Astrum, the starly metal found in fallen stars. It is coming mixed with meteorite iron, so it must be purified through difficult procedures. Pure astrum by custom is enchanted so anyone who touches it doesn't need to breathe for as long as tactile contact continues, and as well, astrum is known to be a legendary material for swords, for "every strike is powered by the kinetic force of a fallen star". It is not indestructible, so even through you can chop trees with it, the blade will shatter if it hits something that is too hard to chew through.
Cloud ice, a special kind of snow that is holding form, doesn't melt for a long time and regenerates through absorbing humidity. Cloud ice is used as a decorative material, and as a working air-cooling conditioner. Manufactured through magic and runes.
Acom crystal, a yellow crystal that protects from mind readers.
Algofite, a silvery stone potent for rune magic. Looks like black marble with cracks of silver webbing.
Antiaurum, or negative gold, is an alchemical material that looks just like normal gold but, once it touches the actual gold, starts a dissolving reaction in which both materials turn into nothing but copper grains and heavy, harmful smoke. Known as a Midas' Demise, it is a dangerous tool that turned entire kingdoms bankrupt from one coin being put in the treasury.
Powdered Raven Hoof, alchemical material made from a rare breed of pegasi or gryphons, a mix between equine and corvine. Is used as a stabilizer of wild magic, and in a Wild Magic Tamer potion that allows mages to control chaos in powerful ways for about 17 minutes.
Balcatite, a black mineral of dense, solidified bad luck.
Cold glass, a special kind of glass created through transmutation rather than smelting sand. Said to be as transparent as air, and giving no reflections.
Meta rock, the pure element of stone - is chemically inert to everything but other pure elements. Used by gnomes as a perfect castle wall building material.
Libidum berries, found in the second circle of hell and having strong aphrodisiac and potency heightening properties. Is invasive, and sometimes gets to the mortal planes as its seeds get carried there on the clothes, hair or skin of demons. Have resemblance of small, red pumpkins with fourfold symmetry.
Heltrock, unique volcanic rocks that are indestructible from all points except one. If hit there, in the focus, the whole rock will violently explode, throwing obsidian-sharp shards everywhere.
Stormbow, a liquid material that glimmers in all colors of the rainbow and gives tempest strength and lightning aura to anyone who consumes it. Found in the rainwater from an eye of the storm, purified and distilled.
Jursa, a drug that replicated itself through contact with unfiltered goat milk. Has relaxing effects and causes fails in visual recognition of objects and people. The addicted can't tell the difference between a spoon and a fork even though they know it, same goes with remotely similar people and objects. Might develop face blindness.
Acanthite - mineral that freezes water on instant, turning it into hard, cold calcite spikes. Used in dungeon traps.
Mageweed, a plant that grows around mage towers, giving non-magic users the effect of tobacco, but seven times stronger. Sometimes used by evil mages to lure people into traps, afterwards using them as experiment subjects. Side effects include curly facial hair and blue spots of skin discoloration.
Bugshroom, grows above buried rusting metals. Upon consumption, gives short-lasting magnetic sense, but upon prolonged repetitive consumption can give the user allergy to glass.
Bankmetal, an alchemical metal made by melting an entire treasury vault door and one golden coin while reading a specific incantation. Bankmetal drives wealth towards itself, and scares off fairies if rubbed with a hand.
Retvam, a material created through fusing bone, iron, marble, glass and oak wood. Looks like cheese, but with texture of tree bark, hard and indestructible by means of common materials and forces, and has an ability to "activate" and radiate life energy. Used in warforged, sometimes as a cloaking device of sorts.
Applying real materials science principles to see how close we can get to Star Trek in the real world. What makes materials transparent and how can we design new transparent materials? Are aluminum-based compounds really viable as high-strength materials?
Colourful interactive table of fictional metals from all areas of popular culture. From Wolverine's claws to TARDIS doors, make your inner geek smile and go click crazy! Click now
Cool things I found: An interactive table of fictional metals and alloys! Most of them ain’t public domain, but they’re still good inspiration for your own stuff!
Vibranium’s the lifeblood of the Black Panther universe—the metal that helped propel Wakanda into a hyper-advanced technological society and granted Black Panther his superheroic abilities via a Vibranium-mutated heart-shaped herb. The Wakandan strain, sheared off a meteorite hundreds of years ago, has a number of useful properties—primarily, its ability to store more energy than any known terrestrial substance. As armor, it renders its wearer unstoppable; as sneaker material, it can neutralize leaps from tall buildings.
