Difference between revisions of "Common misconceptions about atomically precise manufacturing"

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APM is a very novel area of research and development that dives into fields of knowledge that are yet pretty alien for most people including many "nanotechnology" experts.
 
APM is a very novel area of research and development that dives into fields of knowledge that are yet pretty alien for most people including many "nanotechnology" experts.
 
When encountering a new network of knowledge one usually tries to apply existing knowledge to judge statements and claims - what else can one do.
 
When encountering a new network of knowledge one usually tries to apply existing knowledge to judge statements and claims - what else can one do.
Without deeper understanding of the relationships this can lead people into trapdoors. Some are so bad that almost everyone falls in. This page is guide around those trapdoors.
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Without deeper understanding of the relationships this can lead people into trapdoors. Some are so bad that almost everyone falls in. This page is intended to be a guide around those trapdoors.
 +
 
 +
There is another related page that focuses on more concrete details around scaling laws here: <br>
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'''[[Common critique towards diamondoid atomically precise manufacturing and technology]]'''
 +
 
 +
= No nanobots here =
 +
 
 +
See main page: [[No nanobots]]
 +
 
 +
When thinking about manufacturing things from the bottom up almost atom by atom often <br>
 +
the first association that often comes up are "nanobots" in the sense of <br>
 +
"littly tiny critters" that can do highly compact [[self replication]].
 +
 
 +
A [[Nanosystems|more technical analysis]] though revealed that this concept is not the right <br>
 +
approach. (At least when it comes to most manufacturing systems.)
 +
 
 +
This (mis)association of APM with "nanobots" and
 +
the intense historic discussion may be due to: <br>
 +
(1) Nanobots being a self suggesting first idea.<br>
 +
(2) Nanobots being a an idea that tends to rile up emotions
 +
because they coming with a number of wild secondary (mis)associations like:
 +
* them being [[almost life like]] – The "How dare you try to play god argument".
 +
* them being capable to evolve like bacteria cells
 +
* them being able to "eat" just about anything
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* them getting [[grey goo horror fable|totally out of control]] – The "How dare you even think about something so dangerous argument"
 +
And that's totally missing that [[molecular assembler|self replicatibe nanobots are not even the target anymore]].
 +
 
 +
= Macroscale style machinery at the nanoscale ?! =
 +
 
 +
Or: Macro-scale style machinery isn't suitable for the quantum world one needs something more exotic instead - wrong
 +
 
 +
Topic of discussion: <br>
 +
What is under scrutiny here is what is crudely outlined in this animation video: <br>
 +
[[Productive Nanosystems From molecules to superproducts]]. <br>
 +
What is shown is a quite accurate visualization of the results of [[exploratory engineering]] that was done in the work that is [[Nanosystems]].
 +
 
 +
There are quite a number of points of critique here. <br>
 +
They are listed and discussed on the page: '''[[Macroscale style machinery at the nanoscale]]''' <br>
 +
The gist is: It is rather clear where the points of critique come from. That is: There are good reason for all these doubts given the current (2021…2024) state of technology. But all of the most fundamental critique points have been analyzed and came to a favorabel conclusion for the concept to work.
 +
In the end it turns out that [[scaling law|the chaining of physics with size scales]] makes [[macroscale style machinery at the nanoscale]] actually work better rather than worse than "macroscale style machinery at the macroscale". Contrary to the expectation of some "current day nanotechnology" experts. <br>
 +
<small>(Side-note: If you are wondering about [[nanoscale style machinery at the macroscale]] now: This is hardly possible.)</small>
 +
 
 +
Related: [[Applicability of macro 3D printing for nanomachine prototyping]]
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 +
== Diamondoind nanomachines would be soft like jelly and thus infeasible - false and false ==
 +
 
 +
This widespread and persistent common misconception is an artifact of a limitation of simulation capabilities <br>
 +
A limitation that leads to systems being simulated at speeds hundred thousand times faster than proposed speeds (100m/s rather than 1mm/s). <br>
 +
Details to that limitation and more can be found on the page: <br>
 +
[[Misleading aspects in animations of diamondoid molecular machine elements]] <br>
 +
 
 +
As a macroscale analogon: <br>
 +
Spring steel does also acts like jelly if parts are shot at each other almost at bullet speeds and observed with a slow motion camera. <br>
 +
That's essentially what one sees in almost all the atomistic simulations. <br>
 +
Difference is that isolated single nano-mechanisms (not bulk volumes of them !!) do not self destruct when steady state operated at these speeds.
 +
Macroscale machines could not get rid of the enormous waste heat fast enough. <br>
 +
Not that one would usually want to run nano-machines at these extreme speeds as it's very inefficient. And one obviously has to design around the wobble then.<br>
 +
At proposed speeds of a few mm/s there would be no perceptible motion driven flex visible in the simulations. <br>
 +
Beside the low speed diamond is way stiffer than even steel. <br>
 +
 
 +
How much things bend actually does not change across scales. <br>
 +
That is: It is scale invariant in the "[[same absolute speed across scales]]" approximation. <br>
 +
And even better it goes down on a closer analysis. <br>
 +
For an explanations of details see page: [[Same relative deflections across scales]]. <br>
 +
Atop the misleading simulations: <br>
 +
The scaling law of [[lower stiffness of smaller machinery]] has the potential to fool even experts into this misconception. <br>
 +
Details on the linked page.
 +
 
 +
= Potential concerns about mechanosynthesis =
 +
 
 +
== Atoms can't be placed individually because of "fat and sticky fingers" - sticky is actually good fat is just untrue for the tips ==
 +
 
 +
Disproved by basic experimental and detailed theoretical work. See: [[Mechanosynthesis]]. <br>
 +
It may get a bit more challenging when the [[mechanosynthesis of chain molecules|mechanosynthesis of ''complex'' chain molecules]] is attempted. <br>
 +
Which is not a requirement for [[nanofactory|gem-gum-factories]].
 +
 
 +
See main articles: "[[Fat finger problem]]" and "[[Sticky finger problem]]" <br>
 +
Or more generally see: "[[The finger problems]]". <br>
 +
There are two more finger problems beside the two infamous ones.
 +
 
 +
== Once placed atoms won't stay there because of "thermodynamics" - mostly false - solvable problem ==
 +
 
 +
In other words: Thermodynamics prevents one from having every atom at the place we want it - wrong for practical scales <br>
 +
 
 +
Picking the right materials to synthesize the placed atoms will very much stay where they are put. <br>
 +
Except hit by hard radiation. Radiation can be dealt with by:
 +
* damage redundant design – (See: [[Redundancy]])
 +
* damage resilient design – (Avoidance of [[semi diamondoid structure]]s)
 +
* optionally by actively [[self repairing systems]]
 +
 
 +
More details:
 +
* See: [[Thermal decay at room temperature]] – See: "[[Thermodynamics]]"
 +
* See: [[Radiation damage]]
 +
 
