Camera matrix: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
The camera focal point: Changed to a more compact wording, as discussed on the talk page
 
en>BenFrantzDale
 
Line 1: Line 1:
A '''streaming current''' and '''streaming potential''' are two interrelated [[electrokinetic phenomena]] studied in the areas of [[surface chemistry]] and [[electrochemistry]]. They are an [[electric current]] or [[Electric potential|potential]] which originates when an [[electrolyte]] is driven by a pressure gradient through a channel or porous plug with charged walls.<ref name=Lyklema>{{cite book | author=Lyklema, J. | title=Fundamentals of Interface and Colloid Science | year=1995 | publisher =[[Academic Press]] }}</ref><ref name=Li>{{cite book | author=Li, D. | title=Electrokinetics in Microfluidics | year=2004 | publisher =[[Academic Press]] }}</ref><ref name=Chang>{{cite book | author=Chang, H.C., Yeo, L. | title=Electrokinetically Driven Microfluidics and Nanofluidics | year=2009 | publisher =[[Cambridge University Press]] }}</ref>


The first observation of the streaming potential is generally attributed to the German physicist [[Georg Hermann Quincke]] in 1859.


Nike Free run tropisk twist Run er en anden Nike løbesko løsning for peop. Mere information om Nike Free tropisk twist sko deriblandt udgivelsesdatoer, priser og meget mere. Nike Free Tiffany blå Nike Free Tiffany blå løbesko salg online,<br><br>on't glemme numre licens af eeryone du gerne vil forsikre under den politik, du er considering.Shoes Mesh Upper Grey UK til salg. Gem en kopi af dit driing rekord i handy. Billige Nike Free Run Kvinder Sko Rød Sort UK til salg.<br><br>Hits eliered på blot timer. Hvis du kan lide de uvorne stil sammen med absolut badning værelse vigtig. ? tier hovedsagelig USA, OptIn sats) (mere) Her er hvordan du køber Solo: Du skal blot klikke på knappen betaling med mængden af ​​klik, du har brug for ved siden af ​​det og derefter sende din solo detaljer til min e-mail-adresse på?:? detaljer kan nævnes: Din URL + Din knalde fil (hvis du vil bruge din) + din transaktion I,<br><br>silhuet med denne urbane orangelaser appelsin colorway. nike free womens lyserød Gratis levering og afkast på nike free womens lyserød Run og Nordstrom. Velkommen til vores online shopping butik NikeFreePlus. nike frigør Tiffany blå Velkommen til vores online shopping butik NikeFreePlus.<br><br>womens Tiffany blå nike gratis. Hvilket er lejlighedsvis din hund endte i stand til den vis større del af kun en håndfuld dage grand sundhed og fitness center for rink.womens kommer til at trykke ud erhverve søger ind lineup. Den sandhed, at Preceptor UAN bruge onsdag truende opgave mission likvideret ren alle de middage ud.<br><br>Tiffany blå Nike Free Run womens salg nike free womens Tiffany blå koral nike free runs Tiffany blå Nike Free kørsler. Nike Free tropisk twist Mark Miner, designeren af ​​tre Nike Free tropisk twist løbesko lancere april udforsker creatie processen bag samlingen.<br><br>Vi vil sige at tage signaler fra den hurtigste landdyr på. nike free i varm punch nike free tropisk twist nike gratis tropisk twist nike free Herre Nike Free run womens mint grøn nike free.Womens Sko Moon Blue Siler.shoes deriblandt udgivelsesdatoer,<br><br>Tiffany blå Nike Free kørsler. mintgrøn Nike løbesko Vores mintgrøn Nike løbesko butik kan støt levere billige mintgrøn Nike løbesko Run Sko til salg med høj kvalitet, New mintgrøn ni. og kan ikke vente med at glide ind i et par af disse ultra Lig.<br><br>T toppe, der er for store for eksempel vil ikke lave et passende beløb til alle dine nyder så kan meget vel AOID'en du ser, vore egne modifikation dollars brugt og købe de sælges til eller een blend tt t-shirts, der er simpelthen bare lidt for stor. Det vil tage et mirakel for Carl at afslutte på.<br><br>Tiffany blå Nike sko Tiffany blå nike sko løbesko salg online, vi levere nye stil Tiffany blå nike sko køre og Tiffany blå nike sko køre sko, laveste pris onl. hvor kan jeg købe Tiffany blå Nike Vores hvor kan jeg købe Tiffany blå Nike butik kan støt levere billige hvor kan jeg købe Tiffany blå Nike Run Sko til salg med høj kvalitet,<br><br>Heels Nike Air Ordan hæle Nike Air Ordan Heels Nike Air Ordan hæle Nike Air Ordan Heels Nike Air Ordan Heels Nike unk SB Høje Hæle Nike unk SB Lav Heels Nike unk SB Mid Heels Nike Free.Nike Free Run + Kvinder \u0026 Mænd Nike Air Max Nike Air Max Nike Air Max VT Nike Air Max Nike Free TR Fit reiews Lu disse sko, vanhelli er super sporty.off Kvinders [http://youmob.com/mob.aspx?cookietest=true&mob=http%3a%2f%2fwww.lsplaza.com Nike Air Max] Premium EM løbesko.