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<p><b>New page</b></p><div>A '''streamer discharge''', also known as ''filamentary discharge'', is a type of transient [[electrical discharge]]. Streamer discharges can form when an insulating medium (for example air) is exposed to a large [[voltage]] difference. When the [[electric field]] created by the voltage difference is sufficiently large, [[electron avalanche]]s can form.<br />
The [[space charge]] created by the electron avalanches gives rise to an additional electric field.<br />
This field can enhance the growth of new avalanches in a particular direction.<br />
Then the [[ionization|ionized]] region grows quickly in that direction, forming a finger-like discharge called a ''streamer''.<br />
<br />
Streamers are transient (exist only for a short time) and filamentary, which makes them different from [[corona discharge]]s. They are used in applications such as ozone production, air purification or plasma medicine. Streamers pave the way for [[Electric arc|arcs]] and [[Lightning#Leader formation and the return stroke|lightning leaders]], in which the ionized paths created by streamers are heated by large currents. Streamers can also be observed as [[sprite (lightning)|sprites]] in the upper atmosphere. Due to the low pressure sprites are much larger than streamers at ground pressure, see the [[#Similarity laws|similarity laws]].<br />
<br />
== History ==<br />
The theory of streamer discharges was preceded by [[John Sealy Townsend]]'s [[Townsend discharge|discharge theory]]<br />
<ref name="Townsend1900">{{cite journal|last1=Townsend|first1=J. S.|title=The Conductivity produced in Gases by the Motion of Negatively–charged Ions|journal=Nature|volume=62|issue=1606|year=1900|pages=340–341|issn=0028-0836|doi=10.1038/062340b0|bibcode = 1900Natur..62..340T }}</ref><br />
from around 1900.<br />
However, it became clear that this theory was sometimes inconsistent with observations.<br />
This was especially true for discharges that were longer or at higher pressure.<br />
In 1939, Loeb<br />
<ref name="Loeb1939">{{cite book|author=Leonard Benedict Loeb|title=Fundamental processes of electrical discharge in gases|url=http://books.google.com/books?id=m3LPAAAAMAAJ|accessdate=22 August 2012|year=1939|publisher=J. Wiley & Sons, inc.}}</ref><br />
<ref name="LoebKip1939">{{cite journal|last1=Loeb|first1=Leonard B.|last2=Kip|first2=Arthur F.|title=Electrical Discharges in Air at Atmospheric Pressure The Nature of the Positive and Negative Point-to-Plane Coronas and the Mechanism of Spark Propagation|journal=Journal of Applied Physics|volume=10|issue=3|year=1939|pages=142|issn=00218979|doi=10.1063/1.1707290|bibcode = 1939JAP....10..142L }}</ref><br />
and Raether<br />
<ref name="Raether1939">{{cite journal|last1=Raether|first1=H.|title=Die Entwicklung der Elektronenlawine in den Funkenkanal|journal=Zeitschrift f�r Physik|volume=112|issue=7-8|year=1939|pages=464–489|issn=1434-6001|doi=10.1007/BF01340229|bibcode = 1939ZPhy..112..464R }}</ref><br />
independently described a new type of discharge, based on their experimental observations.<br />
Shortly thereafter, in 1940, Meek presented the ''theory of spark discharge''<br />
,<ref name="Meek1940">{{cite journal|last1=Meek|first1=J.|title=A Theory of Spark Discharge|journal=Physical Review|volume=57|issue=8|year=1940|pages=722–728|issn=0031-899X|doi=10.1103/PhysRev.57.722|bibcode = 1940PhRv...57..722M }}</ref><br />
which quantitatively explained the formation of a self-propagating streamer.<br />
This new theory of streamer discharges successfully explained the experimental observations.<br />
<br />
== Applications ==<br />
Streamers are used in applications such as ozone generation, air purification and plasma assisted combustion.<br />
An important property is that the plasma they generate is strongly non-equilibrium: the electrons have much higher energies than the ions.<br />
Therefore, chemical reactions can be triggered in a gas without heating it.<br />
This is important for plasma medicine, where `plasma bullets' or guided streamers can be used for wound treatment, although this is still experimental.<br />
<br />
== Streamer physics ==<br />
Streamers can emerge when a strong electric field is applied to an insulating material, typically a gas.<br />
There will usually be some free charge in the medium, for example due to [[cosmic radiation or]] [[radioactive decay]].<br />
Electrons will accelerate in the electric field, and gain energy.<br />
Ions are much heavier, so they move very slowly compared to electrons.<br />
As the electrons move through the medium, they collide with the neutral molecules or atoms.<br />
Important collisions are:<br />
