Efficient Utilization of Higher-Lying Excited States to Trigger Charge-Transfer Events

Several new fullerene–heptamethine conjugates, which absorb as far as into the infrared spectrum as 800 nm, have been synthesized and fully characterized by physicochemical means. In terms of optical and electrochemical characteristics, appreciable electronic coupling between both electroactive spec...

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Veröffentlicht in:	Chemistry : a European journal 2010-08, Vol.16 (31), p.9638-9645
Hauptverfasser:	Bouit, Pierre-Antoine, Spänig, Fabian, Kuzmanich, Gregory, Krokos, Evangelos, Oelsner, Christian, Garcia-Garibay, Miguel A., Delgado, Juan Luis, Martín, Nazario, Guldi, Dirk M.
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Schlagworte:	Buckminsterfullerene Charge transfer Chemical Sciences Chemistry cyanines Donors (electronic) dyes/pigments Electronics Excitation excited states Fullerenes Infrared Joining Lying or physical chemistry Organic chemistry Theoretical and
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container_title	Chemistry : a European journal
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creator	Bouit, Pierre-Antoine Spänig, Fabian Kuzmanich, Gregory Krokos, Evangelos Oelsner, Christian Garcia-Garibay, Miguel A. Delgado, Juan Luis Martín, Nazario Guldi, Dirk M.
description	Several new fullerene–heptamethine conjugates, which absorb as far as into the infrared spectrum as 800 nm, have been synthesized and fully characterized by physicochemical means. In terms of optical and electrochemical characteristics, appreciable electronic coupling between both electroactive species is deduced. The latter also reflect the excited‐state features. To this end, time‐resolved, transient absorption measurements revealed that photoexcitation is followed by a sequence of charge‐transfer events which evolve from higher singlet excited states (i.e., S2—fast charge transfer) and the lowest singlet excited state of the heptamethine cyanine (i.e., S1—slow charge transfer), as the electron donor, to either a covalently linked C60 or C70, as the electron acceptor. Finally, charge transfer from photoexcited C60/C70 completes the charge‐transfer sequence. The slow internal conversion within the light‐harvesting heptamethine cyanine and the strong electronic coupling between the individual constituents are particularly beneficial to this process. The higher the better: We have realized the rarely found scenario of a charge transfer that commences in a higher‐energy excited state (see image), through the careful choice of electron donor and electron acceptor.
doi_str_mv	10.1002/chem.201001613
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In terms of optical and electrochemical characteristics, appreciable electronic coupling between both electroactive species is deduced. The latter also reflect the excited‐state features. To this end, time‐resolved, transient absorption measurements revealed that photoexcitation is followed by a sequence of charge‐transfer events which evolve from higher singlet excited states (i.e., S2—fast charge transfer) and the lowest singlet excited state of the heptamethine cyanine (i.e., S1—slow charge transfer), as the electron donor, to either a covalently linked C60 or C70, as the electron acceptor. Finally, charge transfer from photoexcited C60/C70 completes the charge‐transfer sequence. The slow internal conversion within the light‐harvesting heptamethine cyanine and the strong electronic coupling between the individual constituents are particularly beneficial to this process. 