Finding the Viscosity of Pitch

ColdChrist writes "The University of Queensland has a page about a 72-year-old experiment on the fluidity of pitch. There's a webcam where you can try to become the first person ever to see a drop of the pitch fall; eight drops have fallen since 1930 and the ninth is now forming. The experiment 'demonstrates the fluidity and high viscosity of pitch, a derivative of tar once used for waterproofing boats. At room temperature pitch feels solid - even brittle - and can easily be shattered with a blow from a hammer', but it does flow, as the pictures demonstrate." I know this is going to bring up glass comparisons, so we'll head those off: glass is not a fluid.

A watched pitch...

[RawDigits]

never dribbles

Time Lapse anyone?

[ayjay29]

This would look excellent with a time-lapse movie. It can't be too hard to generate MPEGs automativally and have the latest available for download.

Any commend line JPG -> MPG converters out there???

Re:Time Lapse anyone?

[GroovBird]

Check out this [mit.edu] and this [mpeg.org].

I like JPGVideo [ndrw.co.uk] a lot, since I can choose any encoder I have.

Dave

What do you mean?

[autopr0n]

It would just look like any other fluid dripping out of something over time-lapse.

Keeps us from getting bored

[tismith]

The experiment is sitting in a glass cabinet just outside one of the lecture theatres used for a lot of first and second year engineering and science lectures.

When I started in first year (1999), the pitch had formed into an interesting drop, and it provided students with a pretty geeky talking point while waiting for lectures to start.

I remember when we went for holidays one year, and came back to find that the drop had fallen! Everyone was a bit pissed (understandably) that it had fallen during uni hols.

Apparently the rate of drop formation is slowing down due to the air conditioning in the building. Or at least thats a rumour circulating around UQ.

Re:Keeps us from getting bored

[richie2000]

And you're telling us that not once, NOT ONCE, in 72 years sitting in plain view in a University milling with students of all sizes, shapes, colours and states of mental health, not once, did first-year students open the glass cabinet and replace the pitch with feces? Not ONCE? Not even a little bit? Pull the other one, mate.

Oh wait, this isn't in the US, is it? Nevermind...

Re:Keeps us from getting bored

[FuzzyDaddy]

My father just retired from the medical school faculty at the University of Pennsylvania, where they have the original experiments on spontaneous generation.

In these experiments, they sealed jars of some sort of growth medium which was sterilized. By showing that nothing grew in them, they disproved the theory that life was "spontaneously generated", and that it comes from previous life. They still have the sealed jars on display.

Dad always said he was tempted to sneak in at night and stick a mouse inside one of the jars.

Re:Keeps us from getting bored

[kin_korn_karn]

And the same company that is responsible for many of the Jumbotrons in our stadiums is also the one that manufactured half the airplanes used by Japan in WWII..

Re:Keeps us from getting bored

[Quikah]

It really doesn't matter who invented something when someone else makes all the money. I am not buying a telephone or television or car or computer from the people who invented it. I had a client from Manchester who once told me the British are great at inventing things but horrible at marketing.

You don't have to be rich to go to a good university. Many excellent state schools (UCLA and UIUC are 2 off the top of my head) are about $4000-$8000 per year for state residents (sometimes less). There are a ton of academic scholarships and student loans which can make the cost essentially zero until after graduation.

Cornstarch and Water

[FatAlb3rt]

Reminds me of a cornstarch and water experiment [slb.com] we used to do. Mix it together and you get a weird substance that exhibits properties of solids and liquids. Try it if you're bored...

Re:Cornstarch and Water

[jhines]

Cornstarch, a length of plastic hose, and a bunsen burner, or other flame source.

Fill one end of the tube with cornstarch, and blow on the other end, directing the cloud towards the flame source.

You'll want a tube that is arms length or better, if you value your eyebrows.

Fun with cornstarch in science class.

Re:Cornstarch and Water

[GoRK]

Licopodium powder (especially) or even flour works a lot better for the fireball trick. Another handy tip for lab fireballs is to attach a funnel to the end of the hose that contains the powder. You can pack a lot more in there that way, plus it will shield your hand if you wish to hold it near the end.

~GoRK

non-Newtonian fluid

[Kris Warkentin]

That is an example of a non-Newtonian fluid. Normal Newtonian fluids' viscosity is a function of temperature: the colder it gets, the thicker it gets. Non-Newtonian fluids' viscosity is a function of something else, in this case, force. That is, the more force you apply to it, the thicker it gets. If you want a really good and simple 'goop' recipe, try this:

-white glue, mixed with water, 50:50
-tablespoon of borax (from laundry section) in a few cups of water
-(optional) food coloring mixed with glue

pour the glue/water mix into the borax solution and it with thicken up. You'll pull out a slimy, goopy mass that is too watery to play nicely with but if you work it in your hands for a bit to get the excess water out, you'll have some fun. Bounce it around, slap it, tear it and it's more like a solid. Let it sit on your hand and it flows like a liquid. Plenty of fun.

