Difference between revisions of "Gem-gum technology"

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The kind of products in this technology level are outlined in the definition of APM on the [[Main Page]]. <br>
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{{Template:Site specific definition}}
This page should give more details to the different aspects of advanced APM systems.
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{| class="wikitable" style="float:right; margin-left: 10px; text-align: center"
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! colspan = "2"|Defining traits of technology level III
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|-
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| building method
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| robotic control ([[machine phase]])
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|-
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| building material
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| minimal [[Moiety|molecule fragments]] and single H atoms
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|-
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| building environment
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| vacuum or noble gas
 +
|-
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! colspan = "2"|Navigation
 +
|-
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| back to very first level
 +
| [[technology level 0]]
 +
|-
 +
| previous level
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| [[technology level II]]
 +
|-
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| previous step
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| [[introduction of practically perfect vacuum]]
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|-
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| '''you are here'''
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| '''Technology level III'''
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|-
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| basis for products
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| [[diamondoid metamaterials]]
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|-
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| products
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| [[further improvement at technology level III]]
 +
|}
 +
[[File:Box_full_of_future_technology.jpg|400px|thumb|right|This box is full of things made with future '''gemstone metamaterial technology'''. While we can already make out roughly what [[products of gem-gum technology|some products]] could look like their exact visual appearance for now remain censored and hidden for our still undeserving eyes.]]
  
previous: [[technology level II]] <br>
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'''Gemstone metamaterial technology (or gem-gum-tec for short)''' is the far term target technology of [[Main Page|atomically precise manufacturing]]. <br>
next: [[further improvement at technology level III]]<br>  
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= Productive nanosystems  =
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Gem-gum-tec as a technological target point worth aiming for …
 +
* was identified via stringent application of low level [[exploratory engineering]] done in the book [[Nanosystems]].
 +
* is not just some fantastic vision based on mere wishful thinking. <br> That is: It's not like "we want the periodic table to behave like a construction kit therefore it will". No. There was feasibility analysis being done and things tuned out to be surprising promising. <br><small>(See: [[Ultimate limits#Whisful thinking vs Exploratory engineering]])</small>
  
[[file:technology-path-sketched.png|thumb|Growing specialization of nanosystems with incremental technology improvement leads more to nanofactories than assemblers.]]
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= Introduction =
  
In the beginning of APM research only ''(molecular) assemblers'' where considered as a means for reachig the capability to produce macroscopic amounts of a product.<br>
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This page will focus more on the products (artifacts of atomically precise technology)<br>
At '''T.Level III''' it turns out that Advanced nanofactories are more balanced and efficient than Assembler systems. At [[technology level I]] the border between minimal assemblers and rudimentary nanofactories is more blurred. '''FAULTY! TO REPAIR! ''' A rudimentary nanofactory might be buildabel without self replicon but a simplified two dimentional assembler model might work well too. <br> To have an umbrella term for both ideas The term ''productive nanosystems'' was introduced.<br>
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rather the production devices (devices for atomically precise manufacturing)
  
Using the whole volume for the building process of the product rather than a layer in the "classic" nanofactory design could speed up the building process. But this will not be neccesary for practical usage [TODO find existing proof]. If you build a solid block though you might end up to being slower than with the layer method due to the [[fractal growth speedup limit]]
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== Products ==
  
== Assembly levels ==
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'''See main page: [[Products of gem-gum-tec]]''' <br>
 +
Also related: [[opportunities]] and [[dangers]]
  
The assambly process of AP products can be clearly divided in a number of subsequent steps no matter whether the concrete implementetion of a productive nanosytem looks more like a nanofactory or more like an assembler system. Those steps are implementation agnostic. Further details can de found on the [[assembly levels|assembly levels page]].
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Products of gemstome metamatrial technology use [[gemstone like compounds]] as base materials but <br>
 +
vastly change their mechanical and other properties through nanostructuring into [[gemstone based metamaterial]]s. <br>
 +
For the fundamental nature of products of this technology see: [[Defining traits of gem-gum-tech]]. <br>
  
== Assemblers  ==
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'''Some expectable properties of this technology on the base materials side:'''
 +
* A giant slew on new materials with from today's perspective very weird and unexpected properties.
 +
* Way more materials that are suitable for outdoor usage exposed to rainwater and sun.
 +
* Materials with combinations of properties that are thought to be impossible today<br> E.g. Super-thought super-elastic elastic scratch resistant and heat transparent [[metamaterial]]s.
 +
* extremely low density yet robust materials allowing for (very speculative) [[aerial meshes]].
  