 +
== Atoms can't be placed fast enough - false ==
 +
 
 +
To make macroscopic products in a reasonable time-span by
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putting them together atom by atom would require
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atom placement frequencies too high to reach.
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 +
This is not true. Quite moderate atom placement frequencies in the MHz range suffice when combined <br>
 +
with massive spacial parallelism that is hard but realistically to reach. <br>
 +
See: "[[Atom placement frequency]]" for details.
 +
 
 +
== Control data can't be supplied fast enough - false ==
 +
 
 +
We already do similar things with our current technology.
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See: [[Data IO bottleneck]]
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 +
If the goal would be to make an exact copy of some chunk of naturally occuring matter with every atom at the <br>
 +
same place the amount of data would indeed could not be handled because the data can't be efficiently compressed. <br>
 +
But that is not the goal. Even in the actual case of [[synthesis of food]] this is not the goal.
 +
 
 +
For organic matter the nature of data de-compression from DNA to tissue is vastly different to <br>
 +
the data-compression in [[gem-gum factories]] from code to [[gem-gum]] product. <br>
 +
See: [[Decompression chain]]
  
 
= It's called "nanotechnology" - not anymore =
 
= It's called "nanotechnology" - not anymore =
  
The term "nanotechnology" is only referring to a size range and nothing more thus it can encompass a very wide range of technologies.
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Due to the terms extreme generality it caused confusion and conflict. <br>
The corresponding word "macrotechnology" is not in wide usage exactly because referring to size alone can be much to general and unspecific to be of use. In contrast to the term "macrotechnology" the term "nanotechnology" though historically lead to problematic political tensions.
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Hardening misconceptions causing unjustified discreditation going as far as <br>
 +
fear of career loss based self censorship and consequently a severe setback in development.
  
With the growing number of very different technologies (and [[grey goo horror fable|myths]]) gathering under the umbrella of "nanotechnology" grossly incorrect cross-associations between these technologies started to emerge in media and public perception.
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For details see main article: "[[The term nanotechnology]]" (and page: [[History]] & [[The negative effects that public overexcitement can have]]).
This caused problems. The discontent at the mainstream side grew so high that "nanotechnology" at some point was actively redefined such that controlled manipulation single atoms (core of [[Main Page|APM]]) where actively excluded from "nanotechnology" (atoms are a bit smaller than a nanometer).
+
  
To make misassociations of the new "conventional nanotechnology" with the technology this wiki covers less likely the new term '''atomically precise manufacturing (APM)''' was introduced to replace older terms that carry the term "nanotechnology" in their name. Such as the term "molecular nanotechnology".
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'''When referring to APM related ideas it's seems best to …'''
 +
* refrain from using the term "nanotechnology" as much as possible and
 +
* refrain from using the nano- prefix in general.
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* more generally refrain from using bio-analogies. <br>See page: [[Misleading biological analogies that should be avoided]]
  
There are huge differences between APM and the new narrowed down APM excluding "nanotechnology". Here's just one:
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== Suggestions for descriptive unannexable names for the technology ==
A big part of work in "nanotechnology" is done on researching interesting things that are on the verge of falling apart.
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'''Atomically precise manufacturing (APM)''' is mostly focused on the most stable structures which is pretty much the opposite.
+
  
----
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Be more specific as far as this is possible. <br>
 +
'''Here are suggestions for terms that are more specific:'''
 +
* "gemstone metamaterial technology" or "gem-gum-tec" for short
 +
* "gem(stone) based APM" or "gem based advanced APM"
  
Some sub-concepts of APM (e.g. [[nanobot]]s) are not exactly wrongly associated with APM but are still overproportionally over-represented in current mainstream media partly because they carry the "nano-" prefix. (See: [[The usual suspects]])
+
'''Note that …'''
 +
* just "advanced APM" is vague, it fails to specify that advancedness shall refer to being based on gemstones so only use this if that's the intention.
 +
* just APM (atomically precise manufacturing) does not explicitly exclude very early systems like <br>[[structural DNA nanotechnology]], [[foldamer]] technologies, [[spiroligomers]], …
 +
* just "advanced nanotechnology" is asking for conflict as there are folks that <br>see [[soft machines]] or more narrowly [[synthetic biology]] filling that role entirely.
  
= The unexceedable biomimetism misconceptions =
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== "Gem based APM" is not "The Real Nanotechnology"™ ==
  
== Results of evolution shows what is not possible. Wrong. ==
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'''As a weak analogy:''' <br>
 +
Fighting for "nanotechnology" to mean "gem based APM"/"gem-gum-tec" exclusively is like <br>
 +
fighting for "macrotechnology" to mean metallurgy and metal machining exclusively.  
  
* A common thought: "If APM where possible nature/evolution would have done it. Wrong.
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* It's misdirected effort as the analogy should make obvious.
 +
* It's a fight against windmills. A pointless waste of effort.
  
Technology already has shown countless of times that it can go where [[evolution]] couldn't.
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Evolution of terminology is an indominable force of nature as a whole society is involved. <br>
{{todo|add link to examples page}}
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When gem based APM becomes the dominant type of nanotechnology eventually, <br>
Probably the most obvious difference is that in the far term goal of advanced nanofactories it is better to [[suppression of thermal motion|suppress]] [[brownian motion]] for the most part rather than to use it in the way nature does.
+
then the term nanotechnology might change it's meaning to align with gem-gum-tec all by itself (reversing the by some perceived problem). <br>
 +
But for now for the sake of productive discussions about near term APM and far term APM <br>
 +
we should seriously try to avoid using the term "nanotechnology" to refer to "gem-gum-tec". <br>
 +
Please 🙏.
  
== How to learn from nature ==
+
= Nature does it differently thus gem based APM must be flawed. – Faulty reasoning. =
  
* A common thought: "We must learn from nature. Thus advanced productive nanosystems must look similar to molecular biology." '''Too superficial!'''
+
See main article: "[[Nature does it differently]]".
  
To give a crude analogy this is similar to saying:<br>
+
= It will be insurmountably difficult to develop gem based APM – Wrong =
"We must learn from nature thus planes must look like birds."
+
  
Yes, we need to learn from nature. In the end everything we ever have known and will know originally came from nature in some way or another.
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'''No, not insurmountable. Yes, it will be a very difficult journey.''' <br>
But the things we need to learn from nature sometimes do not lie on her surface.
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It's just a humongous, possibly multi-generational, challenge with many people and work-hours months and years involved. <br>
These things often lie much deeper (fundamental physical principles).  
+
It may happen within one single average human lifespan (as of 2021…2024), but anyone who says that this is a fact is wildly guessing. <br>
Especially for far term goals it turns out that following natures examples superficially is not sensible. For the far term goal of gem-gum nanofactories lots of natures examples need to be shunned. So much in fact that one ends up at systems that are '''very''' different from natural ones. Even natures example of thermal diffusion transport turns out to be too superficial.
+
There is not "the one exponential trend" like e.g Moores law that can be projected into the future. <br>
 +
At least not yet.
  