Re:non-Newtonian fluid

[iabervon]

Incidentally, that stuff is a whole lot of fun to juggle. It's not difficult once you've got it going, but getting started is very difficult because two blobs in the same hand merge and a blob you're not paying attention to thins out and gets difficult to throw.

For real fun, juggle two blobs of this stuff and one of those plastic toroidal tubes of water, and remember which ones to squeeze each time...

Re:non-Newtonian fluid

[Decimal]

pour the glue/water mix into the borax solution and it with thicken up. You'll pull out a slimy, goopy mass that is too watery to play nicely with but if you work it in your hands for a bit to get the excess water out, you'll have some fun. Bounce it around, slap it, tear it and it's more like a solid. Let it sit on your hand and it flows like a liquid. Plenty of fun.

Egads! He's invented silly putty!

Re:Cornstarch and Water

[tgibbs]

I remember it as a practical joke. You make a mixture of cornstarch and water, and continuously roll it between your hands to that it makes a nice firm ball. Then you hand it to a victim, and laugh as it immediately turns into a messy puddle in his hand.

stealthy osdn slashvertisement

[Speare]

www.thinkgeek.com is reselling a goo they labeled "smart mass." The original product is Crazy Aaron's Thinking Putty. I'll leave it to google to provide links. Crazy Aaron has quite a few mpeg's of the product being shot from a potato gun.

It's similar to your cornstarch putty, though a bit more involved. It exhibits different properties on four different time scales. It will drip on its own weight slowly, will bounce firmly if dropped, will tear and shear if pulled too quickly, and will shatter if struck with a hammer.

Kinda like the force shields in the Dune movie and books. You can dent it easily with a fingertip if you move slowly, but it will repell your fist if you try to punch it.

It will take several years

[anandsr]

Considering that the 8th drop fell in Nov. 2000 and the one before that dropped in 1988, we have only spent the first two years. I would expect that it would take at least 5 years before the next one drops. It will require more thant the students there to keep us entertained for that much time.

Re:Keeps us from getting bored

[machine of god]

I admit, I shook the case, I'm sorry...

The Fluidity of Glass

[richie2000]

glass is not a fluid

Well, from that very link one can glean: 'There is no clear answer to the question "Is glass solid or liquid?".'. Of course, that does not absolutely preclude the possible truth of michael's assertion, but it does make it seem a little ambigous. Oh, the semantics!

Re:The Fluidity of Glass

[flamingmoose]

Q: Is glass solid or liquid?
A: Yes.

Seems like a clear answer to me.

Re:The Fluidity of Glass

[PhilHibbs]

Technically it's an amorphous solid.

Re:The Fluidity of Glass

[Dahan]

Jell-O is a... gel. Which is liquid suspended in a solid matrix.

Re:The Fluidity of Glass

[Citizen of Earth]

Seems like a clear answer to me.

I think that you're forced to talk about degrees of translucency.

Re:The Fluidity of Glass

[gimpboy]

besides if so much glass did actually shift from the top of an elaborate stain to the bottom, the picture would be long blurry, as they love making a big deal about how obvious the thickness difference is.

typically the colored pieces of stained glass windows are separated by a border of lead and tin i believe. this would prevent them from blurring. i once saw a presentation on this, and the lady giving it said people who make glass look at glass from ancient rome. evidently they provide good data points.

Re:The Fluidity of Glass

[babbage]

The thing is, does the apparent thickness difference mean anything? Is it even the case that all centuries old glass is thicker at the bottom, as opposed to along some other axis?

If not, and you find exampls where say the top of the glass is thicker pretty frequently, then the idea that glass flows isn't as compelling as the idea that only in modern times have we been able to mass produce industrial quality, evenly flat panes of glass.

But even if the panes are generally thicker on the bottom, what does that mean? Maybe it was easier / safer / more reliable to set the thick end of the glass at the bottom. Maybe it's easier to install that way. Maybe experience showed that glass set that way held up longer. Who knows?

Either way, "melting glass" is only one of several explanations, with others including "no difference" and "difference can be explained by work practices", and it isn't clear which if any explanation is the valid one.

Re:The Fluidity of Glass

[Sabalon]

"what's playdough"

I'll let my 3 year old answer that one.

Yummy.

Re:Stained Glass

[Tablizer]

Just goes to show you that you can't argue experimental evidence with logic. I wish I would have met you in a group of people, had you calmly point your astounding piece of logic out ot me, so I could have pointed out how pretentious and silly you were arguing that somthing very verifiable didn't exist, because it didn't make sense.

Boy, you must be real fun to have lunch with :-)

Wow!!!

[autopr0n]

I had no idea that micrometer's were able to see into the past! I thought they just mesured length!

Re:Glass DOES flow (Re:The Fluidity of Glass)

[Suppafly]

Wrong, read the linked article.