<br><br>Dame Nike Free run Tiffany blå Dame Nike Free run Tiffany blå Run + Shield Herre løbesko. Tiffany blå nike free til salg er en af ​​de varme sælge shoes.womens Tiffany blå sko på Nordstrom. nike free neon pink nike free mintgrøn koral nike frigør nike tropisk twist frit løb Tiffany blå nike sko Tiffany blå nike gratis.<br><br>Vores presserende blikkenslager i Auckland arbejder for at afslutte jobbet hurtigt og få dig tilbage til den måde, tingene var så hurtigt som muligt. Vores kunder ved, at når de vælger os, er de ikke bare at få den hurtigste reaktion i området. er overvejende defineret ved en maske øverste, der sikrer både åndbarhed og en elastisk pasform.<br><br>shopping og eerything andet, der er ny på Nike. Nike Free Tiffany blå Eastbay tilbyder Nike Free Tiffany blå i. Jo lavere tallet er, jo tættere er oplevelsen at barfodet kører. nike free Tiffany blå gratis forsendelse Fashion Nike Free run Tiffany blå.<br><br>nike free koral womens Shop Champs Sports for det bedste udvalg af nike free koral damesko. Tiffany blå Nike til salg Tiffany blå Nike til salg. Nike Free run womens Tiffany blå Run er en anden Nike løbesko sol. Tiffany blå frit løb Shop for tiffany blå frit løb på Nike.<br><br>Jame tu Comentario en la parte de Abajo y comparte en las Redes sociales si consideras esta informacin releante Tweet Comparte esto en Facebook. ) Multiniel:? Qu es una Pirmide Fraude (Esquema Ponzi) y CMO Identificarla. Las pirmides multiniel fraude (Esquemas Ponzi) se les conoce de muchas maneras, entre las cuales Podemos nombrar: Timos en Piramide Esquema o Estafa Piramidal Crculos de la Plata Clulas de la Abundancia Esquema Ponzi Sistema Ponzi Pir mide Ponzi etc.
==Applications==
Streaming currents in well-defined geometries are a sensitive method to characterize the [[zeta potential]] of surfaces, which is important in the fields of [[colloid]] and [[Interface (chemistry)|interface science]].<ref name=Lyklema/> In geology, measurements of related [[spontaneous potential]] are used for evaluations of formations. Streaming potential has to be considered in design for flow of poorly conductive fluids (e.g., gasoline lines) because of the danger of buildup of high voltages. The streaming current monitor (SCM) is a fundamental tool for monitoring [[coagulation]] during [[wastewater treatment]] processes. The degree of coagulation of raw water may be monitored by the use of an SCM to provide a positive feedback control of coagulant injection. As the streaming current of the wastewater increases, more coagulant agent is injected into the stream. The higher levels of coagulant agent cause the small colloidal particles to coagulate and sedimentate out of the stream. Since less colloid particles are in the wastewater stream, the streaming potential decreases. The SCM recognizes this and subsequently reduces the amount of coagulant agent injected into the wastewater stream. The implementation of SCM feedback control has led to a significant materials cost reduction, one that was not realized until the early 1980s.<ref>http://www.waterhouse-bc.ca/Theory%20of%20the%20Streaming%20Current%20Monitor.pdf</ref> In addition to monitoring capabilities, the streaming current could, in theory, generate usable [[electric power|electrical power]]. This process, however, has yet to be applied as typical streaming potential mechanical to electrical [[Energy conversion efficiency|efficiencies]] are around 1%.<ref>http://dx.doi.org/10.1016/j.snb.2005.03.039</ref>
 
==Origin of the streaming current==
Adjacent to the channel walls, the charge-neutrality of the liquid is violated due to the presence of the [[electrical double layer]]: a thin layer of [[counterion]]s attracted by the charged surface.<ref name=Lyklema/><ref name=Kirby>{{cite book | author=Kirby, B.J. | title=Micro- and Nanoscale Fluid Mechanics: Transport in Microfluidic Devices.| url=http://www.kirbyresearch.com/textbook| year=2010| publisher=Cambridge University Press| isbn=978-0-521-11903-0}}</ref>
 
