TY - JOUR
T1 - How surface bonding and repulsive interactions cause phase transformations
T2 - Ordering of a prototype macrocyclic compound on Ag(111)
AU - Bischoff, Felix
AU - Seufert, Knud
AU - Auwärter, Willi
AU - Joshi, Sushobhan
AU - Vijayaraghavan, Saranyan
AU - Écija, David
AU - Diller, Katharina
AU - Papageorgiou, Anthoula C.
AU - Fischer, Sybille
AU - Allegretti, Francesco
AU - Duncan, David A.
AU - Klappenberger, Florian
AU - Blobner, Florian
AU - Han, Runyuan
AU - Barth, Johannes V.
PY - 2013/4/23
Y1 - 2013/4/23
N2 - We investigated the surface bonding and ordering of free-base porphine (2H-P), the parent compound of all porphyrins, on a smooth noble metal support. Our multitechnique investigation reveals a surprisingly rich and complex behavior, including intramolecular proton switching, repulsive intermolecular interactions, and density-driven phase transformations. For small concentrations, molecular-level observations using low-temperature scanning tunneling microscopy clearly show the operation of repulsive interactions between 2H-P molecules in direct contact with the employed Ag(111) surface, preventing the formation of islands. An increase of the molecular coverage results in a continuous decrease of the average intermolecular distance, correlated with multiple phase transformations: the system evolves from an isotropic, gas-like configuration via a fluid-like phase to a crystalline structure, which finally gives way to a disordered layer. Herein, considerable site-specific molecule-substrate interactions, favoring an exclusive adsorption on bridge positions of the Ag(111) lattice, play an important role. Accordingly, the 2D assembly of 2H-P/Ag(111) layers is dictated by the balance between adsorption energy maximization while retaining a single adsorption site counteracted by the repulsive molecule-molecule interactions. The long-range repulsion is associated with a charge redistribution at the 2H-P/Ag(111) interface comprising a partial filling of the lowest unoccupied molecular orbital, resulting in long-range electrostatic interactions between the adsorbates. Indeed, 2H-P molecules in the second layer that are electronically only weakly coupled to the Ag substrate show no repulsive behavior, but form dense-packed islands.
AB - We investigated the surface bonding and ordering of free-base porphine (2H-P), the parent compound of all porphyrins, on a smooth noble metal support. Our multitechnique investigation reveals a surprisingly rich and complex behavior, including intramolecular proton switching, repulsive intermolecular interactions, and density-driven phase transformations. For small concentrations, molecular-level observations using low-temperature scanning tunneling microscopy clearly show the operation of repulsive interactions between 2H-P molecules in direct contact with the employed Ag(111) surface, preventing the formation of islands. An increase of the molecular coverage results in a continuous decrease of the average intermolecular distance, correlated with multiple phase transformations: the system evolves from an isotropic, gas-like configuration via a fluid-like phase to a crystalline structure, which finally gives way to a disordered layer. Herein, considerable site-specific molecule-substrate interactions, favoring an exclusive adsorption on bridge positions of the Ag(111) lattice, play an important role. Accordingly, the 2D assembly of 2H-P/Ag(111) layers is dictated by the balance between adsorption energy maximization while retaining a single adsorption site counteracted by the repulsive molecule-molecule interactions. The long-range repulsion is associated with a charge redistribution at the 2H-P/Ag(111) interface comprising a partial filling of the lowest unoccupied molecular orbital, resulting in long-range electrostatic interactions between the adsorbates. Indeed, 2H-P molecules in the second layer that are electronically only weakly coupled to the Ag substrate show no repulsive behavior, but form dense-packed islands.
KW - charge transfer
KW - interface
KW - near-edge X-ray absorption fine structure
KW - photoelectron spectroscopy
KW - porphine
KW - porphyrin
KW - repulsion
KW - scanning tunneling microscopy
KW - self-assembly
UR - http://www.scopus.com/inward/record.url?scp=84876525938&partnerID=8YFLogxK
U2 - 10.1021/nn305487c
DO - 10.1021/nn305487c
M3 - Article
C2 - 23521075
AN - SCOPUS:84876525938
SN - 1936-0851
VL - 7
SP - 3139
EP - 3149
JO - ACS Nano
JF - ACS Nano
IS - 4
ER -