Dipole driven bonding schemes of quinonoid zwitterions on surfaces

Donna A. Kunkel; Scott Simpson; Justin Nitz; Geoffrey A. Rojas; Eva Zurek; Lucie Routaboul; Bernard Doudin; Pierre Braunstein; Peter A. Dowben; Axel Enders

doi:10.1039/c2cc32462h

Dipole driven bonding schemes of quinonoid zwitterions on surfaces

Donna A. Kunkel, Scott Simpson, Justin Nitz, Geoffrey A. Rojas, Eva Zurek, Lucie Routaboul, Bernard Doudin, Pierre Braunstein, Peter A. Dowben, Axel Enders

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Abstract

The permanent dipole of quinonoid zwitterions changes significantly when the molecules adsorb on Ag(111) and Cu(111) surfaces. STM reveals that sub-monolayers of adsorbed molecules can exhibit parallel dipole alignment on Ag(111), in strong contrast with the antiparallel ordering prevailing in the crystalline state and retrieved on Cu(111) surfaces, which minimizes the dipoles electrostatic interaction energy. DFT shows that the rearrangement of electron density upon adsorption is a result of donation from the molecular HOMO to the surface, and back donation to the LUMO with a concomitant charge transfer that effectively reduces the overall charge dipole.

Original language	English (US)
Pages (from-to)	7143-7145
Number of pages	3
Journal	Chemical Communications
Volume	48
Issue number	57
DOIs	https://doi.org/10.1039/c2cc32462h
State	Published - Jun 20 2012

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abstract = "The permanent dipole of quinonoid zwitterions changes significantly when the molecules adsorb on Ag(111) and Cu(111) surfaces. STM reveals that sub-monolayers of adsorbed molecules can exhibit parallel dipole alignment on Ag(111), in strong contrast with the antiparallel ordering prevailing in the crystalline state and retrieved on Cu(111) surfaces, which minimizes the dipoles electrostatic interaction energy. DFT shows that the rearrangement of electron density upon adsorption is a result of donation from the molecular HOMO to the surface, and back donation to the LUMO with a concomitant charge transfer that effectively reduces the overall charge dipole.",

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AU - Kunkel, Donna A.

AU - Simpson, Scott

AU - Nitz, Justin

AU - Rojas, Geoffrey A.

AU - Zurek, Eva

AU - Routaboul, Lucie

AU - Doudin, Bernard

AU - Braunstein, Pierre

AU - Dowben, Peter A.

AU - Enders, Axel

PY - 2012/6/20

Y1 - 2012/6/20

N2 - The permanent dipole of quinonoid zwitterions changes significantly when the molecules adsorb on Ag(111) and Cu(111) surfaces. STM reveals that sub-monolayers of adsorbed molecules can exhibit parallel dipole alignment on Ag(111), in strong contrast with the antiparallel ordering prevailing in the crystalline state and retrieved on Cu(111) surfaces, which minimizes the dipoles electrostatic interaction energy. DFT shows that the rearrangement of electron density upon adsorption is a result of donation from the molecular HOMO to the surface, and back donation to the LUMO with a concomitant charge transfer that effectively reduces the overall charge dipole.

AB - The permanent dipole of quinonoid zwitterions changes significantly when the molecules adsorb on Ag(111) and Cu(111) surfaces. STM reveals that sub-monolayers of adsorbed molecules can exhibit parallel dipole alignment on Ag(111), in strong contrast with the antiparallel ordering prevailing in the crystalline state and retrieved on Cu(111) surfaces, which minimizes the dipoles electrostatic interaction energy. DFT shows that the rearrangement of electron density upon adsorption is a result of donation from the molecular HOMO to the surface, and back donation to the LUMO with a concomitant charge transfer that effectively reduces the overall charge dipole.

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Dipole driven bonding schemes of quinonoid zwitterions on surfaces

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