Re:Glass DOES flow (Re:The Fluidity of Glass)

[Shanep]

Just because something is written in an article, does not make it correct.

His conclusions are flawed at best.

Telescopes doomed?

[Tablizer]

This may not apply to all varieties of glass however, but the old glass panes are definately thicker on the bottom (and we not when installed).

Even a *small* amount of "flow" would ruin telescope optics over say decades. If true, then my little ol' 60mm may grow nearly useless soon.

I hope those who chewed you out for not reading the slashdotted article are right and that the lenses won't warp.

You are wrong

[autopr0n]

The glass was thicker at the bottom when it was made. Usualy it was put big-side-down, but occasionaly you will find window panels where the larger part is on the top.

Re:Glass DOES flow (Re:The Fluidity of Glass)

[autopr0n]

Conclusion: Glass will flow download, but the motion is imperceptible and extremely slow, not noticable except over a long period of time. This may not apply to all varieties of glass however, but the old glass panes are definately thicker on the bottom (and we not when installed).

Or: People couldn't make perfictly flat glass, and chose to put the fat-side down to make the window more stable.

An epiphany!

[echucker]

Ya know, ppl sitting around eating pizza waiting for this to happen is how they get too fat to work for the FBI! [slashdot.org] ;-)

did it drop already?

[morie]

I can't see it on the movie! Maybe that is because the movieserver is slashdotted.

Kelvin's experiments

[Bazzargh]

Lord Kelvin (William Thomson) created an older pitch experiment: one which had a variety of objects lying on a tray of pitch that are slowly sinking in. [wolfram.com]

Its usually on show in either the Hunterian Museum [gla.ac.uk] or the Department of Physics and Astronomy [gla.ac.uk] at Glasgow University.

As I recall, this is considered the oldest continuously running scientific experiment, with the exception only of a wheat-breeding experiment in England? (I can't find references on that, just remember it from back in the mists of time)

BTW: it is more fun to watch paint dry - its faster...

Re: Kelvin's Pitch Glacier

[szyzyg]

I rememebr this, it used to sit at the front of the old Kelvin Lecture theater before the remodelled it, in fact it sat out in the open and it was pretty much gathering dust.
It was more like a little series of steps, pitch had been placed in a reservoir at one end and had flowed down the steps into the reservoir at the other end. In fact it had started overflowing at the bottom.

Re: Kelvin's Pitch Glacier

[Bazzargh]

I remember the pitch glacier too, and I guess it was undustable (a 100-year-old layer of dust having just sunk into its surface). However there was a different experiment /as well/ - which had thinks like corks and metal weights lying in it. The pitch glacier was (I guess) meant to amuse the students, whereas the other one actually was an experiment.

I'm not sure you'd have seen this one, at the time you'd have been passing through (I checked yer homepage) the Kelvin Museum on the 4th floor was also the lecturer/postgrad coffee room and pretty much out of bounds to undergrads.

When the room was found to be riddled with asbestos :( during the installation of the new floor for the Astronomy dept, most of Kelvins things either went to the Hunterian or into a skip (I kid you not).

-Baz (PhD, Nuclear Theory, Glasgow 1990-94)

Re: God's experiments

[cioxx]

I'd consider the universe to be the oldest experiment that I know of, or is it just a very elaborate joke?

In reality God is a hacker who rooted the Universe.

So yes, it's a big experiment (read: Honeypot project)

Re:Kelvin's experiments

[Bazzargh]

thats the one! Thanks!

Did michael read his "glass is not a fluid" link?

[pmc]

Apparently not, or the link would have been "Is Glass liquid or solid?", the actual title of the article. I'll repeat the start of its conclusion here:

There is no clear answer to the question "Is glass solid or liquid?". In terms of molecular dynamics and thermodynamics it is possible to justify various different views that it is a highly viscous liquid, an amorphous solid, or simply that glass is another state of matter which is neither liquid nor solid. The difference is semantic.

Re:Did michael read his "glass is not a fluid" lin

[caffeineboy]

I think that this article is an attempt to rebutt the "glass is a liquid because it flows over long periods of time" line that was fed to you and everyone by their 6th grade science teachers. This has long been a beef of a glass science friend of mine... He is of the mind that amorphous solids should be classified as a different state of matter...

The whole "glass is a liquid" thing is a classic example of one of thos things that people say without really understanding understanding what they mean. This article, which is well written, addresses the two main points that you need to prove that glass isn't a "liquid".

• that what you mean by "is a liquid" is "flows over time"
  
• That there is no crystallization, and hence you have to define a threshhold viscosity beneath which you consider something not to flow EVER, even on geologic timescales, below which you allow something to be called "solid".
  

It then refutes the common and to my knowledge ONLY evidence for glass "flowing" on human timescales, the thickness difference in the top and bottom of old windowglass. Windows that are OPPOSITE what one would expect to find and the fact that hanging the windows with the thick edge down was common practice neatly debunks this evidence.

