Your search keyword '"Jirasek, M."' showing total 4 results

1. A Peierls Transition in Long Polymethine Molecular Wires: Evolution of Molecular Geometry and Single-Molecule Conductance.

Author

Xu W, Leary E, Sangtarash S, Jirasek M, González MT, Christensen KE, Abellán Vicente L, Agraït N, Higgins SJ, Nichols RJ, Lambert CJ, and Anderson HL

Abstract

Molecules capable of mediating charge transport over several nanometers with minimal decay in conductance have fundamental and technological implications. Polymethine cyanine dyes are fascinating molecular wires because up to a critical length, they have no bond-length alternation (BLA) and their electronic structure resembles a one-dimensional free-electron gas. Beyond this threshold, they undergo a symmetry-breaking Peierls transition, which increases the HOMO-LUMO gap. We have investigated cationic cyanines with central polymethine chains of 5-13 carbon atoms ( Cy3 + -Cy11 + ). The absorption spectra and crystal structures show that symmetry breaking is sensitive to the polarity of the medium and the size of the counterion. X-ray crystallography reveals that Cy9·PF 6 and Cy11·B(C 6 F 5 ) 4 are Peierls distorted, with high BLA at one end of the π-system, away from the partially delocalized positive charge. This pattern of BLA distribution resembles that of solitons in polyacetylene. The single-molecule conductance is essentially independent of molecular length for the polymethine salts of Cy3 + -Cy11 + with the large B(C 6 F 5 ) 4 - counterion, but with the PF 6 - counterion, the conductance decreases for the longer molecules, Cy7 + -Cy11 + , because this smaller anion polarizes the π-system, inducing a symmetry-breaking transition. At higher bias (0.9 V), the conductance of the shorter chains, Cy3 + -Cy7 + , increases with length (negative attenuation factor, β = -1.6 nm -1 ), but the conductance still drops in Cy9 + and Cy11 + with the small polarizing PF 6 - counteranion.

Published

2021

2. Allosteric Cooperativity and Template-Directed Synthesis with Stacked Ligands in Porphyrin Nanorings.

Author

Bols PS, Rickhaus M, Tejerina L, Gotfredsen H, Eriksen K, Jirasek M, and Anderson HL

Abstract

The link between allosteric cooperativity and template-directed synthesis has been investigated by studying complexes in which two oligopyridine ligands bind inside a zinc porphyrin nanoring in a stacked arrangement. The binding of a 6-porphyrin nanoring to two tridentate ligands (with s -triazine or benzene cores) occurs with high negative allosteric cooperativity (α ≈ 10 -3 -10 -4 ). Formation constants for 1:1 and 1:2 complexes were determined by UV-vis-NIR denaturation titration, using pyridine as a competing ligand, and cooperativity factors were confirmed by NMR spectroscopy. The rate constants for formation of the 1:1 and 1:2 complexes are approximately equal, and the negative cooperativity can be attributed to faster dissociation of the 1:2 complex. These tridentate ligands are not effective templates for directing the synthesis of the 6-porphyrin nanoring, in keeping with their negative cooperativity of binding. In contrast, the binding of a 12-porphyrin nanoring to two hexadentate ligands occurs with high positive allosteric cooperativity (α > 40), and the ligand is an effective Vernier template for directing the synthesis of the 12-porphyrin nanoring. This stacked Vernier template approach creates the product in an open circular conformation, which is advantageous for preparing macrocycles that do not easily adopt a figure-of-eight geometry.

Published

2020

3. Tuning the Circumference of Six-Porphyrin Nanorings.

Author

Haver R, Tejerina L, Jiang HW, Rickhaus M, Jirasek M, Grübner I, Eggimann HJ, Herz LM, and Anderson HL

Abstract

Most macrocycles are made from a simple repeat unit, resulting in high symmetry. Breaking this symmetry allows fine-tuning of the circumference, providing better control of the host-guest behavior and electronic structure. Here, we present the template-directed synthesis of two unsymmetrical cyclic porphyrin hexamers with both ethyne (C2) and butadiyne (C4) links, and we compare these nanorings with the symmetrical analogues with six ethyne or six butadiyne links. Inserting two extra carbon atoms into the smaller nanoring causes a spectacular change in binding behavior: the template affinity increases by a factor of 3 × 10 9 , to a value of ca. 10 38 M -1 , and the mean effective molarity is ca. 830 M. In contrast, removing two carbon atoms from the largest nanoring results in almost no change in its template-affinity. The strain in these nanorings is 90-130 kJ mol -1 , as estimated both from DFT calculation of homodesmotic reactions and from comparing template affinities of linear and cyclic oligomers. Breaking the symmetry has little effect on the absorption and fluorescence behavior of the nanorings: the low radiative rates that are characteristic of a circular delocalized S 1 excited state are preserved in the low-symmetry macrocycles.

Published

2019

4. Single-Acetylene Linked Porphyrin Nanorings.

Author

Rickhaus M, Vargas Jentzsch A, Tejerina L, Grübner I, Jirasek M, Claridge TDW, and Anderson HL

Abstract

The synthesis of ethyne-linked porphyrin nanorings has been achieved by template-directed Sonogashira coupling. The cyclic hexamer and octamer are predicted by density functional theory to adopt low symmetry conformations, due to dihedral twists between neighboring porphyrin units, but their symmetries are effectively D 6h and D 8h , respectively, in solution by 1 H NMR. The fluorescence spectra indicate that the singlet excited states of these nanorings are highly delocalized.

Published

2017