Nebelwerfer41 wrote:

NewtonPulsifer wrote:

If your bonding rate is 100 nanometers per minute

Where did you find this number? Is it stated in the core book somewhere?

No, just taking a conservative number from actual atomic bonding measurements. You can get higher than that (like 6x), but it involves highish defect rates (like 1 in 1000) or where exacting structure isn't desired (amorphous solids).

Nebelwerfer41 wrote:

For the record, I don't have an issue with hand-waving the fact that items can be replicated from feedstock with a nano assembler, what breaks immersion for me is that Anarchists and anti-hypercorp factions should have distributed the these "locked/verboten" blueprints the mesh long ago.

Re:blueprints - yeah, its actually worse than that. There's a financial interest in even *regular* hypercorps releasing blueprints as open-source if they are only using the blueprints internally (not as an end product they sell). They then benefit from the "free" updates and improvements from other users of the blueprints (which may even just be other hypercorps). But part of the reason blueprints are a big deal in EP is because you can buy a desktop cornucopia machine or protean swarm and a blueprint and basically print unlimited money with no serious cost with rules as written. If you actually analyze it, a desktop cornucopia machine isn't feasible except to generate feedstock for fabbers (at a very slow rate at that) - and that feedstock is the vast majority of the cost of any complex item.

Nebelwerfer41 wrote:

NewtonPulsifer wrote:

If your bonding rate is 100 nanometers per minute

Where did you find this number? Is it stated in the core book somewhere? For the record, I don't have an issue with hand-waving the fact that items can be replicated from feedstock with a nano assembler, what breaks immersion for me is that Anarchists and anti-hypercorp factions should have distributed the these "locked/verboten" blueprints the mesh long ago.

From my perspective hand-waving the arbitrary bonding of feedstock cubes/chunks/polyhedrons together "somehow" puts nano-fabrication solidly into the realm of "soft" sci-fi not "hard" sci-fi" for rapid versions of it (hence the original title of the thread).

Madwand wrote:

I'm sure there will be significant engineering challenges that Eclipse Phase unrealistically glosses over for the sake of exploring the consequences of a transhuman setting more fully (and the fact that no one really knows). However, reasonable people can disagree on the real difficulty of atomic manufacturing. Take a look at this essay with much more optimistic projections: http://e-drexler.com/p/04/04/0507molManConvergent.html Eclipse Phase (reasonably, perhaps?) stands between the two extremes of time required given in the above essay and the OP.

That's a design for building architectural things (all of which would be slotted/bolted/screwed together). Besides which using a nanofabricator to build macrostructures being totally unecessary, inferior, and more expensive etc. EDIT: macrostructures meaning things like bridges, walls, doors etc. Say I want something very basic like a 1mm thick bundle of carbon nanotube electrical wiring. How is this nanofabricator going to create that? Here you can take a look at the input of actual experimental researchers who are more skeptical of easily overcoming big challenges to make things fast debating a nanofabrication apologist: http://www.softmachines.org/PDFs/PhoenixMoriartyI.pdf Here's an interview with Professor Moriarty on his progress in mechanosynthesis: http://nextbigfuture.com/2011/03/philip-moriarty-discusses.html EDIT 2:To further elucidate the progress, mechanosynthesis has not been successful yet with diamond, and very limited success has been had with silicon (liquid nitrogen temperatures for the silicon, hot tip). The diamond facing they are using has a lattice distance that is very small (0.154nm -as opposed to silicon - which is slightly more than 50%longer). It's not surprising silicon has been much much easier.

nick012000 wrote:

NewtonPulsifer wrote:

Nebelwerfer41 wrote:

NewtonPulsifer wrote:

If your bonding rate is 100 nanometers per minute

Where did you find this number? Is it stated in the core book somewhere?

No, just taking a conservative number from actual atomic bonding measurements. You can get higher than that (like 6x), but it involves highish defect rates (like 1 in 1000) or where exacting structure isn't desired (amorphous solids).

That's for modern technology, with a single probe that rearranges the atoms, right?

Actually that's from a modern understanding of physics, so its a more fundamental limit.

nick012000 wrote:

Eclipse Phase nanoassemblers don't work like that. There are no probes; there's a stupid number (thousands? millions?) of nanobots, each of which works simultaneously. You don't print line by line, you build the entire surface at the same time.