So, READ the whole article before you quote without understanding context...

Re:Did michael read his "glass is not a fluid" lin

[pmc]

I did read the whole article. I also studied the subject for a while when doing a physics degree at university so I am keenly aware of the context.

Michael was flat out wrong in that the article explained the debate, and the rather than supported one side of it. It is, as the article said, a matter of semantics.

Liquid means lots of things: the two most common technical meanings are 1) this flows and 2) this has no long range crystalline order. Hence by 2) glass is a liquid, and by 1) glass isn't. Hence the conclusion from the article that it is a matter of semantics.

fluid != liquid

[autopr0n]

Maybe he meant that even though it was a liquid, it was a not a fluid. The articaly clearly states that it is not a fluid (it will not move to fill it's container), although it may be considered a liquid.

Re:fluid != liquid

[pmc]

Doubt it - fluids = liquids + gases (by conventional meanings).

well, read the artical

[autopr0n]

A fluid is something that will change its shape to its container. A liquid is something that has spesific chemical properties, and may not be a fluid. That's why glass can be a liquid, but not a fluid. Read the artical.

Re:Did michael read his "glass is not a fluid" lin

[TillmanJ]

Robert H. Brill, Research Scientist

The Corning Museum of Glass

July, 2000

Early one spring morning in 1946, Clarence Hoke was holding forth in his chemistry class at West Side High School in Newark, New Jersey.

"Glass is actually a liquid." the North Carolina native told us in his soft Southern tones. "You can tell that from the stained glass windows in old cathedrals in Europe. The glass is thicker on the bottom than it is on the top."

Now, more than half a century later, that is the only thing I can actually remember being taught in high school chemistry. I didn't really believe it then, and I don't believe it now.

In the years that followed, I came across the same story every now and then. Most often it popped up in college textbooks on general chemistry. And now, thanks to the Internet, our Museum has received dozens of inquiries about whether or not this is true. Most people seem to want to believe it.

***

It is easy to understand why the myth persists. It does have a certain appeal. Glass and the glassy state are often described by noting their similarities with liquids. So good teachers, such as Mr. Hoke was, like to quote the story about the windows. As is the case with liquids, the atoms making up a glass are not arranged in any regular order-and that is where the analogy arises. Liquids flow because there are no strong forces holding their molecules together. Their molecules can move freely past one another, so that liquids can be poured, splashed around, and spilled. But, unlike the molecules in conventional liquids, the atoms in glasses are all held together tightly by strong chemical bonds. It is as if the glass were one giant molecule. This makes glasses rigid so they cannot flow at room temperatures. Thus, the analogy fails in the case of fluidity and flow.

***

There are at least four or five reasons why the myth doesn't make sense.

Some years ago, I heard a remark attributed to Egon Orowan of the Massachusetts Institute of Technology. Orowan had quipped that there might, indeed, be some truth to the story about glass flowing. Half of the pieces in a window arc thicker at the bottom, he said, but, he added quickly, the other half are thicker at the top. My own experience has been that for earlier windows especially, there is sometimes a pronounced variation in thickness over a distance of an inch or two on individual

fragments. That squares with the experience of conservators and curators who have handled hundreds of panels. Although the individual pieces of glass in a window may be uneven in thickness, and noticeably wavy, these effects result simply from the way the glasses were made. Presumably, that would have been by some precursor or variant of the crown or cylinder methods.

One also wonders why this alleged thickening is confined to the glass in cathedral windows. Why don't we find that Egyptian cored vessels or Hellenistic and Roman bowls have sagged and become misshapen after lying for centuries in tombs or in the ground? Those glasses are 1,000-2,500 years older than the cathedral windows.

Speaking of time, just how long should it take theoretically-for windows to thicken to any observable extent? Many years ago, Dr. Chuck Kurkjian told me that an acquaintance of his had estimated how fast-actually, how slowly-glasses would flow. The calculation showed that if a plate of glass a meter tall and a centimeter thick was placed in an upright position at room temperature, the time required for the glass to flow down so as to thicken 10 angstrom units at the bottom (a change the size of only a few atoms) would theoretically be about the same as the age of the universe: close to ten billion years. Similar calculations, made more recently, lead to similar conclusions. But such computations are perhaps only fanciful It is questionable that the equations used to calculate rates of flow are really applicable to the situation at hand.

***

This brings us to the subject of viscosity. The viscosity of a liquid is a measure of its resistance to flow-the opposite of fluidity, Viscosities are expressed in units called poises. At room temperature, the viscosity of water, which flows readily, is about 0.01 poise. Molasses has a viscosity of about 500 poises and flows like... molasses. A piece of once proud Brie, left out on the table after all the guests have departed, may be found to have flowed out of its rind into a rounded mass. In this sad state, its viscosity, as a guess, would be about 500,000 poises.

