All optical full adder based on intramolecular electronic energy transfer in the rhodamine - Azulene bichromophoric system

Olga Kuznetz; Husein Salman; Yoav Eichen; F. Remacle; R. D. Levine; Shammai Speiser

doi:10.1021/jp804658b

All optical full adder based on intramolecular electronic energy transfer in the rhodamine - Azulene bichromophoric system

Olga Kuznetz, Husein Salman, Yoav Eichen, F. Remacle, R. D. Levine, Shammai Speiser^*

^*Corresponding author for this work

Institute of Chemistry

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

Charge and electronic energy transfer (ET and EET) are well-studied examples whereby different molecules can signal their state from one (the donor, D) to the other (the acceptor, A). The electronic energy transfer from the donor (Rh) to the acceptor (Az) is used to build an all-optical full adder on a newly synthesized bichromophoric molecule Rh - Az. The results are supported and interpreted by a full kinetic simulation. It is found that the optimal design for the implementation of the full adder relies in an essential way on the intramolecular transfer of information from the donor to the acceptor moiety. However, it is not the case that the donor and the acceptor each act as a half adder.

Original language	English
Pages (from-to)	15880-15885
Number of pages	6
Journal	Journal of Physical Chemistry C
Volume	112
Issue number	40
DOIs	https://doi.org/10.1021/jp804658b
State	Published - 9 Oct 2008

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abstract = "Charge and electronic energy transfer (ET and EET) are well-studied examples whereby different molecules can signal their state from one (the donor, D) to the other (the acceptor, A). The electronic energy transfer from the donor (Rh) to the acceptor (Az) is used to build an all-optical full adder on a newly synthesized bichromophoric molecule Rh - Az. The results are supported and interpreted by a full kinetic simulation. It is found that the optimal design for the implementation of the full adder relies in an essential way on the intramolecular transfer of information from the donor to the acceptor moiety. However, it is not the case that the donor and the acceptor each act as a half adder.",

author = "Olga Kuznetz and Husein Salman and Yoav Eichen and F. Remacle and Levine, {R. D.} and Shammai Speiser",

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AU - Kuznetz, Olga

AU - Salman, Husein

AU - Eichen, Yoav

AU - Remacle, F.

AU - Levine, R. D.

AU - Speiser, Shammai

PY - 2008/10/9

Y1 - 2008/10/9

N2 - Charge and electronic energy transfer (ET and EET) are well-studied examples whereby different molecules can signal their state from one (the donor, D) to the other (the acceptor, A). The electronic energy transfer from the donor (Rh) to the acceptor (Az) is used to build an all-optical full adder on a newly synthesized bichromophoric molecule Rh - Az. The results are supported and interpreted by a full kinetic simulation. It is found that the optimal design for the implementation of the full adder relies in an essential way on the intramolecular transfer of information from the donor to the acceptor moiety. However, it is not the case that the donor and the acceptor each act as a half adder.

AB - Charge and electronic energy transfer (ET and EET) are well-studied examples whereby different molecules can signal their state from one (the donor, D) to the other (the acceptor, A). The electronic energy transfer from the donor (Rh) to the acceptor (Az) is used to build an all-optical full adder on a newly synthesized bichromophoric molecule Rh - Az. The results are supported and interpreted by a full kinetic simulation. It is found that the optimal design for the implementation of the full adder relies in an essential way on the intramolecular transfer of information from the donor to the acceptor moiety. However, it is not the case that the donor and the acceptor each act as a half adder.

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All optical full adder based on intramolecular electronic energy transfer in the rhodamine - Azulene bichromophoric system

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