Difference between revisions of "Mechanooptical conversion"

From apm
Jump to: navigation, search
(As is content factored out from page Optical effects)
 
(basic extension of page)
Line 1: Line 1:
One idea would be to have a dead end of an optical fiber and pass by with an attachment chain (over some stretch) electronically excited material
+
== Photonic steampunk ==
in such a way that the dradgging by catalyses a radiation emitting electronic de-excitation.
+
 
(could probably be combined with laser like stimulated emission).
+
One idea would be to have a dead end of an optical fiber and <br>
At an other location along the attachment chain the material is electronically re-excited.  
+
pass by with an attachment chain (over some stretch of the fiber) electronically excited material <br>
Electronically re-excited either by mechanical means, electronic means or in any other suitable way.
+
in such a way that the dragging by catalyses a radiation emitting electronic de-excitation. <br>
 +
<small>(This could probably be combined with laser like stimulated emission.)</small>
 +
At an other location along the attachment chain the material is electronically re-excited. <br>
 +
Electronically re-excited either by:
 +
* mechanical means (like applying very high pressure) or
 +
* electronic means or  
 +
* in any other suitable way.
  
 
Note that this approach with a chain only makes sense if in-place-re-excitation is a bottleneck. <br>
 
Note that this approach with a chain only makes sense if in-place-re-excitation is a bottleneck. <br>
(Kinda hope so, transporting metastable electronic excitations on an nanoscale attachment chain sounds kinda cool.)
+
<small>(Kinda hope so, transporting metastable electronic excitations on an nanoscale attachment chain sounds kinda cool. Like '''photonic steampunk''')</small>
  
 
'''Long enough phosphorescent decay time needed''': <br>
 
'''Long enough phosphorescent decay time needed''': <br>
The phosphorescent transition will need to have a long enough decay time to be mechanically transportable from excitation-site to (catalyzed) de-excitation-site. <br>
+
The phosphorescent transition will need to have a long enough decay time to be mechanically transportable  
Maybe with advanced atomically precise manufacturing capabilities (and fine tunable unusaually large intermolecular forces) a lot bigger range of <br>
+
* from excitation-site  
phosphorescent systems will be acessible/developable. {{todo|Investigate design of phosphorescent centers assuming advanced [[gem-gum technology]] is available.}}
+
* to (catalyzed) de-excitation-site.
 +
Maybe with advanced atomically precise manufacturing capabilities <br>
 +
(and fine tunable unusually large intermolecular forces) <br>
 +
a lot bigger range of phosphorescent systems will be acessible/developable. <br>
 +
{{todo|Investigate design of phosphorescent centers assuming advanced [[gem-gum technology]] is available.}}
  
'''No photo-bleaching''': <br>
+
'''Machine phase preventing photo-bleaching''': <br>
 
Having the photoactive molecules in machine phase may make it possible to avoid "photobleaching" (photoactive molecules taking damage) entirely.
 
Having the photoactive molecules in machine phase may make it possible to avoid "photobleaching" (photoactive molecules taking damage) entirely.
 +
 +
== Radio wave generation by mechanically rotating dipoles ==
 +
 +
{{wikitodo|Discuss this.}}
 +
 +
== Related ==
 +
 +
* [[Optical effects]]
 +
* [[Ligand field theory]]
 +
* [[Fin with spins]]
 +
* [[Organometallic gemstone-like compound]]

Revision as of 10:23, 26 August 2022

Photonic steampunk

One idea would be to have a dead end of an optical fiber and
pass by with an attachment chain (over some stretch of the fiber) electronically excited material
in such a way that the dragging by catalyses a radiation emitting electronic de-excitation.
(This could probably be combined with laser like stimulated emission.) At an other location along the attachment chain the material is electronically re-excited.
Electronically re-excited either by:

  • mechanical means (like applying very high pressure) or
  • electronic means or
  • in any other suitable way.

Note that this approach with a chain only makes sense if in-place-re-excitation is a bottleneck.
(Kinda hope so, transporting metastable electronic excitations on an nanoscale attachment chain sounds kinda cool. Like photonic steampunk)

Long enough phosphorescent decay time needed:
The phosphorescent transition will need to have a long enough decay time to be mechanically transportable

  • from excitation-site
  • to (catalyzed) de-excitation-site.

Maybe with advanced atomically precise manufacturing capabilities
(and fine tunable unusually large intermolecular forces)
a lot bigger range of phosphorescent systems will be acessible/developable.
(TODO: Investigate design of phosphorescent centers assuming advanced gem-gum technology is available.)

Machine phase preventing photo-bleaching:
Having the photoactive molecules in machine phase may make it possible to avoid "photobleaching" (photoactive molecules taking damage) entirely.

Radio wave generation by mechanically rotating dipoles

(wiki-TODO: Discuss this.)

Related