In the world of viscosity, things can get rather sticky. At elevated temperatures, the viscosities of glasses can be measured, and much practical use is made of such measurements. Upon removal from a furnace, ordinary glasses have a consistency that changes gradually from that of a thick house paint to that of putty, and then to that of saltwater taffy being pulled on one of those machines you see on a boardwalk. To have a taffy-like viscosity, the glass would still have to be very hot and would probably glow with a dull red color.

At somewhat cooler temperatures, pieces of glass will still sag slowly under their own weight, and if they have sharp edges, those will become rounded. So, too, will bubbles trapped in the glass slowly turn to spheres because of surface tension. All this happens when the viscosity is on the order of 50,000,000 poises, and the glasses are near what we call their softening points.

Below those temperatures, glasses have pretty well set up, and by the time they have cooled to room temperature, they have, of course, become rigid. Estimates of the viscosity of glasses at room temperature run as high as 10 to the 20th power Scientists and engineers may argue about the exact value of that number, but it is doubtful that there is any real physical significance to a viscosity as great as that anyway. As for cathedral windows, it is hard to believe that anything that viscous is going to flow at all.

It is worth noting, too, that at room temperature the viscosity of metallic lead has been estimated to be about 10 to the11th power, poises, that is, perhaps a billion times less viscous-or a billion times more fluid, if you prefer than glass. Presumably, then, the lead caming that holds stained glass pieces in place should have flowed a billion times more readily than the glass. While lead caming often bends and buckles under the enormous architectural stresses imposed on it, one never hears that the lead has flowed like a liquid.

***

When all is said and done, the story about stained glass windows flowing-just because glasses have certain liquid-like characteristics-is an appealing notion, but in reality it just isn't so.

Thinking back, I do recall another memorable remark by Mr. Hoke. One day, our self-appointed class clown sat senselessly pounding a book on his desk at the back of the room. "Great day in the mawnin', son! " shouted Hoke. "Stop slammin' your book on the desk. Use your head!" That was good advice-no matter how you read it.

Reprinted with permission from Dr. Robert Brill, brillrh@cmog.org

no, glass does *not* flow

[autopr0n]

It's not possible:

The glass transition is purely kinetic: i.e. the disordered glassy state does not have enough kinetic energy to overcome the potential energy barriers required for movement of the molecules past one another. The molecules of the glass take on a fixed but disordered arrangement.

Your windows are in the exact same shape they were when they were made.

Couldn't resist...

[Anonymous Coward]

It is pitch black. You are likely to be eaten by a grue.

Minor nit to pick.

[BrK]

According to the website [uq.edu.au] "that now, 72 years later, the eighth drop is only just about to fall.", it seems 7 drops have fallen so far and the 8th not the 9th drop is now forming. Although this seems like a minor detail, it's a 12% difference in the number of drops, which given that pitch has a computed viscosity of over 100 billion times that of water, 12% could add up to a lot.

Re:Minor nit to pick.

[Raetsel]

I was confused by that point as well. There is also this page [uq.edu.au] -- the link is right there at the top -- that states:

• "Technically speaking, the eighth drop in Parnell's famous Pitch-Drop demonstration experiment "fell" at the end of November last year, while I was overseas. Unfortunately the high-tech webcam's digital memory also suffered a bout of amnesia at the crucial moment. That was not all, however. When Parnell set up the demonstration in 1927 he could not have foreseen that during the gestation years of the eighth drop the University would decide to air-condition the two large lecture theatres in whose foyer the pitch resides, thus reversing the drop's seasonal experiences. That drop became by far the largest in the series, and when the time arrived for it to fall there was insufficient depth to the bottom of the beaker below for it to suffer a complete break."

Seven? Eight? Seems even they don't have a handle on it.

The two numbers are right next to each other no matter where on the keyboard you look. I can imagine someone mistyping it... it's not as if the page needs updating all that often. (Looks like the last update was 9 Apr.) Here's hoping they read /., notice this thread, and make the change. (Yeah, right.)

Re:Minor nit to pick.

[BrK]

Well, then. In light of the confusion about how many drops have actually fallen, and when they fell, I propose the experiment be restarted.

Nope

[p3d0]

Do the math. The experiment started in 1927, so the phrase "now, 72 years later" indicates that the web page is three years out of date.

In fact, another page [uq.edu.au] confirms that the 8th drop fell in November 2000, so it is indeed the 9th drop forming.

Re:Nope

[ColdChrist]

Perhaps the "72 years" refers to 1930, the year in which they cut the stem of the funnel and started the pitch dripping. Between 1927 and 1930 they let the pitch settle in the funnel.

Re:Nope

[stienman]

They also state that the glass tubing was cut open in 1930, three years after having placed the pitch into the funnel. Those three years the pitch was allowed to settle- therefore the experiment started in 1930, though it was prepared in 1927.

-Adam

Bah! That's Nothing.