Vibranium’s the lifeblood of the Black Panther universe — the metal that helped propel Wakanda into a hyper-advanced technological society and granted Black Panther his superheroic abilities via a Vibranium-mutated heart-shaped herb. The Wakandan strain, sheared off a meteorite hundreds of years ago, has a number of useful properties — primarily, its ability to store more energy than any known terrestrial substance. As armor, it renders its wearer unstoppable; as sneaker material, it can neutralize leaps from tall buildings.
Could such a substance ever actually fall from the sky? Are there planets out there that could, plausibly, harbor vast quarries of Vibranium-like materials? And if not, how far along are we in inventing those materials, or similar ones? For this week’s Giz Asks we reached out to a number of materials scientists for some answers — and while most denied the possibility of a Vibranium analogue existing on another planet (let alone our own), all proposed workable man-made substitutes.
Yury Gogotsi
Distinguished University and Charles T. and Ruth M. Bach Professor, Materials Science and Engineering, Drexel University, and Founder/Director of the Drexel Nanomaterials Group
We can say that with a high probability no natural material can have those properties. As we know that all the same elements exist in the universe as on our planet earth, no mineral of pure metal is expected to have properties of Vibranium. Some of the properties of vibranium can be achieved, though not at the same scale, by design of material structure and architecture using advanced nanomaterials. Piezoelectric materials transform mechanical pressure and vibrations into voltage. Charge produced by piezoelectric materials can be stored and used. Kids running around in sneakers that lighten up with every step demonstrate this principle. Light advanced ceramic materials, such as boron carbide and silicon carbide, are used as armor in bullet-proof vests. They protect due to their extreme hardness — they are harder than any metal.
Material architectures capable of absorbing blast energy are being developed and can, potentially, protect a person jumping from a high altitude (but, again, this will be a 20-feet rather than a 20-story jump).
Vincent Crespi
Distinguished Professor of Physics, Materials Science and Engineering, and Chemistry, Penn State
I happen to have a piece of Vibranium in my office: it’s called tungsten carbide. This is a metal which is used to form pressure cells to compress materials to extremely high pressures. Its corner is cut off; if you stack eight of these together into a larger cube there’s an empty space where those corners come together. If you put a sample there and squeeze the cubes together, you can get enormous pressures. When you do that the metal itself is compressed, and it stores up some of that compressive energy, and it can release it later.
Some of the material [of the cube in my office] has come off. It actually exploded while it was sitting on a lab bench later, spontaneously. Somehow the compression to extremely high pressures reorganizes the grain structure within this material and locks in some of that compressive energy as elastic energy that can be released later.
Now, Vibranium is supposed to be 1/3 the density of steel; this stuff is much more dense than steel. This is tungsten carbide. So, [we’ve] gotta do better than that. And it turns out that at Penn State, we’ve recently discovered a new material called diamond nanothreads.
There are thread-like material, parallel threads, one after the other, organized all the way through diamond nanothreads. Each of those individual threads has the structure of diamond. We have carbon atoms bonded together the same way they are in diamond, but in a very thin thread capped off with hydrogen atoms, and many of these threads, parallel to each other, may be one day woven together into a fabric. These bonds are extraordinarily strong, and they should be able to hold an enormous amount of elastic energy. (John Badding collaborated with me on the discovery of diamond nanothreads. His group made them; my group predicted them.)
The trick will be to get them to keep it, and not release it immediately. We don’t’ know how to do that — but if we could somehow build some kind of [ratcheting] mechanism into diamond nanothreads, then maybe we’ll be able to make some proper Vibranium.
William Gleason
Newmont Distinguished Professor, Metallurgical & Materials Engineering, Montana Tech
To make a long story short, the answer is no. Metals are elements. They follow a quantum order (the periodic table of elements) and so no new metals are going to be found, no matter what planet you are on. New elements are still being formed in very controlled, very expensive pieces of equipment, but they are not stable and would not do what vibranium does.
