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Suppose you take a metal disc and cut a small, circular hole in the center. When you heat the whole thing, will the hole's diameter increase or decrease? and why?

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Sometimes answers become clear when you think about various extremes. Instead of a small hole, make it big. Almost as big as the disk, coming very close to the rim, stopping short by just a paper-thin margin. You'll have a hoop of metal. How will that change when heated? –  DarenW Mar 16 '12 at 3:15
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i have a doubt.Consider the particles on the outer circumference of the disc expand outwards..and the inner circumference expand inwards....so the volume is increasing with the mass remaining constant...so with the explanation in one of the above answers it is possible that the hole's diameter decreases as the density is decreasing(in one of the answers it was mentioned that as density increases it is not possible)..but it does not happen.why? –  user8673 Apr 14 '12 at 9:02
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Here is a way to think about it that makes the answer obvious. Replace 'cut a hole into with 'draw a circle on' and consider what happens to the drawn circle when the disc is heated. –  Benjamin Franz Apr 14 '12 at 13:51
    
@BenjaminFranz That does not make the answer obvious (at least to me). It presumes that the "cut a hole into" and "draw a circle on" scenarios are equivalent, but that's begging the question. Why are they equivalent? –  jamesdlin May 2 '13 at 2:39

8 Answers 8

Instead of a circular hole, let's think of a square hole. You can get a square hole two ways, you can cut it out of a complete sheet, or you can get one by cutting a sheet into 9 little squares and throwing away the center one. Since the 8 outer squares all get bigger when heat it, the inner square (the hole) also has to get bigger:

enter image description here

Same thing happens with a round hole.


This is confusing to people because the primary experience they have with stuff getting larger when heated is by cooking. If you leave a hole in the middle of a cookie and cook it, yes, the cookie gets bigger and the hole gets smaller. But the reason for this is that the cookie isn't so solid. It's more like a liquid, it's deforming. And as Ilmari Karonen points out, the cookie sheet isn't expanding much so there are frictional forces at work.

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Awesome way to explain it! –  Manishearth Mar 16 '12 at 1:36
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The reason why cookies don't expand uniformly when baked has probably more to do with the fact that they're in semi-adhesive contact with the baking tray, which is both much stiffer than cookie dough and expands much less during the process, and which thus provides an external force counteracting the dough's expansion and deforming it. I suspect that, if you were to bake a cookie with a hole in free-fall, suspended in air without a tray, the hole would expand. –  Ilmari Karonen Jul 24 '12 at 19:58
    
(In fact, it occurs to me that, in the absence of a convenient free-fall cookie oven, one might be able to conduct an equivalent experiment by (slowly) deep-frying the annular cookie instead. Hmm... it might be time for some science, here.) –  Ilmari Karonen Jul 24 '12 at 20:03
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Nice comment, however, I've seen doughnuts where the hole closes up due to frying. –  Carl Brannen Jul 25 '12 at 18:08

Good question! Assuming the disc is uniform and isotropic (the same in different directions), the hole will expand in the same ratio as the metal. You can see this because the thermal expansion equation

$$\mathrm{d} L = L\alpha\mathrm{d}T$$

applies to all lengths associated with the metal, including the circumference of the hole, since the edge of the hole is made out of metal. And if the circumference of the hole expands, so does the diameter.

If you have a disc with different regions that are made of different types of metal, or if the metal that makes up your disc has an anisotropic crystal structure (so that it expands by different factors in different directions), then the analysis is more complicated. But in both cases, I think the hole would still get larger since the overall change in size is still an expansion.

In order to get the hole to shrink, you would need to use a material with a negative thermal expansion coefficient $\alpha < 0$, which means it gets smaller as the temperature gets higher. In that case the entire disc would shrink as it heats up. Wikipedia has an entry on these kinds of materials (h/t Kevin Reid).

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Consider the disc made of isotropic material is heated uniformly across its area... the metal near the outer circumference, tries to expand outward because of resistance from its disk-side neighboring molecules. Similarly, the part that is near the inner circumference of the hole (cut-out part) tend to expand to its free side, and thereby covering up the hole –  Mallik Mar 15 '12 at 17:50
    
@Mallik: But it would also try to expand along the ring, and if it moves inward, it has even less space. Therefore it has to move outwards in order to expand (with the outer parts moving outwards more). –  celtschk Apr 15 '12 at 21:54

David Zaslavski's answer is correct and complete. But I want to propose a different way to look at the problem.

Think of the disc that was cut out, and imagine that you heat it too, exactly as you heat the plate. After heating, the disc will fit in exactly to the hole, just as if it was first heated and then cut out. Therefore, the hole will expand.

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I feel like this answer is begging the question. Why must the whole disc expand in the same way whether or not a smaller disc was cut out of its center? How do you know that the cut-out disc will fit exactly into the hole? For example, I could argue that without the expanding center piece, there is nothing providing an outward force to make the hole bigger. –  jamesdlin May 2 '13 at 2:32
    
@jamesdlin I agree that it's heuristic and as such one could argue differently. The real solution is sketched by David Z. If you want more justification, you can say that the thermo-elastic equations with $T=const$ and stress-free BC will result in a stress free configuration (easily verified). Therefore, having the disc in place or cut out has no effect on the surrounding - the "interaction" is the stress, and therefore stress free boundary conditions are equivalent to not having a disc at all. Again, I stress that this can be solved analytically and then there's no ambiguity. –  yohBS May 2 '13 at 6:50

If you worked in an auto shop, you'd know the answer already.

When an axle gets stuck in a ball bearing, one way to pull it out is to heat up the bearing with a welding torch. The whole bearing, including the hole in the middle, expands and allows you to pull the axle free.

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... and you have to be careful to heat the bearing more than you heat the axle. –  Mike Dunlavey Dec 17 '11 at 16:27
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Or even if you were a medieval blacksmith fitting a metal rim on a wheel. –  Martin Beckett Sep 23 '12 at 4:35

Im a machinist. We commonly heat holes to expand them in vatious applications. For example to install bearings that demand press. We use liquid nitrogen to also freeze the bearings. When both objects return to ambient temps the results are the hole shrinks. We can even control within some tolerance how much. Consider on an atomic level what is taking place. End of day? Heat a hole it expands. When it cools it will shrink

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I think that there is an important assumption at work here. The hole will expand as long as the material is sufficiently rigid; since most things that we want to expand are rigid (jar lids and axle bearings, for example), and since a disk is likely to be made from a comparatively rigid alloy such as steel, it is generally fair to say that the hole would expand. But I think that you could also create a disk in which the hole would shrink; I would expect a hole in a disk made from a malleable material with a high thermal expansion coefficient (such as gold or lead) to shrink.

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This is analogous to the reason that the holes in cookies get smaller, not larger, when baked. –  dotancohen Oct 2 '12 at 12:04

The answer might lie in the ratio of ring thickness to circumference. In the case of an infinitely large disk compared to hole size the hole may get smaller. Remember the extremes of the theory must be answered.

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Be careful with how you visualize infinity. You seem to imagine that the disk can't grow outward, but it can. There is no "wall" at infinity preventing every atom from moving away from the center of your coordinates. In fact, a finite hole in an infinite plane will expand when everything is heated. –  Chris White Jan 14 '13 at 7:26

I know it has been answered already. Just a different perspective. When a solid body is heated, it expands as if we look though a magnifying glass - everything looks bigger, including the hole in the disc.
Hence the hole in the expands when it is heated up.

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protected by Qmechanic Jan 22 '13 at 16:19

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