* Common thought: "But look what you do is actually biomimetism." (Referring to the work currently being done. The first steps of the [[incremental path]].)
+
There are some common incorrect assumptions about what <br>
 +
are unconditionally necessary technological prerequisite skills.
  
Yes. If we where already at the goal we wouldn't need to get there.
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'''Three misconceptions:''' <br>
The fact that biomimetism is a good starting point does not mean that it is a good far term goal.
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* This technology would need to be as advanced as life.
It's just an easier starting point than the [[direct path]] for now.
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* We have no hope of ever recreating a level of technological skill that comes anywhere close to life.
 +
* We should not even dare to attempt recreation of something as advanced as life.
 +
'''No, no, and false premise respectively.'''
 +
* No, the technology is ''very'' different to living systems and most likely much less complex. (See dedicated section below)
 +
* No, there is [[Synthetic biology|other (APM unrelated) technological development]] that aims at recreation of primitive life like systems and it might have chance at succeeding.
 +
* Aside the false premise: <br>Don't we have the obligation (and privilege) to research the world given to us in a responsible way. <br>Won't the lack of hopes, dreams, and curiosity will certainly lead to bad things?
  
Recent developments in structural DNA nanotechnology though show clear signs of veering away into the direction of nano-robotic cogs and gears. A direction that has received and still receives harsh criticism.
+
'''Misconception:''' <br>
 +
Handling the complexity of large scale full on quantum mechanical systems will be an unconditionally necessary technological skill. <br>
 +
<small>Full on quantum mechanically meaning aptly handling highly quantum-dispersed and entangled-systems.</small><br>
 +
No, This is not a prerequisite for advanced APM. See: "[[It's not quantum mechanical]]" <br>
 +
It would be a prerequisite if building quantum computers would be a direct target of APM, but that is not a target. <br>
 +
Advanced skills in quantum system handling will rather be a natural byproduct of developments in the field of APM.
  
Also developments in the [[direct path]] while not showing great progress (as of 2017) do clearly show the feasibility of siliconoid [[mechanosynthesis]] (which is not very different from diamondoid mechanosynthesis where complementary theoretical analysis has been performed.)
+
'''Misconception:''' <br>
 +
Super advanced AI/AGI systems will be critically necessary to build even minimal viable [[advanced productive nanosystem]]s. <br>
 +
No, We managed to build incredibly intricate computer-chips without advanced AI. <br>
 +
Though it certainly will be of help for optimizing routing of electrical and other [[subsystems]] and such. <br>
 +
And AI tools will become increasingly available. Same with quantum computing.
  
== One must use thermal motion to transport nano-stuff. Wrong. ==
+
'''Misconception:''' <br>
 +
The (very difficult) [[direct path]] is a the only viable path.<br>
 +
No, there is also the [[incremental path]] (using soft nanotech to get to stiff nanotech ASAP) <br>
 +
A path that can augment the direct path or rather take on the bulk of the development process.
  
* Common thought: "Since molecular biology uses diffusion transport to do work factory style transport does not work at the nanoscale." Wrong.
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'''Misconception:''' <br>
 +
The (very difficult) [[direct path]] is pointless and (because too difficult) <br>
 +
will contribute absolutely nothing to progress towards [[gem based APM]].
  
There simply was/is no continuous path of small incremental steps towards this kind of technology that molecular biology could have followed. It takes humans to do this.
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== We would need god like skills to create life-like nanotechnology ==
See: [[Diffusion transport]]
+
  
== There are no cogs and gears in cells so artificial systems cant have them either. ==
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'''No, Development of [[APM]] does not aim at recreating some form of artificial life.''' <br>
 +
Aiming at doing that is part of a sub-field of [[synthetic biology]]. <br>
 +
Synthetic biology is a different field of technological development. <br>
 +
Synthetic biology is not aiming at atomically precision over over larger size scales and thus <br>
 +
it does not fall into the field of [[APM]] as it is defined in this wiki. Not even [[incremental path]]. <br>
 +
People working in the field of synthetic biology may well have a chance at creating primitive life like systems. <br>
 +
So even if R&D in the field of APM would aim at recreating primitive life-like systems (which it does not) <br>
 +
the situation would still not be absolutely hopeless.
  
* Common thought "Makro scale style machinery is not suitable for nano scale devices at all." Wrong.
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Complex systems can gain surprising and charismatic behavior similar to life. Looking at computers and AI/AGI here. <br>
 +
So eventually products made by [[gem-gum on chip factories]] may behave and feel life like. <br>
 +
But that is way beyond basic [[advanced productive nanosystem]]s. <br>
 +
That would be about the [[Most speculative potential applications|most advanced products]] of them.
 +
<small>(Related: [[Multi limbed sensory equipped shells]])</small>
  
Simply wrong. - See: [http://www.molecularassembler.com/KSRM/6.3.7.htm] <br>
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Associations of R&D in the field of APM with the idea of recreating life-likely systems comes <br>
For an other explanation see further below.
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likely mostly from the self-suggesting analogy to microorganisms like bacteria that <br>
 +
was brought forward in the (now outdated) [[molecular assembler]] concept (initially presented in [[Engines of Creation]]). <br>
 +
While molecular assemblers would not need to be anywhere near as complex as living cells (e.g. no need for evolving skills) <br>
 +
they would need to be much more complicated (and slow/inefficient) than systems that do not feature such ultra-compact self-replicative capabilities.
  
= Nanobots - in most cases a very flawed image =
+
The idea of [[molecular assembler]]s (the idea not the devices themselves) was (and sadly still is) so successful <br>
 +
compared to the [[gemstone metamaterial on chip factory|actual target]] likely because:
 +
* its self suggestiveness - people can hinge on something that they (believe) to understand - (thereby being misled in judgements)
 +
* it being the only option if the original from of the [[direct path]] via [[molecular assembler]]s is the only path under consideration. <br>Ignoring the [[incremental path]], [[mixed path]] and newer variants of the [[direct path]] that avoid [[molecular assembler]]s or their chip mounted equivalent.
  
Associated traits that have nothing to do with advanced productive APM systems:
+
'''Early [[advanced productive nanosystem]]s will likely be more like computer chips rather than living cells.''' <br>
* swarms
+
While living cells store their building plan in a few gigabytes (which is well in reach of current 2021 computer technology) <br>
* living & evolving
+
an incredible aspect of life is the degree of smartness in data-compression. <br>
* insatiable, metabolize just about anything
+
E.g. how a whole human being can be encoded in the little amount of information stored in the DNA (ignoring epigenetics and the microbiome here). <br>
* super dangerous - [[grey goo meme|''the'' accident]] is unavoidable and cataclysmic
+
But again, recreating that is an eventual goal of [[synthetic biology]] not a goal when aiming for minimal viable [[gem-gum factories]].
  