[[File:self-replicating-assembler-unit.png|thumb|Artistic depiction of a mobile assembler unit capable of self replication. An outdated idea.]]
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'''Some expectable properties of this technology on the materials side (near surface):'''
 +
* extremely bright displays with a much wider color gamut than what's possible today (2023) <br>also passive reflective-color displays with video capability <br>holographic capabilities (in the physically accurate meaning)
  
'''Note: Assemblers are deprecated!'''<br>The idea is to create a machine with side-lengths of a few hundred nanometers which packages all the functionality to produce useful products and also make copies of itself (directly with [[diamondoid]] [[mechanosynthesis]]). This way you get an exponential rate of reproduction and can produce macroscopic goods in reasonable amounts of time.
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'''Some expectable properties of this technology on the products side:'''
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* The possible high power densities means actuators will become invisibly integrated into things.
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* Ultra advanced emergency relieve systems. See: [[Disaster proof]] & [[Desert scenario]]
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* Enormous advances in macroscale robotics. See: [[Multi limbed sensory equipped shells]]
  
It turned out that packaging all the functionality into such a small package is a rather unbalanced and inefficient approach for T.Level III. This can be seen in the nanofactory cross section image (further down this page) where it is visible that the bottommost assembly levels (here layers) take the largest portion of the stack. In the small package of an assembler the bottommost layers would be underrepresented making it rather slow.
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'''Some expectable properties of this technology on the production machinery side:'''
 +
* Super-fast and local [[recycling]] by disassembling stuff only to the reusable [[microcomponent]] level rather than individual atoms.
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* Many public terminals for a [[global microcomponent redistribution system]]
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* Larger scale systems may take the manufacturing chips along with them. <br>Like e.g. "growing roads" or sparse-scaffold mega-structures in shipyards for the maritime sea and outer space.
  
Quite a bit of thought was put into this model. Either they where supposed to swim about in a solution or there was some form of movement mechanism in a machine phase scaffold crystal envisioned like:
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== Production devices (also a product) ==
  
*sliding cubes [TODO add references]
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'''See main page: [[Gemstone metamaterial on-chip factories]]'''
*legged blocks [TODO add references]
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The combination of their appearance (legs) with their very tightly packed capability of [[self replication]] in their vacuum "belly" that seem akin to a "whomb" led to the situation that the public started to perceive this technology as swarms of tiny life like nano-bugs that could potentially start uncontrollable and unstoppable self replication. Why this is a rather missinformed opinion can be read up [[the grey goo meme|here]].
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Artifacts (products) of in-vacuum gem-gum technology are manufactured via robotic atomically precise pick and place manipulation of [[moiety|molecule fragments of a size ranging from one to a few atoms each]] ([[piezochemical mechanosynthesis]]). This happens in an environment "filled" with [[practically perfect vacuum]]. Following are a number of assembly steps at increasingly larger size scales. Thesee are the [[assembly levels]] of [[convergent assembly]].
  
'''Many considerations about assemblers are still relevant:'''
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Products are assembled in [[advanced productive nanosystem]]s.<br>
* ''methods for movement'' e.g. for the transport of microcomponents and self repair by microcomponent replacement in the higher assembly levels of nanofactories. The ''[[Legged Block Mobility|legged block mobility]]'' design is also known from the concept of [[Utility Fog|Utility Fog]] ''(speculativity warning) ''but has other design priorities in an manufacturing context like more rigidity and less "intelligence".
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These [[gem-gum factories]] may come in various [[Form factors of gem-gum factories|form factors]].
* ''methods for gas tight sealing''
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Most promising candidate at the moment are [[gemstone metamaterial on-chip factories]] with an [[Design of gem-gum on-chip factories|appropriate design]] that employs [[convergent assembly]].
* ''and many more ...''
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== Advanced nanofactories  ==
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= Related =
  
