The Casimir Effect is quite intriguing. First predicted in 1948 (by Hendrick BG Casimir), that placing two metallic plates close together in a vacuum will produce an attractive force between them. This effect was finally measured in 1997, not sure how many of you guys read the news about it then. =p Quick update now in 2005.
The traditionally accepted explanation and theory is that this force is caused by zero point quantum fluctuations. Virtual particle-antiparticle pairs continually form out of nothing and then vanish back into nothing. (energy and mass still conserved). The tiny space between the two plates restricts the range of wavelengths possible for these virtual particles : so there's lower energy density between the plates, creating a pressure difference compared to the outside that pushes both plates together.
The Casimir Effect is generally taken to be
Particle physicist Robert Jaffe published a paper recently essentially saying that we need not invoke vacuum fluctuations to explain the Casimir Force. He calls for a simpler explanation - the attractions between the particles making up the metal sheets.
Both methods differ in perspective : but they give the same answer. Both give mathematically close enough values for the expected force between the two metal plates.
The really ironic thing he points out is that the electron charge e is absent from Casimir's formula because he assumed perfect electrical conductance : but everyone convenient forgot this assumption... and when the experiments in 1997 confirmed Casimir's formula and theory, scientists assumed the Casimir Effect came out from the vacuum because there was no reference to metallic properties.
Robert Jaffe's doesn't disprove the existence of zero point energy in vacuum, but it does cast doubt over the use of the Casimir Effect
The trouble is, he suggests, physicists can't agree on what it means for something to be real - and Susskind has a radical solution in mind. "I would ban the word real from the physicist's vocabulary," he says.
My own thoughts triggered from this development :
It's all a matter of perspective. It's the same experiment, but two different schools of thought predict the same outcome. I've always assumed this is so in social science (where two people can predict two different motivations for a person to act) but for this to turn up in hard science is... slightly disturbing.
This is roughly similar to Fermat's Principle of Least Time : which I will not explain fully at this time, but basically it is used in optics. There are two ways of looking at optical refraction : the standard view most of us have (taught in high school science), of the action / reaction principle -> the light beam enters the glass block and is refracted to change direction.
Fermats Principle of Least Time dictates that the light ray always travels in a path that minimizes the time it takes to reach its destination. He states that optical path length is always extremal - either maximizing or minimizing the time taken.
This will mean that before the ray of light leaves the source, it has to know in advance its final destination and all the varying materials between it and its destination. Rather than an action/reaction type interpretation of light, this is a "purposeful" interpretation of light, where the light beam actively attempts to minimize its total path time.
My point : the same natural phenomenon can sometimes be explained by two completely valid theories, and that you can't really say which one is "real" or the "truth" : whether you're trying to explain attraction between two conductive plates or rays of light. Even in so called hard science there's a lot of subjectivity involved.
*edit* in case you think Fermat's principle of least time is some fanciful theory that doesn't really hold water, it's used to derive Snell's Law and is the basis of most optics calculations. there are quite a few extremal mathematical principles out there.
3 comments:
About this...
"The Casimir Effect is generally taken to be proof of zero point energy,"
I believe that instead of 'proof' you mean 'evidence' :P
And you know, it's always fun (and so I always hope it happens) when they have multiple theories predicting the same observable phenomenon.... and one day one bright chap comes up with a unifying paradigm for the entire conversation ^_^
About...
"He states that optical path length is always extremal - either maximizing or minimizing the time taken."
How 'maximise'? Can explain ah? When you tell me that light takes maximum time, I start thinking of were'lights (the little floating mages' marsh light balls). My horrible sentence, but you get the picture I presume.
Isn't 'speed' of light constant? So that when there's higher friction (resistance to change in spatial location), the light doesn't slow down, but bends through space instead, such that energy is conserved, causing at least a change in wavelength etc..... ok so actually I don't really know what I'm talking about :P just thought it was a fun topic to comment on.
doh, good point, i meant evidence. my english in regards to scientific nomenclature is deteriorating badly after my 3 years in a commerce degree.
the speed of light does vary depending on what material it is in. to an outside observe (outside a block of glass) you will observe the light travelling slower. maybe i'll draw up an illustration and put it up =p
well, under normal conditions fermat's principle always says that light takes the minimal path time : i have briefly read somewhere which said that the maximal path time part of that principle is used when dealing with gravitational lensing, but that subject was a bit too esoteric for my tastes =p
:P
Lol I like this blog post.
Isn't it cool though? There are some theories I think that have like three plausible explanations. Haha.
I guess the real question is, can all the theories be correct at the same time? or is there only one thing that is actually happening?
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