Re-evaluating how charge transfer modifies the conformation of adsorbed molecules

P.J. Blowey; Simone Velari; L.A. Rochford; D.A. Duncan; D.A. Warr; T.-L. Lee; Alessandro De Vita; G Costantini; D.P. Woodruff

Re-evaluating how charge transfer modifies the conformation of adsorbed molecules

P.J. Blowey, Simone Velari, L.A. Rochford, D.A. Duncan, D.A. Warr, T.-L. Lee, Alessandro De Vita, G Costantini, D.P. Woodruff

Physics

University of Warwick

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

35 Citations (Scopus)

164 Downloads (Pure)

Abstract

The archetypal electron acceptor molecule, TCNQ, is generally believed to become bent into an inverted bowl shape upon adsorption on the coinage metal surfaces on which it becomes negatively charged. New quantitative experimental structural measurements show that this is not the case for TCNQ on Ag(111). DFT calculations show that the inclusion of dispersion force corrections reduces not only the molecule-substrate layer spacing but also the degree of predicted molecular bonding. However, complete agreement between experimentally-determined and theoretically-predicted structural parameters is only achieved with the inclusion of Ag adatoms into the molecular layer, which is also the energetically favoured configuration. The results highlight the need for both experimental and theoretical quantitative structural methods to reliably understand similar metal–organic interfaces and highlight the need to re-evaluate some previously-investigated systems.

Original language	English
Pages (from-to)	14984
Number of pages	9
Journal	Nanoscale
Volume	10
Publication status	Published - 27 Jul 2018

Access to Document

Re-evaluating how charge_BLOWEY_Accepted27July2018_GREEN AAMAccepted author manuscript, 1.82 MB

Cite this

@article{a6f2a41a6ed2444c863c44b333936bd7,

title = "Re-evaluating how charge transfer modifies the conformation of adsorbed molecules",

abstract = "The archetypal electron acceptor molecule, TCNQ, is generally believed to become bent into an inverted bowl shape upon adsorption on the coinage metal surfaces on which it becomes negatively charged. New quantitative experimental structural measurements show that this is not the case for TCNQ on Ag(111). DFT calculations show that the inclusion of dispersion force corrections reduces not only the molecule-substrate layer spacing but also the degree of predicted molecular bonding. However, complete agreement between experimentally-determined and theoretically-predicted structural parameters is only achieved with the inclusion of Ag adatoms into the molecular layer, which is also the energetically favoured configuration. The results highlight the need for both experimental and theoretical quantitative structural methods to reliably understand similar metal–organic interfaces and highlight the need to re-evaluate some previously-investigated systems.",

author = "P.J. Blowey and Simone Velari and L.A. Rochford and D.A. Duncan and D.A. Warr and T.-L. Lee and {De Vita}, Alessandro and G Costantini and D.P. Woodruff",

year = "2018",

month = jul,

day = "27",

language = "English",

volume = "10",

pages = "14984",

journal = "Nanoscale",

issn = "2040-3364",

publisher = "Royal Society of Chemistry",

}

TY - JOUR

T1 - Re-evaluating how charge transfer modifies the conformation of adsorbed molecules

AU - Blowey, P.J.

AU - Velari, Simone

AU - Rochford, L.A.

AU - Duncan, D.A.

AU - Warr, D.A.

AU - Lee, T.-L.

AU - De Vita, Alessandro

AU - Costantini, G

AU - Woodruff, D.P.

PY - 2018/7/27

Y1 - 2018/7/27

N2 - The archetypal electron acceptor molecule, TCNQ, is generally believed to become bent into an inverted bowl shape upon adsorption on the coinage metal surfaces on which it becomes negatively charged. New quantitative experimental structural measurements show that this is not the case for TCNQ on Ag(111). DFT calculations show that the inclusion of dispersion force corrections reduces not only the molecule-substrate layer spacing but also the degree of predicted molecular bonding. However, complete agreement between experimentally-determined and theoretically-predicted structural parameters is only achieved with the inclusion of Ag adatoms into the molecular layer, which is also the energetically favoured configuration. The results highlight the need for both experimental and theoretical quantitative structural methods to reliably understand similar metal–organic interfaces and highlight the need to re-evaluate some previously-investigated systems.

AB - The archetypal electron acceptor molecule, TCNQ, is generally believed to become bent into an inverted bowl shape upon adsorption on the coinage metal surfaces on which it becomes negatively charged. New quantitative experimental structural measurements show that this is not the case for TCNQ on Ag(111). DFT calculations show that the inclusion of dispersion force corrections reduces not only the molecule-substrate layer spacing but also the degree of predicted molecular bonding. However, complete agreement between experimentally-determined and theoretically-predicted structural parameters is only achieved with the inclusion of Ag adatoms into the molecular layer, which is also the energetically favoured configuration. The results highlight the need for both experimental and theoretical quantitative structural methods to reliably understand similar metal–organic interfaces and highlight the need to re-evaluate some previously-investigated systems.

M3 - Article

SN - 2040-3364

VL - 10

SP - 14984

JO - Nanoscale

JF - Nanoscale

ER -

Re-evaluating how charge transfer modifies the conformation of adsorbed molecules

Abstract

Access to Document

Fingerprint

Cite this