Difference between revisions of "Brownian technology path"

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m (Apm moved page Technology path µ to Brownian technology path: more descriptive title was needed)
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'''Technology path µ''' is a randomly chosen term used on this site to describe an '''branch of advancement to an [[atomic precision|AP]] nanotechnology''' (beyond simple self assembly) '''that does exploit thermal movement''' like biological nanomachinery does instead of avoiding it and turning to [[machine phase]] like the mechanosynthetic branch to [[Main Page|APM]].  
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The term '''Brownian technology path''' will be used on this site to describe the '''branch of advancement to an [[atomic precision|AP]] nanotechnology''' (beyond simple self assembly) '''that does exploit thermal movement''' ([http://en.wikipedia.org/wiki/Brownian_motion Brownian motion]) like biological nanomachinery does instead of avoiding it and turning to [[machine phase]] like the mechanosynthetic branch does [[Main Page|APM]].  
  
Path µ will develop parallel to the mechanosynthetic technology levels I to III and may interact with them in unexpected and yet unpredictable ways.
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Thechnology of the ''brownian path'' utilize borrowed thermal energy to archive an action (e.g. material transport).
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It will develop parallel to the mechanosynthetic technology levels I to III and may interact with them in unexpected and yet unpredictable ways.
  
 
Like in the mechanosynthetic branch a switch from more scientific to more engineering treatment is probable to occur.
 
Like in the mechanosynthetic branch a switch from more scientific to more engineering treatment is probable to occur.
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Beside polypeptides artificial materials that biological systems cant easily break down can and will be used like (foldamers, peptoids).
 
Beside polypeptides artificial materials that biological systems cant easily break down can and will be used like (foldamers, peptoids).
  
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Due to it's nature brownian-technology is often limited to a narrow temperature range. The solvent's liquid range must not be out-stepped.
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Flexible 1D molecular chains or 2D sheets are generally more susceptible to thermal breakage than 3D crystals where multiple bonds would have to break simultaneously. If inventions of this technology path find use in [[technology level III]] they may severely limit the range of allowed operation temperature.
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See: "[[consistent design for external limiting factors]]".
  
 
Richard Jones [http://www.softmachines.org/wordpress/] is someone looking out in this direction. <br>
 
Richard Jones [http://www.softmachines.org/wordpress/] is someone looking out in this direction. <br>
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[Todo: add description ... about speculative advanced bio-compatible area]
[Todo: add description ... about speculative advanced bio-compatible area - also optics magnetics electronics and so forth]
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Due to it's nature of µ-technology is always limited to a narrow temperature range (the solvent's liquid range or smaller).
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The allowed temperature range of a whole system (on a thermally equilibrated micro-scale) is defined by the intersection of all the allowed temperature ranges of the system components.
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When using technology of Path µ in e.g. [[technology level III]] either in the process of reaching it or when re-merging after reaching it the machine phase AP Technology will acquire an accordingly restricted range of allowed operation temperature range especially much of the allowed low temperature regime will be cut off.
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It is advisable to keep track off all the allowed temperature ranges for system components (no matter which technology path)
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and keep the technology path branches (with vastly different allowed temperature ranges) as separate as possible.
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This is an instance of the general concept of [[consistent design for external limiting factors]].
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Revision as of 13:42, 12 January 2014

The term Brownian technology path will be used on this site to describe the branch of advancement to an AP nanotechnology (beyond simple self assembly) that does exploit thermal movement (Brownian motion) like biological nanomachinery does instead of avoiding it and turning to machine phase like the mechanosynthetic branch does APM.

Thechnology of the brownian path utilize borrowed thermal energy to archive an action (e.g. material transport). It will develop parallel to the mechanosynthetic technology levels I to III and may interact with them in unexpected and yet unpredictable ways.

Like in the mechanosynthetic branch a switch from more scientific to more engineering treatment is probable to occur. keeping useful principles salvaged from biological systems and ditching evolutionary remnants that hinder orthogonal design .... [Todo: add link]

Beside polypeptides artificial materials that biological systems cant easily break down can and will be used like (foldamers, peptoids).

Due to it's nature brownian-technology is often limited to a narrow temperature range. The solvent's liquid range must not be out-stepped. Flexible 1D molecular chains or 2D sheets are generally more susceptible to thermal breakage than 3D crystals where multiple bonds would have to break simultaneously. If inventions of this technology path find use in technology level III they may severely limit the range of allowed operation temperature. See: "consistent design for external limiting factors".

Richard Jones [1] is someone looking out in this direction.
[Todo: add description ... about speculative advanced bio-compatible area]

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