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Author: Subject: Pyrolytic Carbon
IrC
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[*] posted on 1-8-2015 at 10:43
Pyrolytic Carbon


I have been trying to understand why only certain forms of carbon exhibit diamagnetism strong enough to float above my N52 magnets. Notably my Pyrolytic Carbon, while graphene and other forms (allotropes) do not appear to float above the magnets (or at least the effect is too weak for me to see).

https://en.wikipedia.org/wiki/Graphene

https://en.wikipedia.org/wiki/Pyrolytic_carbon

Taking a couple quoted portions of this page:

"Pyrolytic carbon is a material similar to graphite, but with some covalent bonding between its graphene sheets as a result of imperfections in its production."

"Pyrolytic carbon samples usually have a single cleavage plane, similar to mica, because the graphene sheets crystallize in a planar order, as opposed to graphite, which forms microscopic randomly oriented zones. Because of this, pyrolytic carbon exhibits several unusual anisotropic properties. It is more thermally conductive along the cleavage plane than graphite, making it one of the best planar thermal conductors available."

What I am looking for is insight into the reason why Pyrolytic Carbon so strongly levitates as opposed to other forms of carbon and so far (to me at least) it appears the focus needs to be on the subject of covalent bonding. Yet considering the subject of Network Covalent Solids only diamond and graphite are mentioned, neither of which appear to want to float above a magnet (as far as I can tell).

http://chemwiki.ucdavis.edu/Physical_Chemistry/Physical_Prop...

Looking at "Pyrolytic carbon is a material similar to graphite, but with some covalent bonding between its graphene sheets as a result of imperfections in its production", I assume they mean Pyrolytic Carbon consists of sheets of graphene. Yet graphene is not so diamagnetic leading me to conclude it is the covalent bonding that should be considered in understanding the very strong diamagnetism.

Does anyone having a greater understanding in this area wish to provide more insight?




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aga
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[*] posted on 1-8-2015 at 11:43


How did you make your Pyrolytic carbon ?

Perhaps it's a quantum effect ?

Seems perfectly feasible in the agaspace model of matter.

[Edited on 1-8-2015 by aga]




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[*] posted on 1-8-2015 at 14:42


I bought it although I am thinking of doing some experiments making it. I have a graphite crucible that sits new unused in a big box. Over 70 pounds weight and far too large for anything I can ever think to use it for. Been sitting for years must be time to do something with it. If I cut the top foot of it off I would still have a larger crucible than I would ever need anyway and that would give me 20 or 30 pounds to experiment with. I was thinking I could shape two pieces for electrodes to make a carbon arc setup to generate high temperatures since the walls are 5 or 6 inches thick at the top (the thinnest part of the crucible). I just don't have a lot of room or time to do things like making my own. Also I would need to study the subject of manufacturing Pyrolytic Carbon. Think I'll go searching for patents to study.

So far the only references I can find involve starting with hydrocarbons not graphite, but hopefully a method exists to start with pure graphite since I have plenty of that on hand.




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battoussai114
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[*] posted on 1-8-2015 at 15:07


How familiar are you with molecular orbital theory? I remember having the magnetic behavior of different materials explained to me with the said theory in mind during some inorganic chemistry lectures last year. I don't have my notebook with me now and I won't risk making a fool of myself by getting it wrong, but tomorrow I'll see if I manage to post my notes here.
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[*] posted on 1-8-2015 at 15:22


Pyrolytic graphite has a roughly equal diamagnetic susceptibility compared to natural graphite:

http://www.rrfisica.cat/rrfisica/m_madruenyo_001/DBFischbach...

The main difference between natural and pyrolytic graphite is crystal size; natural graphite single crystals are usually smaller than a square mm, whereas pyolytic graphite can be several square centimeters.
Why does that matter? I guess that's because graphite is highly anisotropic; it's only strongly diamagnetic perpendicular to the crystal plane.
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[*] posted on 1-8-2015 at 17:59


I can take a 25mm square 1mm thick sheet of Pyrolytic Carbon and float it a few mm above N48 to N52 magnets, whereas if the same size sheet of graphite floats I sure cannot see it.

http://www.scitoyscatalog.com/category/M.html

You can buy the kit of 4 magnets and Pyrolytic Carbon square for about $35 here if you wish to see the effect.

Yet another fact I had not read before was on the wiki page:

"A recent discovery in Japan shows that pyrolytic carbon can respond to laser light or sufficiently powerful natural sunlight by spinning or moving in the direction of the field gradient.[2] The carbon's magnetic susceptibility changes upon illumination, leading to an unbalanced magnetization of the material and thus a sideways force."

This point "carbon's magnetic susceptibility changes upon illumination" I find very interesting. Many odd properties stem from this material and being so out of the normal experience we have in life I tend to agree with Aga that some type of quantum effect being exhibited on a macroscopic level is at play here.

I can take a 25mm square 1mm thick sheet of Pyrolytic Carbon and float it a few mm above N48 to N52 magnets, whereas if the same size sheet of graphite floats I sure cannot see it.

http://www.scitoyscatalog.com/category/M.html

You can buy the kit of 4 magnets and Pyrolytic Carbon square for about $35 here if you wish to see the effect.

Yet another fact I had not read before was on the wiki page:

"A recent discovery in Japan shows that pyrolytic carbon can respond to laser light or sufficiently powerful natural sunlight by spinning or moving in the direction of the field gradient.[2] The carbon's magnetic susceptibility changes upon illumination, leading to an unbalanced magnetization of the material and thus a sideways force."

