Amorphous Steel 110
pfdietz writes "Researchers at Oak Ridge have achieved a holy grail of materials science: they have figured out how to produce amorphous (glassy) steel. The material is reported to be twice as hard and have twice the tensile strength of the strongest ultra-high tensile strength steel alloy."
Transparent steel-w00t! (Score:4, Funny)
Posting anonymously to protect my karma from Apple zealots.
Great. Now how will we fight the Robots... (Score:2)
Re:Great. Now how will we fight the Robots... (Score:3, Funny)
Re:Great. Now how will we fight the Robots... (Score:2, Funny)
Re:Great. Now how will we fight the Robots... (Score:2)
Re:Great. Now how will we fight the Robots... (Score:1)
Well, now we have SilkSteel! (Score:1)
Re:Great. Now how will we fight the Robots... (Score:3, Interesting)
Re:First post! (Score:2, Informative)
"The researchers have produced centimeter-sized pieces of the amorphous steel, and they feel that structural steel in bulk metallic glass form can be produced economically with traditional drop-casting methods, in which metallic glasses are made by pouring the hot liquid into a cold copper mold."
The big news is it is now easier (Score:2)
Amorphous iron based alloys have been around for a while, I had a bit that was handed out as a sample well over a decade ago.
The big news, if this is true is that they are easier to make now. The way to get the disordered iron alloys before was to chill the molten metal at a rate of a few million degrees K per second - ie. solidify the molten metal in a tiny fraction of a second.
How Long Will It Be ... (Score:3, Funny)
before the nanotechnologists are able to reproduce this material an the atomic scale and essentially "grow" amorphous-steel items?
I want my +5 Broadsword of Nerdly Might!
One step away... (Score:3, Funny)
Re:One step away... (Score:2)
Thank you ... (Score:3, Interesting)
However, all kidding aside
By 'glassy', can anyone shed light on this actually infers? I'm thinking more to do with material versus optical properties. (Yes, I R'd TFA, and they certainly don't say anything about optical properties.)
Re:Thank you ... (Score:1)
Re:Thank you ... (Score:4, Informative)
This is non-crystalline steel. It's not transparent aluminum - but then, nothing is.
Re:Thank you ... (Score:2)
Re:Thank you ... (Score:2)
However, the claim about the amorphous steel being "twice as strong and hard" smells funny to me... twice as hard? On what sort of scale? Isn't steel already about 2/3 as hard as diamond anyway? Does that mean that amorphous steel is 4/3 as hard as diamond? How would they measure that?
Enquiring minds want to know!
Somebody explain this to me? (Score:5, Interesting)
Ok, somebody who understands materials science explain this to me, please: is the amorphous steel's hardness and strength greater because the non-amorphous, crystalline steel breaks easily along a row of atoms, as if along a perforation, while the amorphous steel, lacking such an orderly structure, lacks long runs of bonds along which breaks can be easily made?
Pictorially, is it like this?
Re:Somebody explain this to me? (Score:4, Insightful)
Re:Somebody explain this to me? (Score:5, Informative)
High strength alloys generally try to put extra chemicals in the metal mixture to block the movements of the dislocations. Also, you tend to "quench" the formed metal so that the crystals that it forms (called "grains") are small. Smaller grains usually means stronger metals because they can only "unzip" a short distance before they hit a different grain with a different orientation.
These guys at ORNL have basically taken the tiny grain idea to the ultimate limit. Each grain basically only has one or a few atoms in it. FYI, IAA Mech. Engineeer.
Thank you very much! (Score:3)
I've understood the basics for some time, but the way you put it has to be the most clear description of exactly why it works that I've seen.
Now it makes sense why adding a metal as soft as zinc to aluminum gives you "aircraft grade" (7000 series) alumimum, which is twice the shear and tensile strength of "marine grade" (6000 series) aluminum, which contains the much stronger magnesium instead.
Re:Thank you very much! (Score:2)
Re:Thank you very much! (Score:4, Interesting)
I used to work in a machine-shop, both in design and in purchasing (for several years).