== APM is like swarms of "nanobots" - wrong ==
+
== Actual points of great difficulty in the development of APM that often are overlooked ==
  
The main body of AP systems and products will be bulk materials produced by [[nanofactory|nanofactories]].
+
* The biggest current challenges in relevant targeted development are of conceptual and institutional nature. <br><small>Meta: This very page here is an effort on improving ion the conceptual.</small> understanding.
Loose autonomous units [[molecular assembler|for productive purposes]] or only for applicative purposes
+
* What is not (yet) well know about advanced APM is that <br>there is stuff that actually ''can'' already be known (via the methodology of [[exploratory engineering]]).
(where loose means unconnected & floating in air or water or "crawling" on surfaces applicable e.g. in form of sprays)
+
* Funding of highly targeted relevant work is very difficult. Perhaps the biggest blocker of progress as of 2024.
are unpractical in relation to nanofactories.
+
* Not at all an exhaustive list ...
  
All kinds of loose units out of diamond like materials may pose environmental problems since spill of non-dissolving non-rotting material into the biosphere can have detrimental effects on many organisms for a long period of time.
+
= Advanced APM systems are a "castle in the sky" with no way to built them - not quite =
  
Loose units should thus be used only in limited ways by non rouge actors where there are no other options.
+
It has often be perceived that [[diamondoid molecular elements]] can only be synthesized by stiff tools made that themselves are made from [[diamondoid molecular elements]]. The [[incremental path]] avoids circular dependencies by continuously changing the [[method of assembly]] from self assembly to [[positional assembly|stereotactic control]]. ([[Radical Abundance]] - page 190)
One such case are medical purposes. They are somewhat of an exception.
+
Their bio-compatible products don't resemble the productive units themselves thus they can be made devoid of any self replication capability.
+
  
Pretty advanced APM systems (way beyond basic advanced APM systems) make swarms of loose productive units undeniable possible but they are over- and most often misrepresented in current media.
+
The [[direct path]] tries to use bigger already stiff but not quite atomically precise slabs of material to build stiff atomically precise structures (e.g. in MEMS-AFMs). This is not fundamentally impossible but a much steeper slope judging from the progress rates.
SciFi is regularly painting unrealistic pictures of the [[the grey goo meme|classic dystopia]].
+
  
== Those "nanobots" can "eat" just about anything - wrong ==
+
== Lots of ''relevant'' pathway entry (and exit) points worth starting to take ==
 +
 +
There is by no means a lack of places where invested work would clearly lead to progress that is specifically relevant to APM.
  
Main article: [[atomically precise disassembly]]
+
If one looks at the right places then one can find both:
 +
* Lots of pathway-starts "signed" to lead to the target.
 +
* Lots of pathway-ends "signed" to come from the start.
 +
With this many starts and ends the existence and realistic archievability of at least one path connecting some start to some end is very very likely.
  
It is often thought that the capability of taking things apart atom by atom would become available
+
See pages:
just when one starts to be able to put things together atom by atom.
+
* '''[[Most relevant R&D construction sites for progress in APM]]'''
This is far from true.
+
* [[Castle in the sky]]
Taking things apart atom by atom is a much harder problem in many cases.
+
* <small>(somewhat related: [[House of cards]])</small>
Beside other factors the inability to consume just about anything harshly limits the aforementioned [[the grey goo meme|grey goo scenario]].
+
  
No disassembly.
+
= Using soft/compliant manomachinery to get to hard/stiff nanomachinery ASAP is hypocrisy - false =
  
== Related ==
+
No, it's just a practical approach. <br>
 +
Ones usage of soft nanomachinery for a rapid [[bootstrapping|bootstrapping process]] does in no way invalidate the results of [[exploratory engineering]] which says (as a highly reliable prediction) that stiff nanomachinery (A) is possible and (B) will (if ever enough focus and effort is put in for it to be built) be capable of outperforming soft nanomachinery by orders of magnitude in pretty much all regards.
  
* [[evolution]]
+
It seems that currently there are more pathway entry (and exit) points via an [[incremental path]] approach rather than there are pathway entry (and exit) points for a [[direct path]] approach. 
 +
That is, it seems as if current technology is just not ready yet to make a a big sudden leap forward. <small>(Side-note: This may be a good thing, considering stability of world economy and such.)</small>
  
= Almost everything will be buildable - often misunderstood =
+
Using to a large (but not exclusive) part soft nanomachinery to get to stiff nanomachinery ASAP is thus the natural and most productive thing to do.
  
It is often thought that APM is supposed to be able to produce almost anything
+
'''On the other hand:''' <br>
(often formulated: all allowed structures permissible by physical law)
+
Using soft nanomachinery without a clear focus towards stiff nanomachinery will
including e.g. food, wood, plastics and metal parts but this is surely not the case.
+
not automatically lead to stiff nanomachinery (at least not in any reasonable timespan).
 +
So arguing that there is already effort in soft nanomachinery and thus if stiff nanomachinery is possible,  
 +
we will end up there eventually anyway, is a ''very'' bad approach.
  
The range of materials and structures targeted actually lies in a very narrow range (see: "[[mechanosynthesis]]"-page). <br>
+
= Almost everything will be buildable - often misunderstood =
The magic lies in the [[diamondoid metamaterials]] that emulate properties above the atomic level.
+
  
This is not to say it will be impossible for all times to assemble materials (or rather compounds) lying outside the narrow set of now targeted materials.
+
* Moved to: [[Every structure permissible by physical law]]
When the technology will have been around for quite a while [[Most speculative potential applications|very advanced extensions]] may be able to do this but this is way beyond the scope of any current day APM attainment project because it is beyond the horizon of useful [[exploratory engineering]].
+
* More on: [[The defining traits of gem-gum-tec]]
 +
 
 +
In particular organic matter like food, replacement organs, and chain polymers likes today's plastics are not a target product of [[gem-gum technology]]. <br>
 +
At least not a direct target.
  
 
== No food from gem-gum factories ==
 
== No food from gem-gum factories ==
Line 161: Line 332:
 
Also other technology branches (bio-nanotechnology ...) unrelated to APM may be able to produce edible tissues before of after we attain advanced APM capabilities.
 
Also other technology branches (bio-nanotechnology ...) unrelated to APM may be able to produce edible tissues before of after we attain advanced APM capabilities.
  
= Flawed critics about the fundamentals =
+
= Less common and or less relevant misconceptions =
  
== Macro-scale style machinery isn't suitable for the quantum world one needs something more exotic instead - wrong ==
+
== Why not go build with nucleons when they are even smaller than atoms? ==
  
Via [[Nanomechanics is barely mechanical quantummechanics|a very simple estimation]] it turns out that '''nanomechanics is actually barely mechanical quantum-mechanics'''. Baffling? The fact that quantum-mechanics is called quantum-''mechanics'' is just a somewhat unlucky result of science history. Basically mechanics was generalized to the point where it also encompasses the behavior of electrons thus to the point where it encompasses what is in eveready language considered electronics. And electronics are pretty quantum mechanical at the nanoscale. Of course certain nanomechanic systems can be made quantum mechanical in behavior if the conditions are made extreme enough.
+
Simply stated: Because it is not possible. <br>
 +
See: "[[Femtotechnology]]"
  
Actually under conditions expectable in [[Nanofactory|advanced atomically precise production devices]] nanomechanics is pretty classical in behavior.
+
== Gemstones are inherently scarce and valuable (and will always be) - wrong ==
Since the objective is to transport stuff from A to B in a controlled manner just like in makrotechnology using makro-style-machinery (with some minor tweaks) makes perfectly sense and has even advantages such as [[superlubrication]] and [[dissipation sharing]].
+
  
== Thermodynamics prevents one from having every atom at the place we want it - wrong for practical scales ==
+
Many gemstones are made of very common elements. <br>
 +
Making gemstones in a dirt cheap way is just a question of manufacturing capabilities. <br>
 +
In this case capabilities in [[mechanosynthesis]].
  