[Bocaj]

They should test the viscosity of Waffle House waffle batter! That's some thick 5hit. Of course it hasn't been proved to be a liquid either. I think DuPont did most of the research for it. Maybe we could ask them.

Re:Bah! That's Nothing.

[putaro]

Mmmmm....waffle house. The only good thing I ever found in Huntsville Alabama

Couldn't resist

[jonman_d]

Sorry, but I just couldn't resist the pun...

Must be a slow news day.

Yeah, I haven't slept in 32 hours. That's funny to me.

Re:Couldn't resist

[scrytch]

> Yeah, I haven't slept in 32 hours. That's funny to me.

Looking at the amazing pitch-cam all night, were ya?

Am I the only one....

[GnomeKing]

...who when reading the article - and looking at the picture of the smashed pitch - finds it hard to get images of a slow motion T-1000 out of my head?

Re:Am I the only one....

[Alsee]

slow motion T-1000

The plot revolves around a time machine, remember?
It's not in slow motion, it's just traveling into the future really really fast.

-

Referenced article: Is glass liquid or solid

[Ctrl-Z]

Michael,

Please read the articles you link to. In particular, note the "Conclusion" section. Quote: There is no clear answer to the question "Is glass solid or liquid?".

I mean, you should know better than to post such blatant trolls.

Re:Referenced article: Is glass liquid or solid

[gorilla]

However, glass being a liquid or a solid is a different question to 'does it flow'. The answer to that is without any doubt, NO.

Anoyone done this quicker?

[squaretorus]

Has anyone tried something like this with a quicker (but not too quick) fluid?

This would make an excellent Calendar type device - a glass funnel full of SOMETHING (my rubber bible is at home - anyone got one handy???) that would drip through in about a year.

Great for lecturing opportunities when people say 'what the fuck is THAT' and point at your bell jar full of brown gooey stuff!

Another phenomenon almost as slow

[ch-chuck]

is a federal judge deciding what to do about the Msft case.

Cheese

[henben]

Never mind glass - is cheese a solid or a liquid?

I have heard that cheeses made in the middle ages have developed thicker rinds at the bottom over time due to very slow cheese flow, but I have never seen it firsthand. Does anyone know if cheese is a liquid or not?

Re:Cheese

[dublin]

It can be both or either. Especially interesting is the high-pressure cheeze delivery system [fertnel.com] developed by the world snak cheeze experts at Fertnel. [fertnel.com]

Anyway this site is a hoot, and I'm surprised it's still there. This was one of the first sites I remember on the web where someone actually committed to the then-considerable expense of registering a domain name and building a web server just for a joke. I'm glad to see this true relic of the old Internet is still hanging around (and apparently, in its original form, too...)

Pitch is used for polishing optics

[goingware]

Telescope makers and opticians use pitch for polishing glass.

I have a page about telescope making [geometricvisions.com] that should give you some jumping off points, but I haven't yet got to the polishing stage of the mirror I'm working on.

One reason for using pitch is that you can press a mirror into it and get a very close fit. Another is that if the mirror is not perfectly spherical, the pitch will flex as the mirror moves across it. And finally, the polishing abrasive (ferrous oxide or cerium oxide) will set in the pitch and have a planing action rather than rolling around and chipping little flakes off as in ordinary grinding.

Pitch is nasty stuff to work with. It takes a lot of practice before a novice telescope maker can make a pitch lap they're happy with.

Re:Pitch is used for polishing optics

[hyacinthus]

I've done some amateur optical work myself, and I know the properties of pitch first-hand. It's worth mentioning that the stuff sold as "pitch" these days isn't really pitch. Proper pitch is a pine-tar product; it smells nice and piney, but it's abominably sticky and subject to enormous changes of viscosity with respect to temperature, and also dangerously flammable. When the old writers like Rev. Ellison write about pitch, this is the material they mean.

Since then, high-boiling coal-tar and petroleum fractions have been formulated which resemble pitch in their physical qualities, but which are much more predictable and constant in their properties, and safer to work with (but smell like roofing tar when they're hot.) "Gugolz" pitch is a petroleum product. "Asphalt" would be a more accurate name, but "pitch" has come to mean any dark-colored organic tar.

One nit: ferric oxide (iron(III) oxide), not ferrous oxide, is the composition of red optical rouge. The cerium oxide used for polishing is the quadrivalent oxide, ceric oxide (cerium(IV) oxide), I believe.

One of the old writers (Ellison, maybe?) writes that if you put a cork at the bottom of container of pitch, the cork will eventually rise to the top. I don't know if this experiment has ever been tried.

My own mirror-making project eventually failed, by the way. I never got a good polish and eventually I gave up.

hyacinthus.

Pitch is used to build airplanes, too...

[dublin]

Another interesting use for the terribly versatile material called pitch is to form the precursor material (PAN) for Carbon (also called Graphite) fibers used in the modern Carbon composites that make everything from tennis rackets and fishing rods to airliners and the leading edge surfaces of the space shuttle.