That being said, could a similar material be made? The answer is yes, but. To put it simply, “vibrations” would include both particles (you on a swing) and waves (sound). Absorbing those types of energy is not so much the issue, since virtually everything will do that in some way; rather, the issue is in how fast can such energy be absorbed. Many materials are available that absorb waves, but particles pack an enormous amount of energy that cannot be distributed across a material before some major change occurs. In essence, once too much energy, either from wave or particle, is absorbed, things mostly just melt. Attempts at making Vibranium have been going on since before Vibranium was put into comics. We are getting better at it with body armor, but it might be some time before we get there. One of the major issues is gravity, since that field has distinct effects on everything made within it. The real vibranium will be a composite of metal, polymer and ceramic probably produced off the planet.
Jayakanth Ravichandran
Assistant Professor, Chemical Engineering and Materials Science, USC
No, I highly doubt that Wakanda Vibranium exists beyond the fictional Marvel universe. We have a solid understanding of the occurrence of stable elements and it is well documented in the periodic table. In fact, our understanding of the constituents of the atoms of such elements is also well established, which is the basis for my statement on their stability. Some features of Vibranium are observable in materials (with more than one elements to form alloys or compounds) but not nearly in the same magnitude as seen in Vibranium. There are materials that are used to absorb vibrations typically in the form of sound or heat, but none of them are going to be remotely as good as what Vibranium is made out to be in these comic books and movies. For example, viscoelastic materials (typically soft polymeric materials) are effective in absorbing sound but are not mechanically rigid. Some metals and ceramics can be viscoelastic but there are always trade offs between strength and the ability to absorb the vibrations. Materials used in armor (typically alloys or metallic glasses) have good impact resistance, but they don’t damp vibrations as effectively as the viscoelastic materials.
Chris Pistorius
POSCO Professor, Materials Science and Engineering, Carnegie Mellon University
The energy-absorption property, coupled with strength — there are definitely not too many materials that have both of those. The everyday example would be car design. Those have been very specific materials, mostly steels right now, that can deform relatively readily — but it takes quite a bit of force to deform that part of the car. It absorbs quite a bit of energy.
Metal foam is a similar thing in a bulk material form. As you deform that and collapse the walls of the foam down, that again absorbs a lot of energy — it’s good for sound absorption, which could play in a role in the formation of a Vibranium-like material. These are real materials that have real uses: NASA researchers think that making fan blades (for aircraft engines) out of metal foam (faced with solid metal) would save weight and be stiffer. Afsaneh Rabei of NC State developed a ceramic foam composite material that is really good at absorbing ballistic energy (that is, stopping bullets).
It’s a growing class of material — I don’t think all the applications have been figured out yet. But another interesting part to this is that you can now 3D print something that looks like this, which means you can really control the size and shape of the cavities in the material. So, I think that maybe the meteorite origin is a cover story by the Wakanda, and that they have actually developed advanced metal 3D printing!
Russian scientists develop technology for production of transparent aluminum
Specialists from the National Research Nuclear University MEPhI and multi-institutional collaborators have developed a technology to produce compacts from aluminum oxynitride (ALON). They've published their results in IOP Conference Series: Materials Science and Engineering.
To obtain "transparent aluminum," researchers at the Institute of nuclear physics and engineering (INPhE) MEPhI applied the method of spark-plasma sintering. This is a new sintering process based on the modified method of hot pressing. In this case, electric current is passed directly through the mold and pressing billet, but not through an external heater. Very rapid heating is achieved by pulsed current for an extremely short work-cycle time.
"Among all present ceramics of medium density, aluminum oxynitride has a significantly high strength, comparable to that of YAG ((yttrium aluminum garnet) and cubic zirconia (stabilized zirconium oxide). Its toughness, which is the most important characteristic for armor protection, surpasses those of all transparent materials including quartz glass, fused quartz, spinel and leucosapphire," explains one of the authors of the publication, postgraduate student of INPhE Nikita Rubinkovskii.
Ooh, Wells made the cage for King Shark out of Promethium Metal.
Cyborg’s original bionic & cybernetic components were made from a Promethium-Titanium-Vanadum alloy, Arsenal once wore a Promethium-backed Kevlar costume, and Deathstroke has used a Promethium sword and staff. Promethium can also be used as a power source, and a mutagenic agent.
Here's Mojo's top ten fictional materials. Can you think of any real-life materials with properties just as impressive as these imagined substances? Superhydrophic materials? Graphene? Self-healing materials? Leave a comment or tweet us @MaterialsWorld and let us know what you think. Alternatively, have a look at our website for lots of exciting materials – just as exciting as these fictional creations – www.iom3.org/materialsworld
