The more you tighten your grip, Tarkin, the more star systems will slip through your fingers.

I dunno, it seems to have worked pretty well for Putin. I mean, wake me up when Obama starts going around assassinating dissenters with polonium and forcing all popular blogs to register with national media censors.

I of course think that the US has stepped way out of bounds with a lot of stuff it's done. But I do find there's this rather curious American Exceptionalism often in play where only the US is deemed capable of moral or relevant behavior, and it's just taken as both a given and irrelevant that others take it to far worse extremes.

As a whistle blower myself, I found that the trick is to do diaphragm exercises. Lots of people focus too much on the muscles in the mouth, but the real airflow comes from the lungs. Also, get yourself a real competition-grade whistle, not a cheap piece of Chinese-made junk. I personally am fond of the late Soviet militiary whistles - not only do they have a distinctive sound, but the titanium pea is extremely efficient at transforming air pressure to sound with little resistance.

Well...

egrep ".*ism$" /usr/share/dict/words | perl -MList::Util=shuffle -e 'print shuffle();' | tail -n 10 ... tells me that the next ten things that the US is going to wage war against are:

Factionalism
Occidentalism
Aerotropism
Briticism
Rebaptism
Establishmentarianism.
Freemasonism
Achronism
Henotheism
Selenotropism

I look forward to the War on Henotheism. Make up your minds, there's either one god or there's multiple! If you don't pick between the existence of one god or multiple, then the Henotheists win!

(Side note: Slashdot, stop playing content critic with your "Filter error: That's an awful long string of letters there")

It's not so much the alternatives becoming cheaper than the extraction of fossil fuels becoming more and more expensive. We extract gold with much more cost per kilogram than coal -- but only because selling the gold will give about $1200 per ounce.

Whether some geological formation is called a deposit for some mineral is depending not only on the characteristics of the local geology, it is at first a question of economics: Does it make sense to extract the mineral here, or will it be cheaper to buy somewhere else and get it shipped? When we are talking about the exhaustion of deposits, we always have to keep the qualifier in mind "under current technological and economical conditions".

Actually, GMO uses a completely natural process, that's called "retro viral infection", and it's often deadly (HIV for instance is a retro virus). In GMO it's called "DNA shuttle". A retro virus puts its own DNA into the host's DNA causing the host to produce copies of the retro virus. For GMO, the retro virus first gets some additional DNA (mostly from a completely unrelated species) to produce the desired proteins, which it then carries into the host and which (hopefully) will integrate into the host's DNA, thus the name DNA shuttle. If the GMO designer is lucky, the host will battle the retro viral DNA and keep the additional DNA.

It has nothing to do with evolution, though the human DNA shows the remainings of several retro virus infections that were kept in the genome, but seems mostly unfunctional right now.

Actually, 33% of renewable energy in Germany comes from wind, about 25% from biomass, 20% from photovoltaic and 15% from hydro. So biomass and hydro. while still large, don't have the biggest share.

There are additional effects: Radiation is not as bad for animals living all the time there. A local wolfpack seems to do just fine. It is rather bad for animals being there only occasionally, like migratory birds. Those animals show much higher level of gene defects. It seems that at least vertebratae can adapt to the higher levels of radiation if they live there all the time. But it's not so easy for those moving in and out all the time.

Local lakes (Tchernobyl borders to a very extensive swamp region, the Pinsk marshes) show very high levels of gene defects in newts and frogs -- not because they got too much radiation, but because migratory predators are missing that normally would eliminate those specimen.

Really, shipping bulk raw materials is equivalent to shipping finished goods, in your world? Finished goods are usually predominantly waste space, are full of packaging, have to be handled gingerly, and need to be distributed to individuals in different locations. Raw materials are packed together as densely as possible, little to no packaging, can be thrown around, and go straight to just a couple manufacturers. And when import taxes come into play, it's even more extreme, since those are generally based on the price of what you're importing.

You know, I was just thinking, wouldn't it be possible to make a rapid 3d *moulder*, for those bulk parts that you don't require as much precision on (aka, chair)? Picture a stretchable half-mould surface, on a large bed (maybe 50x100cm for a home edition, larger for a workshop) with a grid of little pistons on it that can change it's shape (nothing too high res, maybe one every square centimeter). Picture a second half-mould positioned just opposite, such that the two elements can close off off a 3d space. Such a system could virtually instantly form whatever shape you want, spray the inside with release agent, pipe in a thermoplastic or thermoset resin or wax (for lost wax casting) or confectionary or whatnot, let it set / cure it, and then open up. The pistons could then reshape to ready for whatever shape you want next. If such a moulder would you mess with the two halves individually after they've formed their shapes, you could use it as a composite layup, too. Disposable liners for the mould could be used if sticking / damaging the adjustable mould surface would be a problem.