My calculation is assuming a bunch of 33x33 atom tools all packed side by side. It doesn't really matter if the tool is attached to a nanobot or not. Please imagine what you're describing - a bunch of nanoscale tools operating on the whole atomic surface at once? Wouldn't that imply that each tool+worker is 1 atom thick? My picking of 33 atoms wide is actually smaller than any optimistic proponent thinks each tool can get, and me using the maximum bonding rate is also much faster than even they think is possible.

Madwand wrote:

Ultimately, I don't think this forum is the right place to be trying to convince people of the arguments against fast molecular manufacturing. You might be right, and it's impractical. You might be wrong. Very few people here have the expertise to argue one way or another, and most just want to enjoy playing a game. The right way of arguing these topics is a scholarly paper. Gather a few knowledgeable co-authors and explain your arguments. Publish them in a reputable, peer-reviewed conference or journal paper. Give experts (not us!) a chance to rebut your arguments. I would personally very much like to read such a paper, particularly a good rebuttal of the paper I cited. This is all fascinating stuff.

That's kind of the reverse of the normal process, though, right? Normally someone will publish a paper in a reputable peer reviewed journal, [i]then[/i] people will take shots at it. I'd be analyzing fringe work that has never been published in any such journal. The onus is really on them to get published first by passing basic peer review, right? If you simply want to appeal to the authority of already existing experts, the consensus so far is "yeah....not gonna work" (The Royal Society, Gordon E. Moore of "Moore's Law" fame etc.)

Madwand wrote:

I'm sure there will be significant engineering challenges that Eclipse Phase unrealistically glosses over for the sake of exploring the consequences of a transhuman setting more fully (and the fact that no one really knows). However, reasonable people can disagree on the real difficulty of atomic manufacturing. Take a look at this essay with much more optimistic projections: http://e-drexler.com/p/04/04/0507molManConvergent.html Eclipse Phase (reasonably, perhaps?) stands between the two extremes of time required given in the above essay and the OP.

Okay I'll stick with high school level stuff for now. This is simply a critique of the convergent assembly thrown out there - this doesn't address at all the difficulty of arbitrarily bonding diamond cubes together. That link you referenced has a conclusion of "Concerns that molecular manufacturing will be impractically slow seem misplaced." It references this link to support its conclusions: http://e-drexler.com/p/04/04/0505prodScaling.html ...but overlooks power requirement scaling. force=mass*acceleration, and power needs scale linearly with force So lets calculate the force needed for an arm to sweep a 1 meter distance twice in one second. Well, we need to sweep a total of 2 meters in 1 second - so our average velocity needs to be 2m/sec. Assuming steady acceleration and same time to accelerate and decelerate, we need to reach a peak velocity of 4m/sec twice (4m/sec final, minus 0m/sec starting, divided by two to get average velocity of 2m/sec). Here's a slightly harder question - what's the acceleration? Well, we need to reach peak velocity twice (two sweeps) and if you assume you slow down as fast as you accelerate, then we need to reach peak velocity (4 m/sec)in period of 0.25 seconds (twice at 0.25 and 0.75 seconds in) in the middle of one of our two sweeps. So acceleration is 16m/sec (4m/sec divided by 0.25 seconds). 16m/sec times mass of 100kg gives us 1600 newtons of force. What if we shrink the arm down by 0.5 scale and then double the frequency (and thus average velocity). Well, we sweep a total of 1 meter in 0.5 seconds. Average velocity is 2m/sec. Peak velocity? 4m/sec. Acceleration - we need to reach peak velocity (4m/sec) in a period of 0.125 seconds. So acceleration is 32m/sec. Mass is constant at 100kg so we have 3200 newtons of force. Uh oh. We doubled our force - that means we doubled our power needs. We need to keep it constant. Okay, so what does the frequency need to be to keep force constant for the 0.5 scale arm? Well, it turns out you just keep the frequency at 1 no matter what the reduction in scale and force/power stays constant. So what does this mean for throughput? Well, it also stays constant. Well, you say, 1kg/sec is pretty awesome for a less than 2 cubic meter setup! There's still a big problem. The 1 cubic meter long section is being fed by four 0.5 cubic meter sections (not eight). That's half the volume and mass, thus half the throughput. This problem continues down stage by stage until after 20 stages you're at approximately [i]1 millionth of the throughput[/i] - the smallest stage is the bottleneck. So with that convergent assembly design in 20 stages a kilogram item will take a 1,048,576 seconds (12 days). EDIT: 20 steps gets us starting with around 63nm cubes from a 66mm final cube. If you wish to take the steps all the way out to say a 1nm molecule that's 6 more steps (and 64 times the time - up to 768 days).