Reynolds and many others consider 6061 and 6063 to be marine-grade.
They also consider 7075 to be aircraft grade... twice the shear and tensile strength of 6061, but also twice as expensive (cost/lb).
The T-rating ("-T6") is a hardening that it receives after forming, irrelevant to the alloy.
As far as what is spec-ed out, I agree... you should be able to use 6k series in an airplane, for example in a coffie-pot-holder.
Oddly enough, we made a run of those for an airline, and they spec-ed it had to be 7075-T6.
And people wonder why air-fare is so expensive... bozos are making the decisions.
The reverse is true too... we made a run of bicycle crank-axles that were spec-ed to be 7075-T9! Hardly an airplane, but those puppies sure were expensive!
Re:Somebody explain this to me? (Score:5, Interesting)
One thing worth noting: While the tensile strength is increased greatly, it is also glass-like in that if you hit it with a baseball bat, it explodes in lots of little shards. It has to do with the lack of a lattice structure keeping it together.
Another thing I thought was interesting: steel knives sort of shed molecules and become deformed at the knife-edge when you use them, requiring you to sharpen them. Glassy steel knives wouldn't do this. You could literally pour yourself a knife in a mold and have a never-dulling knife -- assuming you don't drop it. :-)
Re:Somebody explain this to me? (Score:2)
You could use it the same way we use glass (Score:3, Interesting)
I can see the glass issue as a problem for some of the proposed uses, though. To retain its strength it would have to avoid crystallizing; if you used it for beams in a building, you would have to guarantee that a
Re:Somebody explain this to me? (Score:1)
Liquidmetal mentioned in Discover article (Score:2, Interesting)
Although the Discover article says that knives can be easily cast (e.g., for surgical purposes, disposable knives can be made much more easily), the metal isn't as hard as hand-made knives.
Knives. (Score:2)
As for loosing thier edge knives loose it from that however you can remove most of that from a sharpening steel. You loose alot of your edge from hitting the cutting surface, which is the main reason(besides costs) cermaic knifes are used for soft stuff as opposed to dicing an
Re:Somebody explain this to me? (Score:1)
My dad has owned a ceramic kitchen knife for about 18 years now. It took a long time, but it's definitely not as sharp now as it was when he got it (in fact it's more like a ceramic letter opener at this point).
I imagine a glass steel knife would perform similarly, but IANA mechanical engineer.
Re:Somebody explain this to me? (Score:1)
Some metals they might find next (?) (Score:5, Informative)
BTW, if you can't get a gmail invite from the poster above, they are giving one away periodically from the bottom of this Google Compute page. [powder2glass.com]
There are several special metals in the Marvel universe that can have a place in the World of Darkness. These metals are usually very hard; much harder than mere steel, and they are not very ablative. They are also very rare, in general. One or two of them have special properties.
Adamantium
Adamantium is the hardest metal known to man, though it has not been made clear how dense it is. One would suspect that its density is roughly the same as that of normal steel, though a Storyteller can rule that it is as heavy as lead or as light as magnesium. At any rate, it would appear that no force on earth is sufficient to break or bend adamantium when it is at a normal temperature. Wolverine has used his adamantium-coated claws in Arctic climes as well as steamy jungles, so there is no reason to suppose that the metal becomes brittle at low temperatures. Judging from the number of times Wolverine's flesh has been roasted or vaporized right off of his skeleton in the comics, with no visible effect on the metal, we must assume that adamantium has a relatively high melting point. In any case, to be nice to Logan, it also seems likely that it has a fairly high specific heat capacity, at least for a metal. It may or may not be one of the magnetic metals- as seen in X-Men 25- because Magneto has enough raw power to reach down and repel protons in the raw, if he wants to.
There is a special process that allows adamantium in ionic (salt) form to be bonded to human bones- as in Wolverine's skeleton- or even human skin- as in Cyber's case. This process was developed by a Japanese scientist and villain called Dark Wind, and stolen (or sold) for the benefit of Department H, a branch of the Canadian Ministry of Defense. The following characters have some sort of connection to the metal, or are actually running around wearing it: Wolverine, Cyber, Dark Wind, Apocalypse, the Professor (not Xavier), Ultron, Lady Deathstrike.