[[File:productive-nanosystems-video-snapshot.png|thumb|Cross section through a nanofactory showing the lower assembly levels vertically stacked on top of each other.]]
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* The core of the technology. The manufacturing devices: '''[[Gemstone metamaterial on-chip factory]]'''
[[File:0609factory700x681.jpg|thumb|Artistic depiction of a nanofactory. Only the last assembly level (convergent assembly) is visible to the naked eye.]]
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* [[Technology levels]]
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* [[The defining traits of gem-gum-tec]]
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* [[In-vacuum gem-gum technology]] is both making up and made by [[gemstone metamaterial on chip factory]]. <br>If that sounds paradox it's because of the chicken egg problem of [[Bootstrapping methods for productive nanosystems|bootstrapping such factories]].
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* [[Gem-gum technology (disambiguation)]]
 +
----
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* [[Macroscale style machinery at the nanoscale]]
  
 +
= Terminology =
  
An [http://e-drexler.com/p/04/05/0609factoryImages.html artistic depiction] of a nanofactory.
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Here in this wiki "gem-gum tech" used without a prefix:
Note that only [[assembly levels#Level IV:|assemly level IV]] (convergent assembly) is visible in this picture. <br>
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* shall always refer to this technology operating in vacuum "in-vacuum gem-gum tech". ([[PPV]] in a [[gem-gum housing shell]])
The official productive nanosystem video [https://www.youtube.com/watch?v=mY5192g1gQg] shows all the other [[assembly levels]] except IV.
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* shall not refer to "in-solvent gem-gum tech" <br>(an eventual precursor technology)
  
= Design levels  =
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== About the chosen name for this kind of technology (meta) ==
  
APM systems can depending on the size of the chunk of them that is under considereration be designed at three different levels:
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"In-vacuum gemstone metamaterial technology"
 +
is a novel term introduced on this wiki (2017).
  
* atomistic level
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Alternative older terms had one or many of the following problems:
* lower bulk limit
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* they didn't exclude unrelated topics well (far too general and wide in scope)
* system level
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* they didn't capture the most important aspects of the technology well
 +
* they weren't catchy memorable and useably short
  
Further details can de found on the [[design levels|design levels page]].
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This situation led to [[History|problems in form of confusion and conflict in the past]].<br>
 +
Introduction of the new terms should in general be kept to a minimum. <br>
 +
But in this case the new term seems well motivated and thus justified.
  
== Diamondoid Molecular Elements (DMEs) ==
+
== Motivations for the name ==
  
At the core an advanced productive APM systems consist out of DMEs. <br>
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The "gem-gum" part of the name represents two core ideas:
DMEs can be designed either directly at the atomistic level or in lower bulk limit form.
+
  
There are two types of DMEs:
+
1) The core idea that even when one can [[mechanosynthesis|mechanosynthesize]] almost nothing (just a few simple [[diamondoid compound|base materials]]) one can make almost anything by mechanical emulation. '''Mechanical metamaterials'''. "gum" is just a shorthand for a concrete example of such a [[metamaterial]] that rhymes on "gem" which makes memorization a lot easier. Also it's an concrete example that's rather un-intuitive. Rubber made from gemstone. Which could peak interest (click-bait effect).
*Diamondoid Molecular machine elements DMMEs
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*Diamondoid Molecular structural elements DMSEs
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Furthere details can be found [[diamondoid molecular elements|diamondoid molecular elements page]].
+
  
Certain standard sets like ''housing components'' or a ''minimal set of compatible DMMEs'' are needed.
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2) The core idea that gradually increasing the [[stiffness]] of [[diamondoid compound|the materials one builds with]] is the ultimate key to advanced [[mechanosynthesis]]. The term "gem" (short for gemstone - obviously) points exclusively to the stiff base materials of the far term target technology. This explicitly excludes early stage atomically precise manufacturing such as "[[structural DNA nanotechnology]]" which has no [[positional atomic precision]] and would be mushed in with other terms.
  
