Difference between revisions of "Low level gemstone metamaterial"
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== On the blurryness of a delineation between base material and metamaterial == | == On the blurryness of a delineation between base material and metamaterial == | ||
| − | With bigger [[neo-polymorph|neopolymorphic]] patterns the | + | With bigger [[neo-polymorph|neopolymorphic]] patterns the materials become |
* less of a high level base materials and | * less of a high level base materials and | ||
* more of a low level metamaterials. | * more of a low level metamaterials. | ||
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* inacessible by means of [[conventional thermodynamic means of production]] only accesible via [[mechanosynthesis]] | * inacessible by means of [[conventional thermodynamic means of production]] only accesible via [[mechanosynthesis]] | ||
* they are quite complicated [[neo-polymorphs]] | * they are quite complicated [[neo-polymorphs]] | ||
| − | * they can | + | * they can themselves be considered a base material in the context of [[mechanical metamaterial]]s of a [[levels of metamaterials|higher level]]. <br>(E.g. a gemstone base material for metamaterials formed by somehow interlocking [[crystolecules]]) |
* their complex structure is giving them properties that are quite different to what could be considered their base material '''(thus metamaterials)''' | * their complex structure is giving them properties that are quite different to what could be considered their base material '''(thus metamaterials)''' | ||
* development of them is not as easy and straightforward (relatively seen) as the development of higher level structural metamaterials | * development of them is not as easy and straightforward (relatively seen) as the development of higher level structural metamaterials | ||
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(Side-note: This is especially relevant for the [[non mechanical technology path]]). | (Side-note: This is especially relevant for the [[non mechanical technology path]]). | ||
| − | A simple example of a low level metamaterial is when | + | A simple example of a low level metamaterial is when doping atoms are embedded in a checkerboard or other exactly periodic pattern. <br> |
The distinction between low level metamaterials and [[gemstone based metamaterial|high level metamaterials]] may be difficult in some cases. <br> | The distinction between low level metamaterials and [[gemstone based metamaterial|high level metamaterials]] may be difficult in some cases. <br> | ||
* Conventionally doped semiconductors with their statistically embedded doping atoms are not called metamaterials. | * Conventionally doped semiconductors with their statistically embedded doping atoms are not called metamaterials. | ||
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* transport properties for all sorts of all sorts of [[quasi particles]] | * transport properties for all sorts of all sorts of [[quasi particles]] | ||
* mechanical properties – (here of most interest) | * mechanical properties – (here of most interest) | ||
| + | |||
| + | === On the difficulty in development of new complex neo-polymorphic materials === | ||
This is all very useful but also very difficult. Often one finds a solution solving only one particular problem. <br> | This is all very useful but also very difficult. Often one finds a solution solving only one particular problem. <br> | ||
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with complementary properties. And then one satisfyingly "fake" all else with combinations of these few which takes orders of magnitude less effort and | with complementary properties. And then one satisfyingly "fake" all else with combinations of these few which takes orders of magnitude less effort and | ||
even makes possible things that without the "faking" wouldn't even possible at all. | even makes possible things that without the "faking" wouldn't even possible at all. | ||
| + | |||
| + | Higher level structural mechanical metamaterials are likely much simpler to design. <br> | ||
| + | They have an other (more at mechanical properties aimed) application case though. | ||
| + | |||
| + | === On the vastness of the number of newly possible complex neo-polymorphic materials === | ||
The set of sufficiently [[metastable]] low level metamaterials is significantly bigger than <br> | The set of sufficiently [[metastable]] low level metamaterials is significantly bigger than <br> | ||
| Line 45: | Line 52: | ||
== Related == | == Related == | ||
| + | * '''[[Levels of metamaterials]]''' | ||
| + | ---- | ||
* [[Gemstone like compound]] | * [[Gemstone like compound]] | ||
| − | * [[Neo-polymorph]] | + | * [[Neo-polymorph]] & [[Pseudo phase diagram]] |
| + | * [[Metamaterial]] | ||
Latest revision as of 12:57, 19 June 2023
Contents
On the blurryness of a delineation between base material and metamaterial
With bigger neopolymorphic patterns the materials become
- less of a high level base materials and
- more of a low level metamaterials.
That is: It may not be possible to draw an entirely sharp line between low level gemstone like compounds and high level gemstone based metamaterials.
Properties of low level metamaterials:
- inacessible by means of conventional thermodynamic means of production only accesible via mechanosynthesis
- they are quite complicated neo-polymorphs
- they can themselves be considered a base material in the context of mechanical metamaterials of a higher level.
(E.g. a gemstone base material for metamaterials formed by somehow interlocking crystolecules) - their complex structure is giving them properties that are quite different to what could be considered their base material (thus metamaterials)
- development of them is not as easy and straightforward (relatively seen) as the development of higher level structural metamaterials
Giving some more details:
Low level metamaterials include very stable patterns that are highly ordered. Those patterns may include vacancies and may have periods of repetition of arbitrary length.
Their structural alterations are small enough to influence properties that originate at such a low size scale.
Influenced properties include chemical, electrical, magnetic, and other properties.
(Side-note: This is especially relevant for the non mechanical technology path).
A simple example of a low level metamaterial is when doping atoms are embedded in a checkerboard or other exactly periodic pattern.
The distinction between low level metamaterials and high level metamaterials may be difficult in some cases.
- Conventionally doped semiconductors with their statistically embedded doping atoms are not called metamaterials.
- Mechanosynthesized materials with highly complex patterns of atoms inside may deserve to be called low level metamaterials.
Things that can be influenced on this very low level involve:
- The shape of the Fermi energy level in the Brilloin zone – which is the crystal unit cell in Fourier transformed space – in reciprocal space – ("periodicity space")
- Band-gaps, Electron density of states
- dispersion relations for photons
- dispersion relations for phonons – relating to thermal conductivity properties
- transport properties for all sorts of all sorts of quasi particles
- mechanical properties – (here of most interest)
On the difficulty in development of new complex neo-polymorphic materials
This is all very useful but also very difficult. Often one finds a solution solving only one particular problem.
One point of gemstone like compounds as base materials for gemstone based metamaterials is that one only pick and develops a few
with complementary properties. And then one satisfyingly "fake" all else with combinations of these few which takes orders of magnitude less effort and
even makes possible things that without the "faking" wouldn't even possible at all.
Higher level structural mechanical metamaterials are likely much simpler to design.
They have an other (more at mechanical properties aimed) application case though.
On the vastness of the number of newly possible complex neo-polymorphic materials
The set of sufficiently metastable low level metamaterials is significantly bigger than
the set of designed materials that is accessible today (2014..2017..2021) through cooking it together by macroscopic means.
This set of designed materials favors random mixing because they require very restrictive good thermodynamic accessibility.