Carbonadium
Carbonadium is a resilient, unstable metal that is much tougher than steel but more flexible than adamantium. It would seem as though it is a difficult and extremely expensive process to make carbonadium, which is probably an alloy of some kind, since there is apparently only one carbonadium synthesizer in the entire world. Carbonadium, like its more resilient counterpart adamantium, would appear to have a high specific heat capacity and melting point.
Carbonadium may or may not have one unique property: it may serve to stabilize a life-force vampire's condition, which would keep the mutant from having to drain the life force of others to survive. This may be a simple fact of Omega Red's condition, rather than something general to life-force vampirism.
Omega Red's tentacles are composed of carbonadium, and it is possible that his skeleton is also laced with the stuff. Other characters with a link to carbonadium include Wolverine, Sabretooth, Maverick, and John Wraith.
Omnium
Omnium is an extremely hard, extremely rigid metal that is likely to be second in resilience only to adamantium. In any case, it would seem that it is even less likely to bend without snapping than that metal. Omnium is not a commonly used or mentioned metal, but it has appeared on rare occasion in Marvel comics.
There was an acolyte of Magneto that had the power to change either himself or another person into an aware omnium statue. Other characters that have been seen using or testing the metal include Penance and the White
Re:Some metals they might find next (?) (Score:5, Funny)
Re:Some metals they might find next (?) (Score:2)
Lithium carbonate [healthatoz.com]
Remember what the nice doctor said? "Comics are not reality." You don't want to have to go back to the hospital, do you?
Say it to yourself a few times: "Comics are not reality. Comics are not reality." That's a good boy, we're all friends here, no one's going to hurt you. Just put the comic down and lets go for a walk outside in the fresh air, OK?
Re:Some metals they might find next (?) (Score:2)
Re:Some metals they might find next (?) (Score:1)
Re:Some metals they might find next (?) (Score:5, Funny)
Unobtainium
Unobtainium is the preferred material of fantasy weaponsmiths for creating arms and armor capable of great feats otherwise impossible by any other means or craft. Many a spell is also said to be enhanced just by the mere possession of the substance. In the far-flung future, it is used in every sector of industry from composing and fueling spacecraft, anti-gravity devices, matter-teleportation machines, polymorphing robots, slashdot-effect-proof web servers, faster-than-lightspeed engines, time travel, to making the construction of 100m tall walking war machines possible.
There is even a rumor that a crash-proof version of Windows exists that requires a special CPU made of pure unobtainium.
Despite its extreme usefulness, there is no known location in the universe where the substance can be mined or produced. Furthermore, there have yet to be any published studies regarding anything about the substance itself; yet there are thousands of studies and papers regarding its many applications.
Deaminite (n. dee-em'-in-ite)
Deaminite is typically found in the construction of mundane objects that are, for reasons unexplained, immobile, impossibly heavy, or otherwise indestructible. There are many a legend involving bands of heroes, who's quest came to halt all because of unlockable and unbreakable doors composed of deaminite. Known artifacts composed of deaminite include: the impossibly heavy weapons of the gods, armor worn by 40th level death knights, Jackie Chan's head, The outer hull of the starship Enterprise, and NYC cockroaches.
Typically encounters with an object made from deaminite result in a loud booming voice, seemingly from nowhere, uttering phrases like "You cannot pick that up", "You cannot do that", "Its too heavy", "No, because I said so", and "You see a grue".
Ironically, unlike unobtaininum, Deaminite has never actually be obtained for any purpose whatsoever, so its composition and properties are completely unkown.
Re:Some metals they might find next (?) (Score:3, Funny)
Vibranium
Vibranium is a special metal with unique properties. When electrical current is passed through it, it begins vibrating erratically.
Characters seen using or "testing" (for periods of several hours) vibranium include Sybia and Eccentrica Gallumbits.
