US2012250716A1PendingUtilityA1

Flexible Microcavity Structure Made Of Organic Materials Using Spin-Coating Technique And Methods Of Making

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Assignee: MENON VINOD MPriority: Dec 4, 2007Filed: Feb 16, 2012Published: Oct 4, 2012
Est. expiryDec 4, 2027(~1.4 yrs left)· nominal 20-yr term from priority
H01S 3/178H01S 5/18369H01S 3/0604H01S 3/0627H01S 3/169H01S 5/36
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Claims

Abstract

A flexible microcavity structure made of organic materials using spin-coating technique for allowing large area structures using a roll-to-roll process. The structure includes at least one first polymer layer, at least one second polymer layer, and a cavity layer. The cavity layer has quantum dots embedded therein fir realizing an electrically pumped microcavity emitter. The at least one first polymer layer alternates with the at least one second polymer layer, respectively, to form a pair of distributed Bragg reflecting mirrors. The cavity layer is sandwiched between the pair of distributed Bragg reflecting mirrors.

Claims

exact text as granted — not AI-modified
1 . A flexible microcavity structure made of organic materials using spin-coating technique allowing large area structures using a roll-to-roll process, comprising:
 a) at least one first polymer layer;   b) at least one second polymer layer; and   c) a cavity layer;   wherein said cavity layer has quantum dots embedded therein for realizing an electrically pumped microcavity emitter,   wherein each of said at least one first polymer layer alternates with said at least one second polymer layer to form a pair of distributed Bragg reflecting mirrors; and   wherein said cavity layer is sandwiched between said pair of distributed Bragg reflecting mirrors.   
     
     
         2 . The structure of  claim 1 , wherein a first polymer chosen for said at least one first polymer layer and a second polymer chosen for said at least one second polymer layers are not dissolvable in the same solvent so as to prevent the solvent dissolving one polymer from dissolving the other polymer. 
     
     
         3 . The structure of  claim 1 , wherein said first polymer used for said at least one first polymer layer is polyvinyl carbazole; and
 wherein said second polymer used for said at least one second polymer layer is cellulose acetate.   
     
     
         4 . The structure of  claim 1 , wherein said cavity layer is polyvinyl carbazole. 
     
     
         5 . The structure of  claim 4 , wherein said cavity layer has a thickness;
 wherein said quantum dots has an emission with a wavelength; and   wherein said thickness of said cavity layer is equal to an integer multiple of half said wavelength of said emission of said quantum dots.   
     
     
         6 . The structure of  claim 5 , wherein said quantum dots include InGaP; and
 wherein said wavelength of said emission of said InGaP is 670 nm.   
     
     
         7 . The structure of  claim 1 , wherein a lower one of said pair of distributed Bragg reflecting mirrors has ten periods; and
 wherein an upper one of said pair of distributed Bragg reflecting mirrors has five periods for better light extraction from said upper one of said pair of distributed Bragg reflecting mirrors.   
     
     
         8 . The structure of  claim 2 , wherein each of said pair of distributed Bragg reflecting mirrors has a stop bandwidth; and
 wherein said first polymer and said second polymer are chosen to allow alteration of said stop bandwidth of each of said pair of distributed Bragg reflecting mirrors.   
     
     
         9 . The structure of  claim 1 , wherein exact reflectivity and quality factors of said cavity layer is controlled by altering one of layer thicknesses, number of periods, and type of polymer.

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