Wouldn't that be getting awfully close to the potential that mass manufacture currently has? Casting as many times as you want and only having to wait for the product to set? Sure, you'd be limited to relatively simple geometries, but if you need anything more complex, that's what regular 3d printing is for. Hollow shapes could be handled in a two-stage process, first printing out the inner, releasing it, securing it in place, respraying both it and the mould with release agent, then printing out the desired part. I'd think a well-designed moulder could handle that without human intervention.

Hmm, come to think of it, it might even be possible to make a direct metal casting moulder. I know there are high temperature flexible fabrics that can withstand the temperature of most molten metals (various ceramic fiber ones), although I'm not sure whether there are any with sufficient flex for such a role. Oh, hey, carbon fiber and graphite felt are used as a flexible insulating material , that'd probably do the trick.

Come to think of it, this has to be a godsend for Hollywood. They've got the budgets, and you can use the same model for both CG special effects and printing for camera work (whether we're talking about printing for miniatures, animatronics, prosthetics, molds for prosthetics, gadgets or other small objects, etc). No need to have both your 3d artist and a physical artist create the same thing.

For this to be more than just a gimmick, UPS needs to offer a 3D scanning service as well.

Which is why I really hope to see Project Tango in the future connect direct with 3d printing.

Scan your scene with your phone, click to print, pick the article in question out of the scene (with simple cutting tools and smart select), assign a material to it (with the app doing its best to choose defaults), possibly apply some filters (welding broken pieces together, for example) or stretch it a bit in different directions to meet your needs if you choose, pick your printing service, pick any other details such as surface treatments and the like, and it gets uploaded, you get billed, and your print arrives in the mail when it's ready.

iMaterialize has a material called "Rubber-like", which is a plastic called TPU 92A-1.

While I agree with you, I think it's important not to overgeneralize today's methods of 3d printing with being the only methods possible.

  For example, I've often speculated a lot about the prospect of using thermal spraying as a printing method. That is, you have any sort of powder or other fine material, fed into a chamber with the Venturi effect. Therein a custom mix of air and fuel is injected at specifically chosen partial pressures. Consequently, depending on what material you're using, you can choose the impact speed and temperature of the particles, anywhere from "cold" to thousands of degrees and anywhere from less than 1 meter per second up to a thousand or more. The size of the nozzle determines flow rate, so you could swap between different print heads for bulk vs. fine detail. You're essentially unlimited in what materials you can use. You could, for example, print isotropic fiberglass composites by alternately spraying fine chopped fibers and a resin. You could even do so by spraying simple quartz sand at high enough temperatures, fast moving molten sand in the air forms fiberglass. Your resin could be a thermoset powder heated during travel, an epoxy that reacts after being mixed on impact, or a wide variety of other possibilities. High velocity spraying of metal powders produces metal structures stronger than simple casting. You could spray at low velocity chemicals for the filling of things like capacitors or resistors. Thermal spraying is often as it stands used to apply durable clear coatings to materials to protect them, so clearly transparency is no problem. And any printer built around the principle of launching varied small particles at high speeds could polish, sandblast, coat, engrave, paint, or do whatever other surface treatments you wanted. It could build scaffoldings and then obliterate them afterwards. And on and on down the line.

It still wouldn't let you do fine detail, though (if anything you'd struggle to get as high detail as with conventional 3d printers). For detail work you'd have to add in a lithography setup. Some types of feed inputs would require refrigeration to remain as dusts. And of course some things would still be easiest assembled with literal assembly, aka, a robotic arm or two would be quite useful. So we're getting more and more complicated here.

Do I think such a thing is right around the corner? Of course not. Could my conception turn out to not work well at all as a 3d printer? Quite possibly - as far as I know, nobody's ever tried. But I'm just pointing out, when talking about future tech, you shouldn't evaluate it based on how today's tech works.

Problem will be printing small things, atomic scale assembly, not just squirting some plastic parts

And yet you want to 3d print a fuel cell for a car? How do you plan to 3d print a PEM?

At least 3d printing a battery might be plausible if you have a 3d printer that can take an extremely wide range of materials (not a li-ion battery, though, you run into the same sort of membrane problems.. I really doubt there's any technology that will allow you to just jet down a membrane material and have it allow through your specific desired ions, at a sufficient flow rate, without leaks)

And where on earth are you getting that printed titanium parts are cheaper than non-printed? Have you ever priced titanium printing? iMaterialise, for example, offers it. A 2x2x4 cm bounding box with a mere 1 gram of titanium (picture how little that is that is compared to a plane) costs a staggering $124. Titanium laser sintering printers are slow energy hogs that cost a king's ransom and even titanium powder itself is absurdly priced compared to bulk titanium. And no, the stats aren't better, they're slightly worse for the exact same shaped part. Maybe you can make a more optimally shaped part and that'll allow you to get better performance, but in terms of raw material properties, it's unimpressive.

The question becomes, how to get manufacturer buy in?

For starters, I think we need a certification mark for products, at the very least, to indicate that their parts are 3d printable (see above). But beyond that, I'm not really sure how to get manufacturer buy-in.