If one just looks at the atom displacements from thermal movement at room temperature alone big macroscopic slabs of stiff diamondoid materials stay atomically precise for long periods of time from a human perspective.
+
See page: [[Abundant element]] <br>
More serious are effects from hard ionizing radiation that can't be shielded effective against with.
+
On the page "[[Chemical element]]" the most abundant ones (in Earth's crust) are the ones that are not in brackets. <br>
Reliability and redundancy make things work practically nevertheless. Self repair can extend lifespans to uncalculable ranges.
+
There are plenty of combinations of very comon elements that make gemstones that make a very good structural base material. <br>
 +
See: [[Base materials with high potential]]
  
* [http://www.zyvex.com/nanotech/errorRates.html Zyvex about error rates]
+
== Gemstones are inherently brittle - wrong ==
  
There are many materials that do not keep their atoms at a constant place due to thermal motion.
+
(Or: One can't make soft materials from diamond - wrong)
They do not preserve their bond topology. Many metals behave that way especially on their surface.
+
Even water does not keep its atoms at its fixed at its molecules.
+
It swaps around hydrogen atoms due to its '''molecular auto-ionization''' pH7 H<sub>3</sub>O<sup>+</sup> OH<sup>-</sup>.
+
  
But there are also many materials (among them e.g. diamond) with bonds strong enough such that the constituent atoms for all practical purposes do not leave their lattice places due to thermal motion (radiation is a different story). Even when there are macroscopic amounts of material sitting around for decades at room temperature.  
+
What makes gemstones brittle are faults.
  
Biological systems (e.g. Proteins, DNA, RNA, ...) feature strong bonds.
+
Faults are unavoidable in macroscopic gemstones.
But almost all the involved molecules are chain molecules.
+
* Todays (2017) synthetic gems have faults right from birth due to their thermodynamic production route.
And (oversimplifying a bit) with chains only one link needs to break for the whole chain to break.
+
* Tomorrows [[mechanosynthesis|mechanosynthesized]] gems will quickly gain faults through natural ionizing radiation originating from the environment (or even from within in the likely case that radioactive isotopes where included)
Biological systems also tend to be embedded in a potentially aggressive chemical environments (aggressive relative to a vacuum).
+
Thus although biological systems feature strong bonds they need (and have) some active repair mechanisms to keep everything roughly where it is.
+
  
Having [[crystolecule]]s with a dense mesh of redundant polycyclic bonds in a vacuum makes the time it takes for them to incur destructive damage long enough for them to be extensively used even without any repair. [[Self repairing system|Self repair in advanced nanosystems]] (in the sense of part replacement) is an available but not unconditionally necessary option.
+
Faults are with a very high rate avoidable in nanoscale gemstones ([[crystolecule]]s) though.
 +
Most of a whole lot of identical crystolecules are perfectly flawlwess.
 +
Due to lack of any flaws these crystolecules are bendable to a pretty high degree.
 +
Well, not as extreme like rubber (several 100%) but still easily up to a two digit percentage range.
 +
A macroscopic block composed out of interlocking crystolecules does catch the cracks of the few unavoidably broken crystolecules at the clean unconnected borders between crystolecules.
 +
This makes the macroscopic block much less brittle than a single crystal.  
 +
(Side-note: Crystolecules do not only feature a perfectly flawless interior but also atomically precise surfaces.)
 +
Adding a more sophisticated metamaterial structure allows even [[elasticity emulation|emulation off rubber like properties]] (reversible strainability to several 100%) but with much higher tensile strength (and heat resistance).
  
Related:
+
== APM can make precious metals from dirt - wrong ==
* [[surface reconstruction]] and [[surface diffusion]]
+
* science vs engineering
+
* low error rate of digital systems
+
* [[Neo-polymorph]]s - exclusively mechanosynthetically accessible highly stable stable non equilibrium polymorphs of compounds
+
* Wikipedia: [https://en.wikipedia.org/wiki/Thermodynamic_equilibrium Thermodynamic equilibrium]
+
  
== Advanced APM systems are a "castle in the sky" with no way to built them - not quite ==
+
APM is all about chemistry. Well, [[unnatural chemistry]] but that's not the point here.
 +
The point is that chemistry cannot make or change (transmute) elements.
 +
(See "[[femtotechnology]]" for more details why).
  
It has often be perceived that [[diamondoid molecular elements]] can only be synthesized by stiff tools made that themselves are made from [[diamondoid molecular elements]]. The [[incremental path]] avoids circular dependencies by continuously changing the [[method of assembly]] from self assembly to stereotactic control. (Radical Abundance - page 190)
+
Elements can only be made with nuclear technology (which are necessarily macroscale power-plants).
 +
This is called (nuclear) transmutation. It is (and likely will remain) way too inefficient to be economic.
 +
A better option may be to get scarce elements from space (asteroid mining) in case they really will be needed in great amounts.<br>
 +
Side-note: Not that its important in face of the other problems but, unlike chemical APM, nuclear technology seems to be fundamentally statistical in nature.
 +
At least if one does not want to go to [[Nuclear_fusion#Highly_speculative_one_try_one_hit_fusion|extremely speculative areas]].
  
The [[direct path]] tries to use bigger already stiff but not quite atomically precise slabs of material to build stiff atomically precise structures (e.g. in MEMS-AFMs). This is not fundamentally impossible but a much steeper slope judging from the progress rates.
+
Of course it will be possible to [[APM and nuclear technology|use APM to build nuclear power-plants in great numbers]].  
 +
But this is an entirely different topic.
  
== Atoms can't be placed individually because of "fat and sticky fingers" - sticky is actually good fat is just untrue for the tips ==
+
== Diamond has a much lower density than silicon (which has identical structure) - wrong ==
 
+
Disproved by basic experimental and detailed theoretical work. See: [[Mechanosynthesis]]. It may get a bit more challenging when the [[mechanosynthesis of chain molecules|mechanosynthesis of ''complex'' chain molecules]] is attempted.
+
Which is not a requirement for [[nanofactory|gem-gum-factories]].
+
 
+
= One can't make soft materials from diamond - wrong =
+
 
+
See: "[[emulated elasticity]]" for why this is not true.
+
 
+
= Minor ones =
+
 
+
== Diamond has a much lower density than silicon - wrong ==
+
  
 
Quite the opposite actually - diamond is pretty heavy for its volume:
 
Quite the opposite actually - diamond is pretty heavy for its volume:
Line 225: Line 392:
 
* Quartz: 2.65 g/cm<sup>3</sup> (denser than silicon although there are voids and lighter oxygen interspersed - how??)
 