The fibers produced by this process are very fine - typical "tow" widths are 12,000 fibers (about the diameter of a small string), 6000 fibers, and the fairly fine 3000 fibers.

We'd have a hard time getting by without pitch in today's world...

coffee

[Tharsis]

Now THAT's how I like my coffee...

Duplicate?

[da3dAlus]

I swear to god I saw a link to this site like 2 years ago in a round of Quickies. However, I'm sure the timeframe is such that the statute of re-posted links has run out. Damn the /. search page for not helping to prove me right!...

Why bother with pitch when there's Thinking Putty!

[bons]

Puttyworld [puttyworld.com] has a great explanation on why Thinking Putty can flow like a liquid and still shatter when hit with a hammer.

And it's more fun to play with than pitch.

And by Slashdotting the RealServer...

[jea6]

...we've guaranteed that noone will see the pitch drop. At least not until this goes "under the fold."

Glass is not a fluid

[kalidasa]

But maybe it's a liquid . . .

There is no clear answer to the question "Is glass solid or liquid?". In terms of molecular dynamics and thermodynamics it is possible to justify various different views that it is a highly viscous liquid, an amorphous solid, or simply that glass is another state of matter which is neither liquid nor solid.

From the page linked at the end of the posting.

Re:Glass is not a fluid

[PigleT]

"But maybe it's a liquid"

FFS, what do you think a fluid is? Fluid is well defined in GCSE Chemistry - if not before - as something in either the liquid or gaseous states.

Also, solid was well defined as something with a very regular molecular layout and as being resistent to deformation under pressure.

Seems pretty obvious to me, looking at my windows here...

The glassy state

[infocalypse1]

As a glass scientist, I wanted to add my 2 cents worth. Almost any substance can occur in a glassy state if quenched fast enough. This includes most metals, plastics, and pitch. Below a critical temperature (the glass transition temperature Tg) a glass is a brittle, perfectly Newtonian solid. At temperatures above Tg, viscosity decreases to the point where relaxation can occur, and the substance becomes rubbery, then fluid. The apparent viscosity at Tg is ~ 10^13 poise. Real motion is observed at ~10^8 poise. The Tg of optical pitch is a bit below room temperature, and the room temperature viscosity is ~10^9 poise. The problem with the experiment cited is that temperature fluctuations change the viscosity exponentially. Droplet formation time will vary accordingly.

Re:The glassy state

[Darby]

Almost any substance can occur in a glassy state if quenched fast enough.

So, is this how we get obsidian?
If so, what's the process?

It Dropped!

[n-baxley]

Wow, that's exciting. Except that I didn't see it actually drop. But I looked at the video and it certainly seems like it has dropped. Wow, I can't wait to see the real-time/slow motion replay.

RealPlayer G2?

[sunset]

I don't see any reference to it at real.com. Has anyone been able to play these clips under Linux? When I try it with RealPlayer 8 (which btw is not very easily found at real.com), I just get "PNR_SERVER_ALERT".

Flawed experiment

[John Harrison]

Whoever built this thing should have made it taller, much taller, say, 10 feet. Also, it should have been made with enough pitch to last 500 years. That would have been cool. As it is, the last drop of pitch didn't even completely fall. Soon there will be no more drops, just a continuous flow of pitch, because the setup is too short. Also, look at the container at the bottom. Can it hold all the pitch that is coming its way? I doubt it. Sooner of later this is going to make a big sticky mess.

Glass as a fluid

[SCHecklerX]

That website does not say that glass is not a fluid. Did you not read the whole thing?

From the last paragraph:

Conclusion

There is no clear answer to the question "Is glass solid or liquid?"

Glass liquid ?

[terrymr]

Oddly enough the article you cite to claim that glass is not liquid makes no such assertion. And in fact concludes that glass may be thought of as a highly viscous liquid as there is not a 4th state of matter somewhere betweeen solid and liquid. Glass does not exhibit the crystaline structure which is usually a definitive characteristic of a solid.

Where do you get pitch?

[jsimon12]

This would be a cool conversation piece around the home, and to pass on the your grandkids, so where does one obtain pitch?

Re:Where do you get pitch?

[pease1]

Any place that sells products to make astronomical mirrors. One example is Newport glass works [newportglass.com]. Look under their Astronomical catalog. Fusco Abrasives [fuscoabrasive.com] used to sell it.

Pitch and astronomical mirror making

[pease1]

I've had hands on contact with pitch for many years since you use it to polish and figure astronomical mirrors - a hobby of mine [ladyandtramp.com]. It is pitch's odd behavior that makes it possible to even make (figure) and astronomical mirror (since you force the glass into a non-spherical shape).

Amateur Telescope Makers often call pitch "funny stuff" since it will behave in different ways with just minor changes in the environment or handling.

The cool thing is that someone figured out how to make use of the properties long before we understood why it does what it does.

