Reducing atmosphere: Difference between revisions
Dickatkinson (talk | contribs) →Notes: Planetary science irrelevant - article is about firing ceramics in artificial non-oxidizing environments, not atmospheres as such. |
Rv. You can't just go and decide personally what an article is about. |
||
Line 9: | Line 9: | ||
In most commercial [[Incineration|incinerator]]s, exactly the same conditions are created to encourage the release of carbon bearing fumes. These fumes are then oxidized in reburn tunnels where oxygen is injected progressively. The exothermic oxidation reaction maintains the temperature of the reburn tunnels. This system allows lower temperatures to be employed in the incinerator section, where the solids are volumetrically reduced. |
In most commercial [[Incineration|incinerator]]s, exactly the same conditions are created to encourage the release of carbon bearing fumes. These fumes are then oxidized in reburn tunnels where oxygen is injected progressively. The exothermic oxidation reaction maintains the temperature of the reburn tunnels. This system allows lower temperatures to be employed in the incinerator section, where the solids are volumetrically reduced. |
||
== Planetary atmospheres == |
|||
The same principle applies to planets. Early Earth had a reducing atmosphere, along with Mars and Venus. This proved to be a good environment for ''[[Cyanobacteria]]'' to evolve the first [[Photosynthesis|photosynthetic metabolic pathways]] which gradually increased the oxygen portion of the atmosphere, changing it to what is known as an oxidizing atmosphere. With increased levels of oxygen, the evolution of the more efficient aerobic respiration was enabled, allowing animal life to evolve and thrive.<ref>{{Cite web |url=http://www.newscientist.com/article/mg14820078.300-structure-of-the-earths-atmosphere.html?full=true|title=Structure of the Earth's atmosphere |accessdate= |author=Gribbin, J. |authorlink= |coauthors= |date=1995-12-09|year= |month= |work= |publisher=NewScientist, 2007 |pages=1 |language= |archiveurl= |archivedate= |quote= }}</ref> |
|||
In contrast, the constant bombardment with hydrogen in the [[solar wind]] means that interplanetary space is reducing. For example, the Moon is directly exposed to solar wind, such that sodium is reduced and evaporated to produce the [[sodium tail of the Moon]] (see [[atmosphere of the Moon]]). |
|||
==See also== |
|||
*[[Redox]] |
|||
==Notes== |
==Notes== |
||
Line 15: | Line 23: | ||
[[Category:Pottery]] |
[[Category:Pottery]] |
||
[[Category:Metallurgy]] |
[[Category:Metallurgy]] |
||
[[Category:Planetary science]] |
Revision as of 15:53, 21 November 2013
This article needs additional citations for verification. (May 2009) |
A reducing atmosphere, also known as a reduction atmosphere, is an atmospheric condition in which oxidation is prevented by removal of oxygen and other oxidising gases or vapours, and which may contain actively reducing gases such as hydrogen, carbon monoxide and gases that would oxidize in the presence of oxygen, such as hydrogen sulfide.
Materials processing
In metal processing, a reducing atmosphere is used in annealing ovens for relaxation of metal stresses without corroding the metal. An inert gas, usually nitrogen is used, or for more extreme conditions, hydrogen gas.
A reducing atmosphere is also used in order to produce specific effects on ceramic wares being fired. A reduction atmosphere is produced in a fuel fired kiln by reducing the draft and depriving the kiln of oxygen. This reduced level of oxygen causes incomplete combustion of the fuel and raises the level of carbon inside the kiln. At high temperatures the carbon will bond with and remove the oxygen in the metal oxides used as colorants in the glazes. This loss of oxygen results in a change in the color of the glazes because it allows the metals in the glaze to be seen in an unoxidized form. A reduction atmosphere can also affect the color of the clay body. If iron is present in the clay body, as it is in most stoneware, then it will be affected by the reduction atmosphere as well.
In most commercial incinerators, exactly the same conditions are created to encourage the release of carbon bearing fumes. These fumes are then oxidized in reburn tunnels where oxygen is injected progressively. The exothermic oxidation reaction maintains the temperature of the reburn tunnels. This system allows lower temperatures to be employed in the incinerator section, where the solids are volumetrically reduced.
Planetary atmospheres
The same principle applies to planets. Early Earth had a reducing atmosphere, along with Mars and Venus. This proved to be a good environment for Cyanobacteria to evolve the first photosynthetic metabolic pathways which gradually increased the oxygen portion of the atmosphere, changing it to what is known as an oxidizing atmosphere. With increased levels of oxygen, the evolution of the more efficient aerobic respiration was enabled, allowing animal life to evolve and thrive.[1]
In contrast, the constant bombardment with hydrogen in the solar wind means that interplanetary space is reducing. For example, the Moon is directly exposed to solar wind, such that sodium is reduced and evaporated to produce the sodium tail of the Moon (see atmosphere of the Moon).
See also
Notes
- ^ Gribbin, J. (1995-12-09). "Structure of the Earth's atmosphere". NewScientist, 2007. p. 1.
{{cite web}}
: Cite has empty unknown parameters:|month=
and|coauthors=
(help)