Advances in 3D two-photon optical storage devices

A. S. Dvornikov; I. Cokgor; F. B. McCormick; S. E. Esener; P. M. Rentzepis

Advances in 3D two-photon optical storage devices

A. S. Dvornikov, I. Cokgor, F. B. McCormick, S. E. Esener, P. M. Rentzepis

Research output: Contribution to conference › Paper › peer-review

Abstract

The materials, method and for storing and accessing information in 3D by means of two-photon absorption will be described. The materials used have very high two photon absorption crosssection and near unit quantum efficiency for fluorescence. The storage devices are composed of organic molecules, uniformly dispersed in polymer matrices. The binary codes zero and one correspond to two different structures of the same molecule, induced by simultaneous absorption of two photons. The writing and accessing of the information can be performed either bit by bit or in a 2D multibit plane format. Fatigue studies suggest that these materials are suitable for 3D storage devices. Automated recording and readout 3D systems have been constructed and characterized. Channel error sources have been identified, and a custom spatial bit-error-rate test has been developed.

Original language	English (US)
Pages	68-71
Number of pages	4
State	Published - 1998
Externally published	Yes
Event	Proceedings of the 1998 7th Biennial IEEE International Nonvolatile Memory Technology Conference (INVMTC) - Albuquerque, NM, USA Duration: Jun 22 1998 → Jun 24 1998

Other

Other	Proceedings of the 1998 7th Biennial IEEE International Nonvolatile Memory Technology Conference (INVMTC)
City	Albuquerque, NM, USA
Period	6/22/98 → 6/24/98

ASJC Scopus subject areas

Computer Science(all)

Cite this

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title = "Advances in 3D two-photon optical storage devices",

abstract = "The materials, method and for storing and accessing information in 3D by means of two-photon absorption will be described. The materials used have very high two photon absorption crosssection and near unit quantum efficiency for fluorescence. The storage devices are composed of organic molecules, uniformly dispersed in polymer matrices. The binary codes zero and one correspond to two different structures of the same molecule, induced by simultaneous absorption of two photons. The writing and accessing of the information can be performed either bit by bit or in a 2D multibit plane format. Fatigue studies suggest that these materials are suitable for 3D storage devices. Automated recording and readout 3D systems have been constructed and characterized. Channel error sources have been identified, and a custom spatial bit-error-rate test has been developed.",

author = "Dvornikov, {A. S.} and I. Cokgor and McCormick, {F. B.} and Esener, {S. E.} and Rentzepis, {P. M.}",

year = "1998",

language = "English (US)",

pages = "68--71",

note = "Proceedings of the 1998 7th Biennial IEEE International Nonvolatile Memory Technology Conference (INVMTC) ; Conference date: 22-06-1998 Through 24-06-1998",

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TY - CONF

T1 - Advances in 3D two-photon optical storage devices

AU - Dvornikov, A. S.

AU - Cokgor, I.

AU - McCormick, F. B.

AU - Esener, S. E.

AU - Rentzepis, P. M.

PY - 1998

Y1 - 1998

N2 - The materials, method and for storing and accessing information in 3D by means of two-photon absorption will be described. The materials used have very high two photon absorption crosssection and near unit quantum efficiency for fluorescence. The storage devices are composed of organic molecules, uniformly dispersed in polymer matrices. The binary codes zero and one correspond to two different structures of the same molecule, induced by simultaneous absorption of two photons. The writing and accessing of the information can be performed either bit by bit or in a 2D multibit plane format. Fatigue studies suggest that these materials are suitable for 3D storage devices. Automated recording and readout 3D systems have been constructed and characterized. Channel error sources have been identified, and a custom spatial bit-error-rate test has been developed.

AB - The materials, method and for storing and accessing information in 3D by means of two-photon absorption will be described. The materials used have very high two photon absorption crosssection and near unit quantum efficiency for fluorescence. The storage devices are composed of organic molecules, uniformly dispersed in polymer matrices. The binary codes zero and one correspond to two different structures of the same molecule, induced by simultaneous absorption of two photons. The writing and accessing of the information can be performed either bit by bit or in a 2D multibit plane format. Fatigue studies suggest that these materials are suitable for 3D storage devices. Automated recording and readout 3D systems have been constructed and characterized. Channel error sources have been identified, and a custom spatial bit-error-rate test has been developed.

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M3 - Paper

AN - SCOPUS:0032226470

SP - 68

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T2 - Proceedings of the 1998 7th Biennial IEEE International Nonvolatile Memory Technology Conference (INVMTC)

Y2 - 22 June 1998 through 24 June 1998

ER -

Advances in 3D two-photon optical storage devices

Abstract

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ASJC Scopus subject areas

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