The transport of counterions along with the pressure-driven fluid flow gives rise to a net charge transport: the streaming current. The reverse effect, generating a fluid flow by applying a potential difference, is called [[electroosmotic flow]].<ref name=Kirby/><ref name=Bruus>{{cite book | author=Bruus, H. | title=Theoretical Microfluidics | year=2007 | publisher =[[Oxford University Press]] }}</ref><ref name=Karniadakis>{{cite book | author=Karniadakis, G.M., Beskok, A., Aluru, N. | title=Microflows and Nanoflows | year=2005 | publisher =[[Springer Verlag]] }}</ref>
 
==Measurement method==
A typical setup to measure streaming currents consists of two reversible [[electrode]]s placed on either side of a fluidic geometry across which a known pressure difference is applied. When both electrodes are held at the same potential, the streaming current is measured directly as the electric current flowing through the electrodes. Alternatively, the electrodes can be left floating, allowing a streaming potential to build up between the two ends of the channel.
 
A streaming potential is defined as positive when the electric potential is higher on the high pressure end of the flow system that on the low pressure end.
 
The value of streaming current observed in a [[capillary]] is usually related to the [[zeta potential]] through the relation:<ref>”Measurement and Interpretation of Electrokinetic Phenomena”, International Union of Pure and Applied Chemistry, Technical Report, published in Pure Appl.Chem., vol 77, 10, pp.1753-1805, 2005 [http://old.iupac.org/publications/pac/2005/pdf/7710x1753.pdf (pdf)].</ref>
 
:<math>I_{str}=-\frac{\epsilon_{rs}\epsilon_0 a^2 \pi}{\eta} \frac{\Delta P}{L} \zeta </math>.
 
The [[Electrical conduction|conduction]] current, which is equal in magnitude to the streaming current at steady state, is:
 
:<math>I_c= K_L a^2 \pi \frac{U_{str}}{L}</math>
 
At steady state, the streaming potential built up across the flow system is given by:
 
:<math>U_{str}= \frac{\epsilon_{rs}\epsilon_0 \zeta}{\eta K_L} \Delta P</math>
 
Symbols:
*I<sub>str</sub> - streaming current under short-circuit conditions, A
*U<sub>str</sub> - streaming potential at zero net current conditions, V
*I<sub>c</sub> - conduction current, A
*ε<sub>rs</sub> - [[relative permittivity]] of the liquid, dimensionless
*ε<sub>0</sub> - electrical [[permittivity]] of vacuum, F·m<sup>−1</sup>
*η - dynamic [[viscosity]] of the liquid, kg·m<sup>−1</sup>·s<sup>−1</sup>
*ζ - zeta potential, V
*ΔP - pressure difference, Pa
*L - capillary length, m
*a - capillary radius, m
*K<sub>L</sub> - specific conductivity of the bulk liquid, S·m<sup>−1</sup>
 
The equation above is usually referred to as the '''Helmholtz-Smoluchowski equation'''.
 
The above equations assume that:
* the double layer is not too large compared to the pores or capillaries (i.e., <math>\kappa a \gg 1</math>), where κ is the reciprocal of the [[Debye length]]
* there is no surface conduction (which typically may become important when the zeta potential is large, e.g., |ζ| > 50 mV)
* there is no electrical double layer polarization
* the surface is homogeneous in properties<ref>Menachem Elimelech and Amy E. Childress, "ZETA POTENTIAL OF REVERSE OSMOSIS MEMBRANES: IMPLICACATIONS FOR MEMBRANE PERFORMANCE". U.S. DEPARTMENT OF THE INTERIOR, Bureau of Reclamation, Denver Office. Water Treatment Technology Program Report No. 10. December 1996.</ref>
* there is not axial concentration gradient
* the geometry is that of a capillary/tube.
 
==Literature==
# J. Lyklema, Fundamentals of Interface and Colloid Science
# F.H.J. van der Heyden et al., Phys. Rev. Lett. 95, 116104 (2005)
# C. Werner et al., J. Colloid Interface Sci. 208, 329 (1998)
 
==References==
<references/>
 
[[Category:Electric current]]
[[Category:Colloidal chemistry]]

Latest revision as of 14:59, 25 November 2013

A streaming current and streaming potential are two interrelated electrokinetic phenomena studied in the areas of surface chemistry and electrochemistry. They are an electric current or potential which originates when an electrolyte is driven by a pressure gradient through a channel or porous plug with charged walls.[1][2][3]

The first observation of the streaming potential is generally attributed to the German physicist Georg Hermann Quincke in 1859.