Further reading... (Score:3, Informative)
Apparently amorphous metals are considered by some scientists to be a type of liquid rather than a solid. Kind of like glass, if you look at an old house you can see that the windows have slowly flowed downward.
Re:Further reading... (Score:5, Informative)
Urban Legend, or at least most of the way to being one. The observed thickness variation is due to the Crown glass process of making glass sheets in that period: it involved spinning out a 5ft diameter disc of glass, thick in the centre and thin at the edges, and cutting the rectangles from that. There are apparently as many panes thicker at the top or the sides as at the bottom, although possibly some glaziers did have a preference for putting 'thick edge down'.
If glass did flow, extremely ancient (Myr) naturally occuring glasses like obsidian, fulgurites or tektites would have flowed into puddles! (they havent). Or if that doesnt convince you: the tolerances on the optical components of large telescopes are so fine that flow of the glass at the claimed rates would distort the image within days.
See, for example, "Do Cathedral Glasses Flow?", Am. J. Phys. v66, pp 392-396, May, 1998
NB. Glass can creep under loading, however - but thats for another thread.
Re:Further reading... (Score:2)
To see the effect in window glass would take many many thousands of years. Not sure about obsidian or what the flow rate would be.
And yes as you mentioned, the apparent flowing of old glass is for 2 reasons. As you stated it's due to the production method, also the myth has been encouraged by the glass being normally installed with the thicker side down.
Ward
Re:Further reading... (Score:5, Informative)
Old glass manufacturing technics were VERY imprecise. You might end up with a pane that had a thicker edge, in which case you would naturally put it on the bottom for balance.
Or you might end up with fairly uniform edges but have an irregular surface that looked like it was "flowing" but was static. I have picture windows in my house that are about 70 years old that have this "flow" pattern and have had people remark that the liquid must be pooling
Even if glass -does- flow (see the "a" link at the beginning), math shows it would take millions of years to complete the process, meaning no glass made by man would yet show visible signs of deterioration.
And you're right, "glassy" in this case is about the physical structure of the metal, not the light transmitting/absorbing aspects though those are probably mildly affected (I imagine a glassy steel will hold a shiny polish better than a crystal steel).
Re:Further reading... (Score:1)
My god teachers are shit, or at least mine were.
We were taught this "fact" in, I think, the first year of secondary school by our science teacher.
Horrible.
Re:Further reading... (Score:3, Informative)
You can also find an abstract [aip.org] and a PDF [aip.org] of the whole article on the physical review letters site (a few links in from the article Slashdot linked).
These are letters, so they haven't been through rigorous peer review, but the authors take great pains to cite related work and describe their experiment in excruciating detail, so their results are almost certainly perfectly valid.
Capsule summary: Adding about 1.5% ytterbium to steel alloys make
Re:Further reading... (Score:1)
Re:Further reading... (Score:1)
Right. "Glassy" is just another word for "amorphous"; that is, noncrystalline. Glassy materials are solids, but they aren't arranged in any sort of pattern. In crystalline materials, the atoms are all lined up nicely in a repeating pattern. In an amorphous, or glassy, material, the atoms are arranged randomly. Window glass is simply amorphous silicon dio
Two words... (Score:5, Funny)
"Hello? computer?"
"Just use the keyboard!"
Re:Two words... (Score:3, Funny)
Re:Two words... (Score:1)
Navy (Score:2, Insightful)
Re:Navy (Score:2)
Re:Navy (Score:2)
Grind, plasma-cut or EDM-machine notches in the edges for finger joints and glue them together (brazing will work just as well if you won't get crystallization). Another method would be to plasma-spray more of the same alloy into the cold joint and roll smooth between applications; this way the joint would be composed of the same glass as the bulk plate.
