Kaehler bracket: Difference between revisions

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'''Kaehler brackets''' are (usually small) structural [[crystolecule]] elements made from [[gemstone-like compound]]s <br>
'''Kaehler brackets''' (named after Ted Kaehler see in links below) <br>
that have as their internal structure not a nicely ordered lattice <br>  
are (usually small) structural [[crystolecule]] elements made from [[gemstone-like compound]]s <br>
but rather a glassy [[quasi amorphous structure|amorphous like structure]] that was computer optimized <br>
that have as their internal structure not in a nicely ordered lattice <br>  
to approximate a certain ideally desired geometric alignment.
but rather in a glassy [[quasi amorphous structure|amorphous like structure]] that was computer optimized <br>
to approximate a certain ideally desired geometric alignment. <br>


Kaehler brackets are mentioned in the book [[Nanosystems]].
Kaehler brackets are mentioned in the book [[Nanosystems]].


== Avoiding high internal stresses and strains ==
== Effect of size on pose apporximation accuracy (and compute effort) ==


Avoiding high internal tensions will usually be desired to:
Bigger Kaehler brackets have more internal volume thus vastly more arrangement options <br>
* retain full mechanical strength
and can much more accurately approximate desired poses in space much more accurately. <br>
* avoid fire hazard or even explosion hazard


== Size and search space ==
Eventually approximation accuracy may become lower in error amplitudes than thermal motions amplitudes or <br>
({{speculativity warning}} even may go down towards the scale of nuclei for really big parts). <br>
See page: [[Quasi amorphous structure]] <br>


The bigger the bracket the more accurate a desired alignement can be approximated. <br>
With larger size also the size of the search space grows extremely (to uber astronomical sizes). <br>
The search-space quickly becomes hyper gigantic though. <br>
See page: [[Quasi amorphous structure]]
[[quantum computation|Quantum computers]] could be used to find optimal atomic arrangements for desired geometries.


== Going to the extreme ==
== Usage cases ==


Even if thermal motions are bigger than the achieved accuracy over large scales (macroscale) that can average out.  <br>
E.g. integrating [[strained shell structure]]s (like e.g. sliding sleeve bearings) <br>
Gravitational detectors e.g. can detect distances far below the diameter of an atomic core.
into a non-strained single [[The benefit of nonmonolithic structures|sort of]] single crystalline global frame while <br>
* introducing minimal stresses
* getting large cross sectional support area
 
Lower remnant stresses can
* … increase thermal, chemical, and mechanical stability and …
* … reduce system internal energy that otherwise could increase flammability <br>or possibly make thing even explosive in the worst case.


== Related ==
== Related ==


* '''[[Quasi amorphous structure]]''', [[glassolecule]], [[quasicrystolecule]]
* [[Crystolecule fragment]]
* [[Crystolecule fragment]]
* [[Dialondeite]]
* [[Dialondeite]]
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* [[Design of crystolecules]]
* [[Design of crystolecules]]
* Solving the associated optimization problem by employing the power of [[quantum computation|quantum computers]].
* Solving the associated optimization problem by employing the power of [[quantum computation|quantum computers]].
* [[Quasi amorphous structure]]
 
== External links ==
 
Wikipedia:
* [[https://en.wikipedia.org/wiki/Ted_Kaehler Ted Kaehler]]

Revision as of 10:37, 28 February 2025

Kaehler brackets (named after Ted Kaehler see in links below)
are (usually small) structural crystolecule elements made from gemstone-like compounds
that have as their internal structure not in a nicely ordered lattice
but rather in a glassy amorphous like structure that was computer optimized
to approximate a certain ideally desired geometric alignment.

Kaehler brackets are mentioned in the book Nanosystems.

Effect of size on pose apporximation accuracy (and compute effort)

Bigger Kaehler brackets have more internal volume thus vastly more arrangement options
and can much more accurately approximate desired poses in space much more accurately.

Eventually approximation accuracy may become lower in error amplitudes than thermal motions amplitudes or
(Warning! you are moving into more speculative areas. even may go down towards the scale of nuclei for really big parts).
See page: Quasi amorphous structure

With larger size also the size of the search space grows extremely (to uber astronomical sizes).
See page: Quasi amorphous structure

Usage cases

E.g. integrating strained shell structures (like e.g. sliding sleeve bearings)
into a non-strained single sort of single crystalline global frame while

  • introducing minimal stresses
  • getting large cross sectional support area

Lower remnant stresses can …

  • … increase thermal, chemical, and mechanical stability and …
  • … reduce system internal energy that otherwise could increase flammability
    or possibly make thing even explosive in the worst case.

Related

External links

Wikipedia:

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