Re:That's where I will be!

[richie2000]

Read the article: "Fortunately you can also see students of the University of Queensland milling around outside the cabinet, so it is more exciting than watching grass grow!"

That would put it right up there on the Entertainment Index together with old Soviet tractor parades, Equal Opportunity Beauty Pageants For The Habitually Ugly and soccer.

apparently not many think so!

[tanveer1979]

I tried it.. and server has reached max capacity!.. So I guess many do not share your opinion.
It depends in what way you look at it, to a physics chap this may be one of the most beautiful things he's ever seen, while to a coder it may be damn damn slow and boring.

Far more fun

[gazbo]

You can actually creat a strange behaving liquid using cornflour. Just put a spoon in a glass, and add a tiny amount of water, then stir it in. Repeat until, well, it feels strange. You'll end up with a mass that you can stab with a spoon and it'll bounce right off the surface. However, you can pour it.

It's also strange to pur it onto a table - itpours out of the glass like treacle would, but then it breaks on contact with the table. Then, it liquifies again, very reminiscent of Terminator, when the shattered metal melts.

Re:Far more fun

[fjordboy]

You're thinking of "corn starch." Yeah...you're right though, that's a lot of fun. I prefer using a whole box and then just adding about a cup of water. It looks like you have a liquid....you can move it around in the bowl and everything. However, if you grab a pile and squeeze, it is solid....if you keep it moving, you can make big balls of it...however, if you let the ball sit in your hand, it just melts right through. That's some crazy stuff...anyone know why cornstarch and water does that?

Re:Far more fun

[AndroidCat]

The best demonstration of those weird properties that I've seen is to fill a small tub/wading pool with it. Then you get a vict^w subject to stand in it. Then you tell them to quickly step out of it. The gooey stuff suddenly turns to concrete around their feet.

Make sure that they've signed the personal injury waver first, of course...

Hmm pity, they don't have this demo on their web page Ontario Science Centre [ontariosciencecentre.ca] only a block away from me.

I'm already there

[xeosdd]

As a UQ student, I'm lucky enough to see it once a week. Since its last drop, there's now a big long tail from the drop to the funnel. I imagine that, just like before a drop, the physics staff and students will gather round and place bets on when they think it'll break off. Apparently there is a fair bit of money in it...

And this is just one example of how our Federal Government's massive spending cutbacks on higher education, and the consequent reduction in spending on research, can produce breakthroughs in science. But of course, our biggest breakthrough is our Scramjet program -- NASA's hundreds of millions of dollar and hundreds of brilliant scientists and engineers, we did for A$1.5 million (that's about US$7.84), a couple of basements full of shock-tunnels, some second-hand rockets, and a handful post-grad students.

Finally, seeing as everybody enjoys looking at UQ web cams so much, you can also view FoyerCam [uq.edu.au], an incentive to make us messy students keep out foyer clean in our computer science building. There's more cams here, but having 2 servers /.ed will probably land me (or somebody else) in a great deal of trouble. And of course, no visit to UQ is complete without a visit to kewn [come.to].

Re:Fluidity of pitch

[mabinogi]

If you read Michael's link, you would have read that the glass being thicker at the bottom was due to the manafacturing process...

Re:Pitch

[Jugalator]

This was what came up in my mind too. But nothing surprise me anymore. I just thought, oh some nerds have found out that tones are really fluid when treated in some weird way... :-P

Heh

[autopr0n]

Yeh, thats what I thought to.

Re:Slashdot wrong again

[Darby]

How exactly is a fluid different from a liquid?

Woo Hoo!
I remember this one from freshman chemistry.
Fluids flow, man.
Fluids are liquids *and* gases.
The major macro-difference between liquids and gases is that gases are compressible.

did you ever learn to read?

[autopr0n]

"Glass is not a fluid"
And
"glass may be a liquid"

Are not incompatable statements, as 'fluid' is not the same thing as 'liquid'

The artical clearly states that glass will not flow, so it is clearly not a fluid.

Re:Glass

[mindstrm]

Yeah... and you know this how?
The process that creates uniform glass panes is less than a century old.

Why is it so hard to grasp. Glass does not flow unless molten. It is not some kind of vicsous fluid, like pitch. The glass pane in your old school looks the same as the day it was installed, except for maybe some scratching due to the elements.

Read more carefully.

[mindstrm]

In Michael's defence....

The article states that glass can be considered either a solid or a liquid.

but it is definately not a FLUID

Fluid does not mean liquid
liquid does not mean fluid

Glass does not flow. A chunk of glass in a jar will not, over time, flow to fill it up evenly.

A chunk of glass in a funnel will not slowly drip out the bottom.

Window panes do NOT flow towards the bottom, making the bottom thicker. They were simply made that way becuase of the manufacturing process of the times.

Glass is not a fluid (unless you get it really hot, in which case it most certainly is a fluid)