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In terms of optical and electrochemical characteristics, appreciable electronic coupling between both electroactive species is deduced. The latter also reflect the excited‐state features. To this end, time‐resolved, transient absorption measurements revealed that photoexcitation is followed by a sequence of charge‐transfer events which evolve from higher singlet excited states (i.e., S2—fast charge transfer) and the lowest singlet excited state of the heptamethine cyanine (i.e., S1—slow charge transfer), as the electron donor, to either a covalently linked C60 or C70, as the electron acceptor. Finally, charge transfer from photoexcited C60/C70 completes the charge‐transfer sequence. The slow internal conversion within the light‐harvesting heptamethine cyanine and the strong electronic coupling between the individual constituents are particularly beneficial to this process. The higher the better: We have realized the rarely found scenario of a charge transfer that commences in a higher‐energy excited state (see image), through the careful choice of electron donor and electron acceptor.</description><subject>Buckminsterfullerene</subject><subject>Charge transfer</subject><subject>Chemical Sciences</subject><subject>Chemistry</subject><subject>cyanines</subject><subject>Donors (electronic)</subject><subject>dyes/pigments</subject><subject>Electronics</subject><subject>Excitation</subject><subject>excited states</subject><subject>Fullerenes</subject><subject>Infrared</subject><subject>Joining</subject><subject>Lying</subject><subject>or physical chemistry</subject><subject>Organic chemistry</subject><subject>Theoretical and</subject><issn>0947-6539</issn><issn>1521-3765</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2010</creationdate><recordtype>article</recordtype><recordid>eNqFkc9v0zAYhi0EYqVw5YgicRgcUuzYie3jVGUrUEBiHRwtx_mceqTJsNOx8tfjKKNCHODkH3q-R6_9IvSc4AXBOHtjtrBbZDjuSUHoAzQjeUZSyov8IZphyXha5FSeoCchXGOMZUHpY3SS4aIgshAz9KW01hkH3ZBcDa51P_Xg-i7pbbJyzRZ8uj64rknKO-MGqJPLQQ8QkqFPNt41DfhkudW-gXTjdRdsPJe30RWeokdWtwGe3a9zdHVebpardP3p4u3ybJ2aXFCackNrWsX0rJYSjK1szXDFRUWNYJTkBasqAQwIEM0FyazIrcyF4URiLklG5-j15N3qVt14t9P-oHrt1Opsrca76BZSYHZLIns6sTe-_76HMKidCwbaVnfQ74PiTGIsWPyhOXr1T5JwzqWkQozSl3-h1_3ed_HNkSo4pSyjY8zFRBnfh-DBHrMSrMYe1dijOvYYB17ca_fVDuoj_ru4CMgJ-OFaOPxHp5ar8sOf8nSadWGAu-Os9t9UTMxz9fXjhfq8uXz3nvBzxekv-RC1wg</recordid><startdate>20100816</startdate><enddate>20100816</enddate><creator>Bouit, Pierre-Antoine</creator><creator>Spänig, Fabian</creator><creator>Kuzmanich, Gregory</creator><creator>Krokos, Evangelos</creator><creator>Oelsner, Christian</creator><creator>Garcia-Garibay, Miguel A.</creator><creator>Delgado, Juan Luis</creator><creator>Martín, Nazario</creator><creator>Guldi, Dirk M.</creator><general>WILEY-VCH Verlag</general><general>WILEY‐VCH Verlag</general><general>Wiley Subscription Services, Inc</general><general>Wiley-VCH Verlag</general><scope>BSCLL</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><scope>K9.</scope><scope>7X8</scope><scope>1XC</scope><scope>VOOES</scope><orcidid>https://orcid.org/0000-0002-0538-9276</orcidid></search><sort><creationdate>20100816</creationdate><title>Efficient Utilization of Higher-Lying Excited States to Trigger Charge-Transfer Events</title><author>Bouit, Pierre-Antoine ; 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In terms of optical and electrochemical characteristics, appreciable electronic coupling between both electroactive species is deduced. The latter also reflect the excited‐state features. To this end, time‐resolved, transient absorption measurements revealed that photoexcitation is followed by a sequence of charge‐transfer events which evolve from higher singlet excited states (i.e., S2—fast charge transfer) and the lowest singlet excited state of the heptamethine cyanine (i.e., S1—slow charge transfer), as the electron donor, to either a covalently linked C60 or C70, as the electron acceptor. Finally, charge transfer from photoexcited C60/C70 completes the charge‐transfer sequence. The slow internal conversion within the light‐harvesting heptamethine cyanine and the strong electronic coupling between the individual constituents are particularly beneficial to this process. 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subjects	Buckminsterfullerene Charge transfer Chemical Sciences Chemistry cyanines Donors (electronic) dyes/pigments Electronics Excitation excited states Fullerenes Infrared Joining Lying or physical chemistry Organic chemistry Theoretical and
title	Efficient Utilization of Higher-Lying Excited States to Trigger Charge-Transfer Events
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