This point "carbon's magnetic susceptibility changes upon illumination" I find very interesting. Many odd properties stem from this material and being so out of the normal experience we have in life I tend to agree with Aga that some type of quantum effect being exhibited on a macroscopic level is at play here.

* However this does not mean I believe in 'the agaspace model of matter', I'm not even sure what that is.

Perhaps he can clarify.




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battoussai114
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[*] posted on 1-8-2015 at 19:11


The laser one I'd guess relates to phosphorescence as predicted by the Batou Model of Photon Induced Spin Change.... Meaning that just like phosphorescent materials the carbon is probably absorbing photons and getting electrons locked in an excited state with its spin inverted, maybe the effect is big enough in the pyrolitic carbon as to induce noticeable changes in magnetic domains due to changes in several valence electrons.

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[*] posted on 1-8-2015 at 21:28


Graphite foil is much cheaper than pyrolytic graphite
and it levitates almost as well.
e.g. I use this http://www.ebay.co.uk/itm/Graphite-Foil-Gland-Packing-for-la...
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[*] posted on 1-8-2015 at 21:54


Never considered that before, I found the following link (better for me since mail is so expensive from England).

http://www.ebay.com/itm/99-5-Pure-Graphite-Flexible-Foil-She...

Still while you say both forms have the same diamagnetism I have to wonder why my 25x25x1mm squares of graphite do not float like the same weight square of Pyrolytic Carbon. Going to get some of this graphite foil since it is so light maybe it will even do better.




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[*] posted on 1-8-2015 at 22:40


the nice thing with graphite foil, apart from the obvious cost saving,
is that with a sharp knife you can cut various shapes,
which work better or worse.

From memory, an X shape aligns over the joins in the magnets and was the highest floating shape that I made.

If is not quite as high floating as pyrolytic graphite, but almost the same,
small thin pieces levitate best,
so the answer to your question is; 1mm is too thick.
(no, I do not kow the math !)

P.S.
putting a steel plate on the bottom of the magnets improves lift,
putting more than one layer of magnets improves lift ....
and of course, bigger N numbers work better.
I think that my best are 10mm N50 cubes.

P.P.S. anyone managed to keep large NdFeB magnets chip-free ? :P

[Edited on 2-8-2015 by Sulaiman]
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[*] posted on 2-8-2015 at 00:14


Quote: Originally posted by battoussai114  
How familiar are you with molecular orbital theory? I remember having the magnetic behavior of different materials explained to me with the said theory in mind during some inorganic chemistry lectures last year. I don't have my notebook with me now and I won't risk making a fool of myself by getting it wrong, but tomorrow I'll see if I manage to post my notes here.

If anyone is interested, here is a series of youtube tutorials on molecular orbital theory. Part VI deals with paramagnetism and diamagnetism. I haven't watched them all but they seem to be of above average quality as far as explanation goes.

Part I
Part II
Part III
Part IV
Part V
Part VI
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[*] posted on 2-8-2015 at 01:17


Quote: Originally posted by IrC  


Still while you say both forms have the same diamagnetism I have to wonder why my 25x25x1mm squares of graphite do not float like the same weight square of Pyrolytic Carbon.

Chiral case pointed out that graphite is only strongly diamagnetic in one direction (with respect to the crystal axis).
If you got lots of squares of pyrolytic graphite and stuck them together to make a cube, then cut a slice off that like a layer cake perpendicular to all the PG sheets the resulting sheet wouldn't levitate.

The arrangement of crystals in the graphite sheet is pretty much random so roughly 1 in 3 is contributing the large diamagnetism but 2 in 3 are only contributing weight.
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[*] posted on 2-8-2015 at 05:52


I believe that the graphite sheet is rolled flat/thin in several stages,
could the graphite sheet have more than random alignment ?
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[*] posted on 2-8-2015 at 16:46


Quote: Originally posted by unionised  

The arrangement of crystals in the graphite sheet is pretty much random so roughly 1 in 3 is contributing the large diamagnetism but 2 in 3 are only contributing weight.

I'm not well versed in the ways of magnetism, but if 1 in 3 crystals produce an upwards force, wouldn't about 1 in 3 produce a force downwards in addition to their weight, completely negating any upwards force?
To me this sounds like when iron is apparently unmagnetised the reality is that lots of tiny grains in the iron have random orientations and so the net result is the material is only paramagnetic, not ferromagnetic.
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[*] posted on 2-8-2015 at 17:15


Since magnetism is the topic, here's 10 minutes worth of a decent explanation on these guys:
https://www.youtube.com/watch?v=hFAOXdXZ5TM
https://www.youtube.com/watch?v=1TKSfAkWWN0

These are from infotainment channels and as such don't go much into fancy equations and stuff, but it gets anyone interested at least some info on the subject.


Quote: Originally posted by Oscilllator  
Quote: Originally posted by unionised  


To me this sounds like when iron is apparently unmagnetised the reality is that lots of tiny grains in the iron have random orientations and so the net result is the material is only paramagnetic, not ferromagnetic.

That's about it. What makes iron ferromagnetic is that its magnetic domains are easily changed to match the external magnetic field and once they're aligned there will be a non-negligible magnetic moment and unless the domains are forced back into a random state by heat they basically stay like that acting like a magnet.
I remember taking a small course on nanomaterials and one of the points they made on how these materials cold allow innovation on several fields was how easy it was to get nanoparticles to magnetize due to that fact that bellow a certain cluster size they tend to have a single domain and as such are really easy to be changed in order to get it pointing to the external field.
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