Inverse curve: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
Correction to formula: See http://en.wikipedia.org/wiki/Inversive_geometry#Circle_inversion
en>LilHelpa
m Typo fixing and general fixes using AWB
 
Line 1: Line 1:
A '''Photo-Carnot engine''' is a [[Carnot cycle]] engine in which the working medium is a photon inside a cavity with perfectly reflecting walls. [[Radiation]] is the working fluid, and the piston is driven by [[radiation pressure]].
My name is Angie from Perpignan doing my final year engineering in Integrated International Studies. I did my schooling, secured 75% and hope to find someone with same interests in Scrapbooking.<br><br>Here is my blog post ... [http://www.tnt-gaming.de/index.php?mod=users&action=view&id=53582 wordpress dropbox backup]
 
A quantum Carnot engine is one in which the atoms in the heat bath are given a small bit of [[Coherence (physics)#Quantum coherence|quantum coherence]].  The phase of the atomic coherence provides a new control parameter.<ref>{{cite web
|url=http://www.sciencemag.org/cgi/content/abstract/299/5608/862|title=Extracting Work from a Single Heat Bath via Vanishing Quantum Coherence -- Marlan Scully, M. Suhail Zubairy, G. S. Agarwal, and Herbert Walther, 299 (5608): 862 -- Science|publisher=www.sciencemag.org|accessdate=2008-06-18}}</ref>
 
The deep physics behind the [[second law of thermodynamics]] is not violated; nevertheless, the quantum Carnot engine has certain features that are not possible in a classical engine.
 
 
 
 
'''Derivation'''
The internal energy of the photo-Carnot engine is proportional to the volume (unlike the ideal-gas equivalent) as well as the 4th power of the temperature (see [[Stefan-Boltzmann law]]).  
 
<math> U = \varepsilon\sigma T^{4}</math>
 
The [[Radiation pressure]] is only proportional to this 4th power of temperature but no other variables, meaning that for this photo-Carnot engine an isotherm is equivalent to an isobar. 
 
<math> P = \frac{U}{3 V} = \frac{\varepsilon \sigma T^{4}}{3 V} </math>
 
Using the First law of thermodynamics (<math> dU = dW + dQ </math>) we can determine the work done through an adiabatic (<math> dQ = 0 </math>) expansion by using the chain rule (<math> dU = \varepsilon \sigma dV T^{4} + 4 \varepsilon \sigma V T^{3} dT </math>) and setting it equal to <math> dW = -P dV = -\frac{1}{3} \varepsilon \sigma T^{4} dV </math>
 
Combining these gives us <math> \frac{2}{3} T^{4} dV = 4 V T^{3} dT </math> which we can solve to find <math> \frac{V^{1/6}}{T} = const </math>
 
....
 
The efficiency of this reversible engine must be the Carnot efficiency, regardless of the mechanism and so <math> \eta = \frac{T_H - T_C}{T_H} </math>
 
==See also==
*[[Carnot heat engine]]
*[[Radiometer]]
==Footnotes==
{{reflist}}
== Further reading ==
*{{cite journal|url=http://www.sciencemag.org/cgi/content/abstract/299/5608/862|title=Extracting Work from a Single Heat Bath via Vanishing Quantum Coherence|author=Marlan O. Scully, M. Suhail Zubairy, G. S. Agarwal, and Herbert Walther|journal=Science|date=2003-02-07|volume=299|issue=5608|pages=862&ndash;864|doi=10.1126/science.1078955|pmid=12511655|bibcode = 2003Sci...299..862S }}
*{{cite conference|url=http://adsabs.harvard.edu/abs/2002AIPC..643...92Z|title=The Photo-Carnot Cycle: The Preparation Energy for Atomic Coherence|author=Zubairy, M. Suhail|booktitle=QUANTUM LIMITS TO THE SECOND LAW: First International Conference on Quantum Limits to the Second Law. AIP Conference Proceedings|volume=643|pages=92&ndash;97|year=2002|doi=10.1063/1.1523787}}
 
{{Heat engines}}
 
[[Category:Hot air engines]]
 
 
{{physics-stub}}

Latest revision as of 18:28, 1 June 2014

My name is Angie from Perpignan doing my final year engineering in Integrated International Studies. I did my schooling, secured 75% and hope to find someone with same interests in Scrapbooking.

Here is my blog post ... wordpress dropbox backup