Potential structural and machine elements that seem suitable to port them to DME designs can be found here:
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The "in-vacuum" part of the name narrows down further to materials that can only be synthesized in [[practically perfect vacuum]].
* [http://www.thingiverse.com/mechadense/collections/potential-nano-machine-and-nano-structural-elements Thingiverse collection I]
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* ['''Todo:''' add further resources]
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Depending on the design different degrees of modifications need to be done. <br>
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All degrees of freedome need to be controlled, wall thicknesses need to be increased, atomic roughness must be considered, ...
+
  
== Logistics  ==
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'''See main page: [[The defining traits of gem-gum-tec]]'''
  
Part of system level design...
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== Modifications of the name ==
  
*Data
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On this wiki "Technology level III" may sometimes be used synonymously for in-vacuum gem-gum technology.
*Energy
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*Raw Material
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*Waste
+
  
= Vacuum =
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By leaving out the "in-vacuum" part of the name (leaving only "gem-gum-tec") one can precisely widen the scope to include one technology level below. Namely ([[In-solvent gem-gum technology]]).
  
[[Mechanosynthesis]] of [[diamondoid]] materials in t.level III needs to be done in a "perfect" vacuum (or noble gas).
+
An other term occasionally used on the wiki to refer to gem-gum-tec is "advanced atomically precise technology". In-liquid gem-gum-tec may or may not be included dependent on context.
Any free gas molecules would quickly react with the tooltips rendering them dysfunctional.
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From current perspective creation of "perfect" vacua seems illusionary. Any operator of an UHV system knows that it is impossible to get rid of all the gas molecules that are unavoidably adsorbed on the vacuuum vessels walls.
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The current perspective is based on the current technology though.
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The vacuum vessels for APM systems of t.level III
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* are cavities sized in the nanometer range - this increases the probability of having zero gas molecules captured inside
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* have atomically precise maximally flat walls - not allowing for gas adsorption and allowing for maximally tight seals
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* can utilize atomically tight positive displacement pumps for vacuum generation - no backflow
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and are thus capable of creating sufficient vacua.
+
 
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At some place in the [[assembly levels]] (above Level II) '''products''' or fractions of them '''need to be locked out''' out of the vacuum area while keeping the interior perfectly gas free. This can be done with two pistons the like depicted below.
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This method doubles as a pump for stray gas molecules. Import of parts (locking them in) is not possible here.
+
 
+
[[File:Single-cycle-export-airlock.png|A method to lock out passivated parts into non-vacuum-areas that keeps the internal vacuum completely intact. Only export of parts is possible here. To import parts for tuning/repair/recycling an other method has to be used.]]
+
 
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It is '''more difficult''' to '''lock in''' parts. This reverse direction '''isn't a necessity''' for t.level III APM with its [[mechanosynthesis]] done in vacuum.
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A lot recycling can be done with passivated microcomponents in non vacuum envirounment.
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The ability to lock parts back in '''might be useful''' for tuning / repair / [[diamondoid molecular elements|DME]] recycling on a sub microcomponent level.
+
 
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To lock parts out shearing off gas molecules is not an option since the parts can be arbitrarily shaped.
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Still extremely low probabilities of remaining trapped gas molecules can be archived by:
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* using pistons / bellows that have a multitple volume of the handled parts
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* operating them multiple times
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* stacking airlocks in stages.
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* additional usage of microscale turbo-molecular pumps
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* slight heating is the nanofactory and product allows this (when no remnants of t.level I included)
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Examples for positive displacement pumps:
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* piston pumps - advantage of high throughput area
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* bellow pumps
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* scroll pumps
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* procressing cavity pumps
+
 
+
= Tooltips  =
+
 
+
[Tooltip cycle; DC10c;...] [[tooltip chemistry]]
+

Latest revision as of 13:07, 20 June 2023

This article defines a novel term (that is hopefully sensibly chosen). The term is introduced to make a concept more concrete and understand its interrelationship with other topics related to atomically precise manufacturing. For details go to the page: Neologism.
Defining traits of technology level III
building method robotic control (machine phase)
building material minimal molecule fragments and single H atoms
building environment vacuum or noble gas
Navigation
back to very first level technology level 0
previous level technology level II
previous step introduction of practically perfect vacuum
you are here Technology level III
basis for products diamondoid metamaterials
products further improvement at technology level III
This box is full of things made with future gemstone metamaterial technology. While we can already make out roughly what some products could look like their exact visual appearance for now remain censored and hidden for our still undeserving eyes.

Gemstone metamaterial technology (or gem-gum-tec for short) is the far term target technology of atomically precise manufacturing.

