Difference between revisions of "Ablative armor"

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Ablative armor hull plating was in development for a number of years prior to its deployment on the [[Defiant class|''Defiant'' class]] in [[Chronology: 2370|2370]]. Various factors related to materials availability, instabilities, [[phaser]] and [[photon torpedo|torpedo]] resistance, and long fabrication lead times prevented its widespread use on frontline starships,<ref name="DS9TM"/> though it was later introduced on several other designs developed under the [[Perimeter Defense Directive]].<ref name="LUG25100"/> The armor worked in two stages; in the event of [[shields|shield envelope]] disruption, phaser or thermal EM was first dissipated over the hull surface, and above an undisclosed threshold caused the molecular matrix to boil off at a controlled rate, carrying away a large fraction of the landed beam energy. In most cases, the boil-off created a medium density particle cloud, which could also help disperse an incoming beam.<ref name="DS9TM"/>
 
Ablative armor hull plating was in development for a number of years prior to its deployment on the [[Defiant class|''Defiant'' class]] in [[Chronology: 2370|2370]]. Various factors related to materials availability, instabilities, [[phaser]] and [[photon torpedo|torpedo]] resistance, and long fabrication lead times prevented its widespread use on frontline starships,<ref name="DS9TM"/> though it was later introduced on several other designs developed under the [[Perimeter Defense Directive]].<ref name="LUG25100"/> The armor worked in two stages; in the event of [[shields|shield envelope]] disruption, phaser or thermal EM was first dissipated over the hull surface, and above an undisclosed threshold caused the molecular matrix to boil off at a controlled rate, carrying away a large fraction of the landed beam energy. In most cases, the boil-off created a medium density particle cloud, which could also help disperse an incoming beam.<ref name="DS9TM"/>
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{{References}}
==References==
 
 
<references>
 
<references>
 
<ref name="DS9TM">[[Star Trek: Deep Space Nine Technical Manual (Book)|''"Star Trek: Deep Space Nine'' Technical Manual"]]. ''[[Star Trek: Deep Space Nine]].'' Book. Simon &amp; Schuster/Pocket Books, November 1994.</ref>
 
<ref name="DS9TM">[[Star Trek: Deep Space Nine Technical Manual (Book)|''"Star Trek: Deep Space Nine'' Technical Manual"]]. ''[[Star Trek: Deep Space Nine]].'' Book. Simon &amp; Schuster/Pocket Books, November 1994.</ref>

Revision as of 11:16, 26 July 2019

Ablative armor hull plating was in development for a number of years prior to its deployment on the Defiant class in 2370. Various factors related to materials availability, instabilities, phaser and torpedo resistance, and long fabrication lead times prevented its widespread use on frontline starships,[1] though it was later introduced on several other designs developed under the Perimeter Defense Directive.[2] The armor worked in two stages; in the event of shield envelope disruption, phaser or thermal EM was first dissipated over the hull surface, and above an undisclosed threshold caused the molecular matrix to boil off at a controlled rate, carrying away a large fraction of the landed beam energy. In most cases, the boil-off created a medium density particle cloud, which could also help disperse an incoming beam.[1]

Notes and References

  1. 1.0 1.1 "Star Trek: Deep Space Nine Technical Manual". Star Trek: Deep Space Nine. Book. Simon & Schuster/Pocket Books, November 1994.
  2. "The Price of Freedom: The United Federation of Planets Sourcebook". Star Trek: The Next Generation Roleplaying Game, Supplement 25100. Game. Last Unicorn Games, Inc., February 1999.