If the bulk material has low shatter resistance it might no
Re:Navy (Score:2)
Glueing seems kind of scary. Overall not likley to happen. The Navy is having a hard time getting any new subs much less one with a new tech hull. Since the fall of the USSR subs have a low priority. Heck the have even retired the S-3. Still a nice idea though. How about a carbon fiber hull
Re:Navy (Score:2)
Indeed. Without an enemy armed with ICBMs, SLBMs or a serious navy, submarines don't have
Re:Navy (Score:2)
Loss of expertise is only one element (Score:2)
NASA has spent tens of billions on a series of programs to develop Shuttle replacements, and all of them have been total fiascoes. This is what appears likely to happen to a super-cool submar
Re:Loss of expertise is only one element (Score:2)
I would say that the potental ASW threat is real. Can you think of a better way to put a commando team "state terrorists" ashore than a sub. Look at North Korea. How about putting ashore bio or chemical agents? The US has a huge amount of cost line. In the 80s drug sugglers used to run across the boarder all the time. That has been pretty well shut down.
After WWI people t
Re:Loss of expertise is only one element (Score:2)
Could I do this with a WWII-style diesel/electric sub? Probably. Could I do this with a modern version thereof, powered by off-the-shelf fuel cells burning fuel with liquid oxygen and able to stay underwater for a week? Almost certainly. Do I need a modern nuclear hunter-killer sub or SLBM sub for
Re:Loss of expertise is only one element (Score:2)
I can see no problem with fewer subs but loosing the ability to build them I see as short sited.
Three SLBMs? Two few by far. The 14 or so that we have now is about the least I would want to have. With three you would have at most two at sea at a time and sometimes only one. Just because right now Russia is not a threat does not mean that they could not become one in the future. I will admit that I feel that India is less of a threat now
Navy uses (Score:2)
1. landing gear
2. arrestor hooks
Subs can't go any deeper. (Score:2)
Only niche subs with limited caps can't go deeper (Score:2)
Only specialized research (niche) subs with very limited capabilities "can't go any deeper". Their designs are not applicable to high performance high capability cost effective combat vessels. That said, those research subs are amazing.
Re:Subs can't go any deeper. (Score:1)
But what about habitats? I'd move to the Mariana Trench Habitat tomorrow, if I could.
(... long as it had free cable and good gym facilities that is
Re:Navy (Score:2)
Uber-steel would make a significant contribution to lightening the load. That way our brave boys can drop out of planes to bring death, er, liberty to the evil-doers - and also avoid getting fragged by said evil-doers' RPG-7s.
Re:Navy (Score:2)
Re:Navy (Score:2)
You will *NEVER* find all 15 of our submarines.
Glassy Metal article in Discover (Score:2, Informative)
Transparent? (Score:2)
The article doesn't mention if it has superior resistance to rust, though. This just talks about the crystal size.
QUESTION: It would seem to me that an ordered solid crystal, such as ordinary steel or glass, would have superior strength, due to every atom having the maximum number of molecular bonds with its neighbors.
Why,
Re:Transparent? (Score:2)
Re:Transparent? (Score:3, Informative)
Re:Transparent? (Score:3, Funny)
here [amazon.com] is your "Invisible Toaster"
Re:Transparent? (Score:2)
Re:Transparent? (Score:2)
You want to be Wonder Woman?
Just more of the ancient art of hardening. (Score:2)
Hardening. I heat the steel to its decolessant point, where the atoms are moving so fast they can no longer align in a magnetic field (so magnets don't stick), then quickly cool the steel. It is hardened and at the same time becomes more brittle.
Tempering is then applied, where the hardened steel is warmed gently to various degrees and again quickly cooled to remov
Re:Just more of the ancient art of hardening. (Score:2)
(Are you sure you spelled "decolessant [google.com]" right? You should write to Google and have them add the word to their index.)
Re:I've seen this... (Score:2)
Thus why we're just now seeing it come out.
Re:I've seen this... (Score:2)
Amorphous Metals are Old News (Score:1)
No, amorphous metals are not transparent. So even if we could make amorphous aluminum, you could not see through it. If you want to see through aluminum, you must still combine it with with oxygen to form alumina (or sapphire).
It's likely more brittle than glass too (Score:2)
Transparent aluminium (Score:2)
What about Titanium ? (Score:1)
Devitrification (Score:2)