Gem-gum-tec as a technological target point worth aiming for …

Introduction

This page will focus more on the products (artifacts of atomically precise technology)
rather the production devices (devices for atomically precise manufacturing)

Products

See main page: Products of gem-gum-tec
Also related: opportunities and dangers

Products of gemstome metamatrial technology use gemstone like compounds as base materials but
vastly change their mechanical and other properties through nanostructuring into gemstone based metamaterials.
For the fundamental nature of products of this technology see: Defining traits of gem-gum-tech.

Some expectable properties of this technology on the base materials side:

  • A giant slew on new materials with from today's perspective very weird and unexpected properties.
  • Way more materials that are suitable for outdoor usage exposed to rainwater and sun.
  • Materials with combinations of properties that are thought to be impossible today
    E.g. Super-thought super-elastic elastic scratch resistant and heat transparent metamaterials.
  • extremely low density yet robust materials allowing for (very speculative) aerial meshes.

Some expectable properties of this technology on the materials side (near surface):

  • extremely bright displays with a much wider color gamut than what's possible today (2023)
    also passive reflective-color displays with video capability
    holographic capabilities (in the physically accurate meaning)

Some expectable properties of this technology on the products side:

Some expectable properties of this technology on the production machinery side:

  • Super-fast and local recycling by disassembling stuff only to the reusable microcomponent level rather than individual atoms.
  • Many public terminals for a global microcomponent redistribution system
  • Larger scale systems may take the manufacturing chips along with them.
    Like e.g. "growing roads" or sparse-scaffold mega-structures in shipyards for the maritime sea and outer space.

Production devices (also a product)

See main page: Gemstone metamaterial on-chip factories

Artifacts (products) of in-vacuum gem-gum technology are manufactured via robotic atomically precise pick and place manipulation of molecule fragments of a size ranging from one to a few atoms each (piezochemical mechanosynthesis). This happens in an environment "filled" with practically perfect vacuum. Following are a number of assembly steps at increasingly larger size scales. Thesee are the assembly levels of convergent assembly.

Products are assembled in advanced productive nanosystems.
These gem-gum factories may come in various form factors. Most promising candidate at the moment are gemstone metamaterial on-chip factories with an appropriate design that employs convergent assembly.

Related


Terminology

Here in this wiki "gem-gum tech" used without a prefix:

  • shall always refer to this technology operating in vacuum "in-vacuum gem-gum tech". (PPV in a gem-gum housing shell)
  • shall not refer to "in-solvent gem-gum tech"
    (an eventual precursor technology)

About the chosen name for this kind of technology (meta)

"In-vacuum gemstone metamaterial technology" is a novel term introduced on this wiki (2017).

Alternative older terms had one or many of the following problems:

  • they didn't exclude unrelated topics well (far too general and wide in scope)
  • they didn't capture the most important aspects of the technology well
  • they weren't catchy memorable and useably short

This situation led to problems in form of confusion and conflict in the past.
Introduction of the new terms should in general be kept to a minimum.
But in this case the new term seems well motivated and thus justified.

Motivations for the name

The "gem-gum" part of the name represents two core ideas:

1) The core idea that even when one can mechanosynthesize almost nothing (just a few simple base materials) one can make almost anything by mechanical emulation. Mechanical metamaterials. "gum" is just a shorthand for a concrete example of such a metamaterial that rhymes on "gem" which makes memorization a lot easier. Also it's an concrete example that's rather un-intuitive. Rubber made from gemstone. Which could peak interest (click-bait effect).

2) The core idea that gradually increasing the stiffness of the materials one builds with is the ultimate key to advanced mechanosynthesis. The term "gem" (short for gemstone - obviously) points exclusively to the stiff base materials of the far term target technology. This explicitly excludes early stage atomically precise manufacturing such as "structural DNA nanotechnology" which has no positional atomic precision and would be mushed in with other terms.

The "in-vacuum" part of the name narrows down further to materials that can only be synthesized in practically perfect vacuum.

See main page: The defining traits of gem-gum-tec

Modifications of the name

On this wiki "Technology level III" may sometimes be used synonymously for in-vacuum gem-gum technology.

By leaving out the "in-vacuum" part of the name (leaving only "gem-gum-tec") one can precisely widen the scope to include one technology level below. Namely (In-solvent gem-gum technology).

An other term occasionally used on the wiki to refer to gem-gum-tec is "advanced atomically precise technology". In-liquid gem-gum-tec may or may not be included dependent on context.