* Quartz: 2.65 g/cm<sup>3</sup> (denser than silicon although there are voids and lighter oxygen interspersed - how??)
  
 +
== Related ==
 +
 +
* [[Macroscale style machinery at the nanoscale]]
 +
* '''[[Common critique towards diamondoid atomically precise manufacturing and technology]]'''
 +
* Some of the trapdoors listed here are known for a long time now. <br>They old [[Engines of Creation]] has some of them pretty early on in the introduction. <br>Listed there are ... {{wikitodo|add list}}
 +
----
 +
* '''[[General tips for productive communication]]'''
  
 
[[Category:General]]
 
[[Category:General]]
 +
 +
== Table of contents ==
 +
 +
__TOC__

Latest revision as of 07:50, 15 September 2024

APM is a very novel area of research and development that dives into fields of knowledge that are yet pretty alien for most people including many "nanotechnology" experts. When encountering a new network of knowledge one usually tries to apply existing knowledge to judge statements and claims - what else can one do. Without deeper understanding of the relationships this can lead people into trapdoors. Some are so bad that almost everyone falls in. This page is intended to be a guide around those trapdoors.

There is another related page that focuses on more concrete details around scaling laws here:
Common critique towards diamondoid atomically precise manufacturing and technology

No nanobots here

See main page: No nanobots

When thinking about manufacturing things from the bottom up almost atom by atom often
the first association that often comes up are "nanobots" in the sense of
"littly tiny critters" that can do highly compact self replication.

A more technical analysis though revealed that this concept is not the right
approach. (At least when it comes to most manufacturing systems.)

This (mis)association of APM with "nanobots" and the intense historic discussion may be due to:
(1) Nanobots being a self suggesting first idea.
(2) Nanobots being a an idea that tends to rile up emotions because they coming with a number of wild secondary (mis)associations like:

  • them being almost life like – The "How dare you try to play god argument".
  • them being capable to evolve like bacteria cells
  • them being able to "eat" just about anything
  • them getting totally out of control – The "How dare you even think about something so dangerous argument"

And that's totally missing that self replicatibe nanobots are not even the target anymore.

Macroscale style machinery at the nanoscale ?!

Or: Macro-scale style machinery isn't suitable for the quantum world one needs something more exotic instead - wrong

Topic of discussion:
What is under scrutiny here is what is crudely outlined in this animation video:
Productive Nanosystems From molecules to superproducts.
What is shown is a quite accurate visualization of the results of exploratory engineering that was done in the work that is Nanosystems.

There are quite a number of points of critique here.
They are listed and discussed on the page: Macroscale style machinery at the nanoscale
The gist is: It is rather clear where the points of critique come from. That is: There are good reason for all these doubts given the current (2021…2024) state of technology. But all of the most fundamental critique points have been analyzed and came to a favorabel conclusion for the concept to work. In the end it turns out that the chaining of physics with size scales makes macroscale style machinery at the nanoscale actually work better rather than worse than "macroscale style machinery at the macroscale". Contrary to the expectation of some "current day nanotechnology" experts.
(Side-note: If you are wondering about nanoscale style machinery at the macroscale now: This is hardly possible.)

Related: Applicability of macro 3D printing for nanomachine prototyping

Diamondoind nanomachines would be soft like jelly and thus infeasible - false and false

This widespread and persistent common misconception is an artifact of a limitation of simulation capabilities
A limitation that leads to systems being simulated at speeds hundred thousand times faster than proposed speeds (100m/s rather than 1mm/s).
Details to that limitation and more can be found on the page:
Misleading aspects in animations of diamondoid molecular machine elements

As a macroscale analogon:
Spring steel does also acts like jelly if parts are shot at each other almost at bullet speeds and observed with a slow motion camera.
That's essentially what one sees in almost all the atomistic simulations.
Difference is that isolated single nano-mechanisms (not bulk volumes of them !!) do not self destruct when steady state operated at these speeds. Macroscale machines could not get rid of the enormous waste heat fast enough.
Not that one would usually want to run nano-machines at these extreme speeds as it's very inefficient. And one obviously has to design around the wobble then.
At proposed speeds of a few mm/s there would be no perceptible motion driven flex visible in the simulations.
Beside the low speed diamond is way stiffer than even steel.

How much things bend actually does not change across scales.
That is: It is scale invariant in the "same absolute speed across scales" approximation.
And even better it goes down on a closer analysis.
For an explanations of details see page: Same relative deflections across scales.
Atop the misleading simulations:
The scaling law of lower stiffness of smaller machinery has the potential to fool even experts into this misconception.
Details on the linked page.

Potential concerns about mechanosynthesis

Atoms can't be placed individually because of "fat and sticky fingers" - sticky is actually good fat is just untrue for the tips

Disproved by basic experimental and detailed theoretical work. See: Mechanosynthesis.
It may get a bit more challenging when the mechanosynthesis of complex chain molecules is attempted.
Which is not a requirement for gem-gum-factories.

See main articles: "Fat finger problem" and "Sticky finger problem"
Or more generally see: "The finger problems".
There are two more finger problems beside the two infamous ones.

Once placed atoms won't stay there because of "thermodynamics" - mostly false - solvable problem

In other words: Thermodynamics prevents one from having every atom at the place we want it - wrong for practical scales

Picking the right materials to synthesize the placed atoms will very much stay where they are put.
Except hit by hard radiation. Radiation can be dealt with by:

More details:

Atoms can't be placed fast enough - false

To make macroscopic products in a reasonable time-span by putting them together atom by atom would require atom placement frequencies too high to reach.

This is not true. Quite moderate atom placement frequencies in the MHz range suffice when combined
with massive spacial parallelism that is hard but realistically to reach.
See: "Atom placement frequency" for details.

Control data can't be supplied fast enough - false

We already do similar things with our current technology. See: Data IO bottleneck

If the goal would be to make an exact copy of some chunk of naturally occuring matter with every atom at the
same place the amount of data would indeed could not be handled because the data can't be efficiently compressed.
But that is not the goal. Even in the actual case of synthesis of food this is not the goal.

For organic matter the nature of data de-compression from DNA to tissue is vastly different to
the data-compression in gem-gum factories from code to gem-gum product.
See: Decompression chain

It's called "nanotechnology" - not anymore

Due to the terms extreme generality it caused confusion and conflict.
Hardening misconceptions causing unjustified discreditation going as far as
fear of career loss based self censorship and consequently a severe setback in development.

For details see main article: "The term nanotechnology" (and page: History & The negative effects that public overexcitement can have).

