessed 15.11.11
  3. ^ Syngas used in IC engines
  4. ^ Syngas used in IC engines 2
  5. ^ Beychok, M.R., Coal gasification and the Phenosolvan process, American Chemical Society 168th National Meeting, Atlantic City, September 1974
  6. ^ "Syngas using metal catalyst". University of Minnesota. Retrieved 25 August 2011. 
  7. ^ DIFFER
  8. ^ NWT magazine 6/2012
  9. ^ "Sunshine to Petrol". Sandia National Laboratories. Retrieved April 11, 2013. 
  10. ^ "Integrated Solar Thermochemical Reaction System". U.S. Department of Energy. Retrieved April 11, 2013. 
  11. ^ Matthew L. Wald (April 10, 2013). "New Solar Process Gets More Out of Natural Gas". The New York Times. Retrieved April 11, 2013. 
  12. ^ Frances White. "A solar booster shot for natural gas power plants". Pacific Northwest National Laboratory. Retrieved April 12, 2013. 
  13. ^ Syngas production with solar energy
  14. ^ No use of fossil fuels with production of syngas using solar power
  15. ^ Sunshine-to-Petrol project reference 1
  16. ^ Sunshine-to-Petrol project reference 2
  17. ^ L. Goldstein. "Beyond electricity generation: airborne wind energy system for synthetic fuel production and energy storage". Presentation at Airborne Wind Energy Conference, 2013. 
  18. ^ a b Emmanuel O. Oluyede. "FUNDAMENTAL IMPACT OF FIRING SYNGAS IN GAS TURBINES". Clemson/EPRI. Retrieved 2012-11-10. 

External links

  • Fischer Tropsch archive
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