Effect of Orientation of the Peptide-Bridge Dipole Moment on the Properties of Fullerene–Peptide–Radical Systems

Abstract: We synthesized two series of compounds in which a nitroxide radical and a fullerene C 60 moiety were kept separated by a 3 10 -helical peptide bridge containing two intramolecular CO···H−N hydrogen bonds. The direction of the resulting molecular dipole moment could be reversed by switching the position of fullerene and nitroxide with respect to the peptide nitrogen and carbon termini. The resulting fullerene−peptide−radical systems were compared to the behaviors of otherwise identical peptides but lacking eit… Show more

“…For example, different ET (or electron‐transport) rates have been found for opposite orientations of the peptides in SAMs; similar effects were observed for ET in freely diffusing donor–peptide–acceptor systems . Thermodynamics, however, could also be responsible for making ET rates different: as a matter of fact, we already showed that an oriented peptide dipole moment affects significantly the redox potentials of electroactive groups and gold clusters . For molecules in solution, as opposed to the concept of dyads, in which two moieties are separated by a spacer, we concluded that moieties separated by Aib peptides must be described also by stressing the orientation of the bridge, because its dipole moment is capable of tuning the system's physicochemical properties (not just electrochemistry) significantly .…”

“…Thermodynamics, however, could also be responsible for making ET rates different: as a matter of fact, we already showed that an oriented peptide dipole moment affects significantly the redox potentials of electroactive groups and gold clusters . For molecules in solution, as opposed to the concept of dyads, in which two moieties are separated by a spacer, we concluded that moieties separated by Aib peptides must be described also by stressing the orientation of the bridge, because its dipole moment is capable of tuning the system's physicochemical properties (not just electrochemistry) significantly . A final mention is about the important effect of oriented dipole moments on the metal work function and associated applications.…”

Dipole Moment Effect on the Electrochemical Desorption of Self‐Assembled Monolayers of 3₁₀‐Helicogenic Peptides on Gold

“…For example, different ET (or electron‐transport) rates have been found for opposite orientations of the peptides in SAMs; similar effects were observed for ET in freely diffusing donor–peptide–acceptor systems . Thermodynamics, however, could also be responsible for making ET rates different: as a matter of fact, we already showed that an oriented peptide dipole moment affects significantly the redox potentials of electroactive groups and gold clusters . For molecules in solution, as opposed to the concept of dyads, in which two moieties are separated by a spacer, we concluded that moieties separated by Aib peptides must be described also by stressing the orientation of the bridge, because its dipole moment is capable of tuning the system's physicochemical properties (not just electrochemistry) significantly .…”

“…Thermodynamics, however, could also be responsible for making ET rates different: as a matter of fact, we already showed that an oriented peptide dipole moment affects significantly the redox potentials of electroactive groups and gold clusters . For molecules in solution, as opposed to the concept of dyads, in which two moieties are separated by a spacer, we concluded that moieties separated by Aib peptides must be described also by stressing the orientation of the bridge, because its dipole moment is capable of tuning the system's physicochemical properties (not just electrochemistry) significantly . A final mention is about the important effect of oriented dipole moments on the metal work function and associated applications.…”

Dipole Moment Effect on the Electrochemical Desorption of Self‐Assembled Monolayers of 3₁₀‐Helicogenic Peptides on Gold

“…[28][29][30][31] In synthetic polypeptide helices, the intrinsic dipoles rectify the directionality of CT. [32][33][34][35][36][37] The broadband gap [or highest occupied molecular orbital (HOMO)-lowest unoccupied molecular orbital (LUMO) gap] of proteins, however, along with the inability to inject charges in them without chemically cleaving their backbones, [38][39][40] considerably limits their utility as electronic materials. Proteins and polypeptides (composed of native α-amino acids and their derivatives) mediate ET solely via tunneling, the efficiency of which is limited to about 2 nm.…”

Bioinspired molecular electrets: bottom-up approach to energy materials and applications

“…When the structures with opposing dipole direction are not completely symmetrical, the differences in the electronic coupling can prevail over the dipole-induced effect for relatively large −ΔG CT (0) [125]. Since the beginning of the 21 st century, studies of dipole effects on CT have focused on systems comprising polypeptide helices [12,95,99,[126][127][128][129][130][131][132][133][134][135][136][137][138][139][140][141]. Donor-bridge-acceptor (DBA) constructs, where the bridge is a helix, allow for testing dipole-induced charge-transfer rectification, i.e.…”

“…the difference between the rates of ET along the dipole vs. ET against the dipole [137]. Self-assembled monolayers (SAMs) of polypeptide helices on gold surfaces show similar dipole-induced rectification of interfacial CT [95], i.e.…”

Bioinspired approach toward molecular electrets: synthetic proteome for materials