When referring to APM related ideas it's seems best to …

Suggestions for descriptive unannexable names for the technology

Be more specific as far as this is possible.
Here are suggestions for terms that are more specific:

  • "gemstone metamaterial technology" or "gem-gum-tec" for short
  • "gem(stone) based APM" or "gem based advanced APM"

Note that …

  • just "advanced APM" is vague, it fails to specify that advancedness shall refer to being based on gemstones so only use this if that's the intention.
  • just APM (atomically precise manufacturing) does not explicitly exclude very early systems like
    structural DNA nanotechnology, foldamer technologies, spiroligomers, …
  • just "advanced nanotechnology" is asking for conflict as there are folks that
    see soft machines or more narrowly synthetic biology filling that role entirely.

"Gem based APM" is not "The Real Nanotechnology"™

As a weak analogy:
Fighting for "nanotechnology" to mean "gem based APM"/"gem-gum-tec" exclusively is like
fighting for "macrotechnology" to mean metallurgy and metal machining exclusively.

  • It's misdirected effort as the analogy should make obvious.
  • It's a fight against windmills. A pointless waste of effort.

Evolution of terminology is an indominable force of nature as a whole society is involved.
When gem based APM becomes the dominant type of nanotechnology eventually,
then the term nanotechnology might change it's meaning to align with gem-gum-tec all by itself (reversing the by some perceived problem).
But for now for the sake of productive discussions about near term APM and far term APM
we should seriously try to avoid using the term "nanotechnology" to refer to "gem-gum-tec".
Please 🙏.

Nature does it differently thus gem based APM must be flawed. – Faulty reasoning.

See main article: "Nature does it differently".

It will be insurmountably difficult to develop gem based APM – Wrong

No, not insurmountable. Yes, it will be a very difficult journey.
It's just a humongous, possibly multi-generational, challenge with many people and work-hours months and years involved.
It may happen within one single average human lifespan (as of 2021…2024), but anyone who says that this is a fact is wildly guessing.
There is not "the one exponential trend" like e.g Moores law that can be projected into the future.
At least not yet.

There are some common incorrect assumptions about what
are unconditionally necessary technological prerequisite skills.

Three misconceptions:

  • This technology would need to be as advanced as life.
  • We have no hope of ever recreating a level of technological skill that comes anywhere close to life.
  • We should not even dare to attempt recreation of something as advanced as life.

No, no, and false premise respectively.

  • No, the technology is very different to living systems and most likely much less complex. (See dedicated section below)
  • No, there is other (APM unrelated) technological development that aims at recreation of primitive life like systems and it might have chance at succeeding.
  • Aside the false premise:
    Don't we have the obligation (and privilege) to research the world given to us in a responsible way.
    Won't the lack of hopes, dreams, and curiosity will certainly lead to bad things?

Misconception:
Handling the complexity of large scale full on quantum mechanical systems will be an unconditionally necessary technological skill.
Full on quantum mechanically meaning aptly handling highly quantum-dispersed and entangled-systems.
No, This is not a prerequisite for advanced APM. See: "It's not quantum mechanical"
It would be a prerequisite if building quantum computers would be a direct target of APM, but that is not a target.
Advanced skills in quantum system handling will rather be a natural byproduct of developments in the field of APM.

Misconception:
Super advanced AI/AGI systems will be critically necessary to build even minimal viable advanced productive nanosystems.
No, We managed to build incredibly intricate computer-chips without advanced AI.
Though it certainly will be of help for optimizing routing of electrical and other subsystems and such.
And AI tools will become increasingly available. Same with quantum computing.

Misconception:
The (very difficult) direct path is a the only viable path.
No, there is also the incremental path (using soft nanotech to get to stiff nanotech ASAP)
A path that can augment the direct path or rather take on the bulk of the development process.

Misconception:
The (very difficult) direct path is pointless and (because too difficult)
will contribute absolutely nothing to progress towards gem based APM.

We would need god like skills to create life-like nanotechnology

No, Development of APM does not aim at recreating some form of artificial life.
Aiming at doing that is part of a sub-field of synthetic biology.
Synthetic biology is a different field of technological development.
Synthetic biology is not aiming at atomically precision over over larger size scales and thus
it does not fall into the field of APM as it is defined in this wiki. Not even incremental path.
People working in the field of synthetic biology may well have a chance at creating primitive life like systems.
So even if R&D in the field of APM would aim at recreating primitive life-like systems (which it does not)
the situation would still not be absolutely hopeless.

Complex systems can gain surprising and charismatic behavior similar to life. Looking at computers and AI/AGI here.
So eventually products made by gem-gum on chip factories may behave and feel life like.
But that is way beyond basic advanced productive nanosystems.
That would be about the most advanced products of them. (Related: Multi limbed sensory equipped shells)

Associations of R&D in the field of APM with the idea of recreating life-likely systems comes
likely mostly from the self-suggesting analogy to microorganisms like bacteria that
was brought forward in the (now outdated) molecular assembler concept (initially presented in Engines of Creation).
While molecular assemblers would not need to be anywhere near as complex as living cells (e.g. no need for evolving skills)
they would need to be much more complicated (and slow/inefficient) than systems that do not feature such ultra-compact self-replicative capabilities.

The idea of molecular assemblers (the idea not the devices themselves) was (and sadly still is) so successful
compared to the actual target likely because:

Early advanced productive nanosystems will likely be more like computer chips rather than living cells.
While living cells store their building plan in a few gigabytes (which is well in reach of current 2021 computer technology)
an incredible aspect of life is the degree of smartness in data-compression.
E.g. how a whole human being can be encoded in the little amount of information stored in the DNA (ignoring epigenetics and the microbiome here).
But again, recreating that is an eventual goal of synthetic biology not a goal when aiming for minimal viable gem-gum factories.

Actual points of great difficulty in the development of APM that often are overlooked

  • The biggest current challenges in relevant targeted development are of conceptual and institutional nature.
    Meta: This very page here is an effort on improving ion the conceptual. understanding.
  • What is not (yet) well know about advanced APM is that
    there is stuff that actually can already be known (via the methodology of exploratory engineering).
  • Funding of highly targeted relevant work is very difficult. Perhaps the biggest blocker of progress as of 2024.
  • Not at all an exhaustive list ...

Advanced APM systems are a "castle in the sky" with no way to built them - not quite

It has often be perceived that diamondoid molecular elements can only be synthesized by stiff tools made that themselves are made from diamondoid molecular elements. The incremental path avoids circular dependencies by continuously changing the method of assembly from self assembly to stereotactic control. (Radical Abundance - page 190)

The direct path tries to use bigger already stiff but not quite atomically precise slabs of material to build stiff atomically precise structures (e.g. in MEMS-AFMs). This is not fundamentally impossible but a much steeper slope judging from the progress rates.

Lots of relevant pathway entry (and exit) points worth starting to take

There is by no means a lack of places where invested work would clearly lead to progress that is specifically relevant to APM.

If one looks at the right places then one can find both:

  • Lots of pathway-starts "signed" to lead to the target.
  • Lots of pathway-ends "signed" to come from the start.