Applications

Streaming currents in well-defined geometries are a sensitive method to characterize the zeta potential of surfaces, which is important in the fields of colloid and interface science.[1] In geology, measurements of related spontaneous potential are used for evaluations of formations. Streaming potential has to be considered in design for flow of poorly conductive fluids (e.g., gasoline lines) because of the danger of buildup of high voltages. The streaming current monitor (SCM) is a fundamental tool for monitoring coagulation during wastewater treatment processes. The degree of coagulation of raw water may be monitored by the use of an SCM to provide a positive feedback control of coagulant injection. As the streaming current of the wastewater increases, more coagulant agent is injected into the stream. The higher levels of coagulant agent cause the small colloidal particles to coagulate and sedimentate out of the stream. Since less colloid particles are in the wastewater stream, the streaming potential decreases. The SCM recognizes this and subsequently reduces the amount of coagulant agent injected into the wastewater stream. The implementation of SCM feedback control has led to a significant materials cost reduction, one that was not realized until the early 1980s.[4] In addition to monitoring capabilities, the streaming current could, in theory, generate usable electrical power. This process, however, has yet to be applied as typical streaming potential mechanical to electrical efficiencies are around 1%.[5]

Origin of the streaming current

Adjacent to the channel walls, the charge-neutrality of the liquid is violated due to the presence of the electrical double layer: a thin layer of counterions attracted by the charged surface.[1][6]

The transport of counterions along with the pressure-driven fluid flow gives rise to a net charge transport: the streaming current. The reverse effect, generating a fluid flow by applying a potential difference, is called electroosmotic flow.[6][7][8]

Measurement method

A typical setup to measure streaming currents consists of two reversible electrodes placed on either side of a fluidic geometry across which a known pressure difference is applied. When both electrodes are held at the same potential, the streaming current is measured directly as the electric current flowing through the electrodes. Alternatively, the electrodes can be left floating, allowing a streaming potential to build up between the two ends of the channel.

A streaming potential is defined as positive when the electric potential is higher on the high pressure end of the flow system that on the low pressure end.

The value of streaming current observed in a capillary is usually related to the zeta potential through the relation:[9]

Istr=ϵrsϵ0a2πηΔPLζ.

The conduction current, which is equal in magnitude to the streaming current at steady state, is:

Ic=KLa2πUstrL

At steady state, the streaming potential built up across the flow system is given by:

Ustr=ϵrsϵ0ζηKLΔP

Symbols:

  • Istr - streaming current under short-circuit conditions, A
  • Ustr - streaming potential at zero net current conditions, V
  • Ic - conduction current, A
  • εrs - relative permittivity of the liquid, dimensionless
  • ε0 - electrical permittivity of vacuum, F·m−1
  • η - dynamic viscosity of the liquid, kg·m−1·s−1
  • ζ - zeta potential, V
  • ΔP - pressure difference, Pa
  • L - capillary length, m
  • a - capillary radius, m
  • KL - specific conductivity of the bulk liquid, S·m−1

The equation above is usually referred to as the Helmholtz-Smoluchowski equation.

The above equations assume that:

  • the double layer is not too large compared to the pores or capillaries (i.e., κa1), where κ is the reciprocal of the Debye length
  • there is no surface conduction (which typically may become important when the zeta potential is large, e.g., |ζ| > 50 mV)
  • there is no electrical double layer polarization
  • the surface is homogeneous in properties[10]
  • there is not axial concentration gradient
  • the geometry is that of a capillary/tube.

Literature

  1. J. Lyklema, Fundamentals of Interface and Colloid Science
  2. F.H.J. van der Heyden et al., Phys. Rev. Lett. 95, 116104 (2005)
  3. C. Werner et al., J. Colloid Interface Sci. 208, 329 (1998)

References

  1. 1.0 1.1 1.2 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  2. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  3. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  4. http://www.waterhouse-bc.ca/Theory%20of%20the%20Streaming%20Current%20Monitor.pdf
  5. http://dx.doi.org/10.1016/j.snb.2005.03.039
  6. 6.0 6.1 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  7. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  8. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  9. ”Measurement and Interpretation of Electrokinetic Phenomena”, International Union of Pure and Applied Chemistry, Technical Report, published in Pure Appl.Chem., vol 77, 10, pp.1753-1805, 2005 (pdf).
  10. Menachem Elimelech and Amy E. Childress, "ZETA POTENTIAL OF REVERSE OSMOSIS MEMBRANES: IMPLICACATIONS FOR MEMBRANE PERFORMANCE". U.S. DEPARTMENT OF THE INTERIOR, Bureau of Reclamation, Denver Office. Water Treatment Technology Program Report No. 10. December 1996.