:* [[Elastic collision]]s, which change the direction of motion of the electrons.<br />
:* [[electron excitation|Excitations]], where the neutral particle is excited and the electron loses the corresponding energy.<br />
:* [[Impact ionization]], where the neutral particle becomes ionized, with the incident electron losing the<br />
:* [[electron capture ionization|Attachment]], where the electron attaches to the neutral to form a negative ion.<br />
In higher electric fields, the electrons gain more energy between collisions, and are more likely to ionize the neutrals.<br />
At the breakdown field, there is a balance between the production of new electrons (due to impact ionization) and the loss of electrons (due to attachment).<br />
Above the breakdown field, the number of electrons starts to grow exponentially, and an [[electron avalanche]] forms.<br />
<br />
The electron avalanches leave behind positive ions, so in time more and more [[space charge]] is building up.<br />
(Of course, the ions move away in time, but this a relatively slow process compared to the avalanche generation).<br />
Eventually, the electric field from all the space charge becomes comparable to the background electric field.<br />
This is sometimes referred to as the `avalanche to streamer transition'.<br />
In some regions the total electric field will be smaller than before, but in other regions it will get larger, which is called electric field enhancement.<br />
New avalanches predominantly grow in the high field regions, so a self-propagating structure can emerge: a streamer.<br />
<br />
=== Positive and negative streamers ===<br />
There are positive and negative streamers.<br />
Negative streamers propagate against the direction of the electric field, so in the same direction as the electrons [[drift velocity]].<br />
Positive streamers propagate in the opposite direction.<br />
In both cases, the streamer channel is electrically neutral, and it is shielded by a thin space charge layer.<br />
This leads to an enhanced electric field at the end of the channel, the `head' of the streamer.<br />
Both positive and negative streamer grow by impact ionization in this high field region.<br />
But the source of electrons is very different.<br />
<br />
For negative streamers, free electrons are accelerated from the channel to the head region.<br />
However, for positive streamers, these free electrons have to come from farther away, as they accelerate into the streamer channel.<br />
Therefore, negative streamers grow in a more diffuse way than positive streamers.<br />
Because a diffuse streamer has less field enhancement, negative streamers require higher electric fields than positive streamers.<br />
In nature and in applications, positive streamers are therefore much more common.<br />
<br />
As noted above, an important difference is also that positive streamers need a source of free electrons for their propagation.<br />
In many cases [[Photoelectrochemical processes#Photoionization|photoionization]] is believed to be this source<br />
.<ref name="Nijdamvan de Wetering2010">{{cite journal|last1=Nijdam|first1=S|last2=van de Wetering|first2=F M J H|last3=Blanc|first3=R|last4=van Veldhuizen|first4=E M|last5=Ebert|first5=U|title=Probing photo-ionization: experiments on positive streamers in pure gases and mixtures|journal=Journal of Physics D: Applied Physics|volume=43|issue=14|year=2010|pages=145204|issn=0022-3727|doi=10.1088/0022-3727/43/14/145204|arxiv = 0912.0894 |bibcode = 2010JPhD...43n5204N }}</ref><br />
<br />
=== Similarity laws ===<br />
Most processes in a streamer discharge are two-body processes, where an electron collides with a neutral molecule.<br />
An important example is [[impact ionization]], where an electron ionizes a neutral molecule.<br />
Therefore the [[mean free path]] is inversely proportional to the gas [[number density]].<br />
If the electric field is changed linearly with the gas number density, then electrons gain on average the same energy between collisions.<br />
In other words, if the ratio between electric field <math>E</math> and number density <math>N</math> is constant, we expect similar dynamics.<br />
Typical lengths scale as <math>1/N</math>, as they are related to the mean free path.<br />
<br />
This also motivates the [[Townsend (unit)|Townsend unit]], which is a physical unit of the <math>E/N</math> ratio.<br />
<br />
== See also ==<br />
* [[electrical discharge]]<br />
* [[sprite (lightning)]]<br />
* [[corona discharge]]<br />
* [[Townsend discharge]]<br />
* [[avalanche breakdown]]<br />
<br />
== References ==<br />
{{Reflist}}<br />
<br />
[[Category:Electrical phenomena]]</div>24.175.228.172