With this many starts and ends the existence and realistic archievability of at least one path connecting some start to some end is very very likely.

See pages:

Using soft/compliant manomachinery to get to hard/stiff nanomachinery ASAP is hypocrisy - false

No, it's just a practical approach.
Ones usage of soft nanomachinery for a rapid bootstrapping process does in no way invalidate the results of exploratory engineering which says (as a highly reliable prediction) that stiff nanomachinery (A) is possible and (B) will (if ever enough focus and effort is put in for it to be built) be capable of outperforming soft nanomachinery by orders of magnitude in pretty much all regards.

It seems that currently there are more pathway entry (and exit) points via an incremental path approach rather than there are pathway entry (and exit) points for a direct path approach. That is, it seems as if current technology is just not ready yet to make a a big sudden leap forward. (Side-note: This may be a good thing, considering stability of world economy and such.)

Using to a large (but not exclusive) part soft nanomachinery to get to stiff nanomachinery ASAP is thus the natural and most productive thing to do.

On the other hand:
Using soft nanomachinery without a clear focus towards stiff nanomachinery will not automatically lead to stiff nanomachinery (at least not in any reasonable timespan). So arguing that there is already effort in soft nanomachinery and thus if stiff nanomachinery is possible, we will end up there eventually anyway, is a very bad approach.

Almost everything will be buildable - often misunderstood

In particular organic matter like food, replacement organs, and chain polymers likes today's plastics are not a target product of gem-gum technology.
At least not a direct target.

No food from gem-gum factories

Future gem-gum factories are not in any way intended to be usable for food production. Structures out of solvated weakly linked non stiff proteins and lipid layers are a good example of "anti-diamondoid" materials. Specialized devices will be capable of some limited form of synthesis of food.

Attempting to create genetic twin tissue (avoiding the need for a complete scan) has the problem that information extraction from DNA to a spacial (not only typological) atom and molecule configuration is not straightforward to say the least. There's not only the forward protein folding problem but also the yet unsolved riddle how body shape at all scales is encoded.

Why an perfect 1:1 copy of a steak is and will stay impossible

Attempting to create exact copies down to positional atomic presicion of an original tissue at this point seems ridiculously complex. Some kind of very advanced scan (atomically precise disassembly) of the original would be needed to be performed in advance. Trying to compress quasi-random atom configurations data hierarchically like in diamondoid APM systems would probably lead to strange unnatural compression artifacts. The need to produce everything in a frozen state (ice crystals) might be a hard problem but one of the most minute ones.

Tasty "meta-food" may be creatable (given sufficient design effort in chain molecule mechanosynthesis capabilities)

Creating something edible by mixing pure synthesizes molecules together (quite a lot of sloppy molecules need to be synthesizable thus not something to expect early on) together would produce something like an advanced nourishment dough. One may be able to fake familiar food for the human senses or make something else heterogeneous and tasty but it's questionable whether we really desire to fool ourselves. At some ends deficiencies through lopsided nutrition may arise while at other ends food might get a lot healthier. A mixed nutrition with natural food will probably be best.

Competing with cheap potatoes is hard

Note: Plants are already self replicating and thus cheap. Most people just don't grow all of the plants they consume because they need space, sun, soil, and often industrial post processing. Advanced (technical) APM will bring all the other stuff to the same or lower price level per mass. Including means for easier plant breeding.

To be competitive with the cheap self replicating food that we eat today tissue construction via advanced mechanosynthetic means (e.g. a pie like this hoax [1]) must be quite a bit faster than biological machinery. This may be expectable but at this point the highly diverse tool-tip chemistry at cryogenic temperatures and at the threshold of stability needed poses a prohibitively high barrier. That is barely any exploratory engineering can be applied here. Further some kind of hierarchical assembly that completely replaces the natural system would be needed.

Other sources of synthetic food

Also other technology branches (bio-nanotechnology ...) unrelated to APM may be able to produce edible tissues before of after we attain advanced APM capabilities.

Less common and or less relevant misconceptions

Why not go build with nucleons when they are even smaller than atoms?

Simply stated: Because it is not possible.
See: "Femtotechnology"

Gemstones are inherently scarce and valuable (and will always be) - wrong

Many gemstones are made of very common elements.
Making gemstones in a dirt cheap way is just a question of manufacturing capabilities.
In this case capabilities in mechanosynthesis.

See page: Abundant element
On the page "Chemical element" the most abundant ones (in Earth's crust) are the ones that are not in brackets.
There are plenty of combinations of very comon elements that make gemstones that make a very good structural base material.
See: Base materials with high potential

Gemstones are inherently brittle - wrong

(Or: One can't make soft materials from diamond - wrong)

What makes gemstones brittle are faults.

Faults are unavoidable in macroscopic gemstones.

  • Todays (2017) synthetic gems have faults right from birth due to their thermodynamic production route.
  • Tomorrows mechanosynthesized gems will quickly gain faults through natural ionizing radiation originating from the environment (or even from within in the likely case that radioactive isotopes where included)

Faults are with a very high rate avoidable in nanoscale gemstones (crystolecules) though. Most of a whole lot of identical crystolecules are perfectly flawlwess. Due to lack of any flaws these crystolecules are bendable to a pretty high degree. Well, not as extreme like rubber (several 100%) but still easily up to a two digit percentage range. A macroscopic block composed out of interlocking crystolecules does catch the cracks of the few unavoidably broken crystolecules at the clean unconnected borders between crystolecules. This makes the macroscopic block much less brittle than a single crystal. (Side-note: Crystolecules do not only feature a perfectly flawless interior but also atomically precise surfaces.) Adding a more sophisticated metamaterial structure allows even emulation off rubber like properties (reversible strainability to several 100%) but with much higher tensile strength (and heat resistance).

APM can make precious metals from dirt - wrong

APM is all about chemistry. Well, unnatural chemistry but that's not the point here. The point is that chemistry cannot make or change (transmute) elements. (See "femtotechnology" for more details why).

Elements can only be made with nuclear technology (which are necessarily macroscale power-plants). This is called (nuclear) transmutation. It is (and likely will remain) way too inefficient to be economic. A better option may be to get scarce elements from space (asteroid mining) in case they really will be needed in great amounts.
Side-note: Not that its important in face of the other problems but, unlike chemical APM, nuclear technology seems to be fundamentally statistical in nature. At least if one does not want to go to extremely speculative areas.

Of course it will be possible to use APM to build nuclear power-plants in great numbers. But this is an entirely different topic.

Diamond has a much lower density than silicon (which has identical structure) - wrong

Quite the opposite actually - diamond is pretty heavy for its volume:

  • Diamond: 3.5–3.53 g/cm3
  • "(Diamond+Silicon)/2" ~= Moissanite: 3.218–3.22 g/cm3 (heavier than the average density)
  • Silicon: 2.3290 g/cm3
  • Quartz: 2.65 g/cm3 (denser than silicon although there are voids and lighter oxygen interspersed - how??)

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