A High‐Conductivity Crystal Containing a Copper(I) Coordination Polymer Bridged by the Organic Acceptor TANC

Abstract: Artificial conductors constructed from molecular building blocks can replicate unique low-dimensional electron-transport phenomena depending on the nature of their molecular components.[1] For example, Cu(DCNQI) 2 (DCNQI = N,N'-dicyanoquinodiimine) systems formed from coordination polymers containing alternating 3D linkages between Cu ion donors and organic DCNQI acceptors exhibit an interesting metal-insulator (M-I) transition under high pressure. This behavior is due to the interaction between the localized … Show more

“…N ‐Heteroacenes, which consist of electron‐deficient imino‐ N atoms in linearly π‐conjugated polycyclic oligoacene framework, are well‐known as electron acceptor and n ‐type organic semiconductors . We have previously reported 5,6,11,12‐tetraazanaphtacene (TANC)‐based liquid‐crystalline (LC) materials, field‐effect transistor in thin films, and Cu‐coordinated molecules in single crystal ,. Among them, LC TANC derivatives self‐organized various superstructures such as 1D columnar LC and 2D layered smectic LC phases through various interactions such as π‐π interaction, hydrophobic interaction, and nanosegregation .…”

Dipole‐Driven Self‐Organization of Liquid‐Crystalline N‐Heteroacene Derivatives Showing Redox‐Properties

“…N ‐Heteroacenes, which consist of electron‐deficient imino‐ N atoms in linearly π‐conjugated polycyclic oligoacene framework, are well‐known as electron acceptor and n ‐type organic semiconductors . We have previously reported 5,6,11,12‐tetraazanaphtacene (TANC)‐based liquid‐crystalline (LC) materials, field‐effect transistor in thin films, and Cu‐coordinated molecules in single crystal ,. Among them, LC TANC derivatives self‐organized various superstructures such as 1D columnar LC and 2D layered smectic LC phases through various interactions such as π‐π interaction, hydrophobic interaction, and nanosegregation .…”

Dipole‐Driven Self‐Organization of Liquid‐Crystalline N‐Heteroacene Derivatives Showing Redox‐Properties

“…No matter how promising the characteristics of pentacene are, they are not sufficient for realizing practical p–n junction devices such as solar cells because pentacene, and other unsubstituted acenes such as naphthacene (tetracene), are mostly p-type (donor) materials and it is not easy to switch the polarity of these molecules. To make favorable pairs with these p-type aromatic hydrocarbons, a number of complementary n-type (acceptor) compounds have been synthesized by the introduction of elements of higher electronegativities such as halogens and nitrogen to their backbones [ 7 , 8 , 9 , 10 , 11 ]. In particular, molecules with nitrogen-containing heterocycles are attracting recent interest as non-fullerene acceptor molecules for the application of organic solar cells and as high mobility n-type organic semiconductors [ 12 ].…”

Interface Structures and Electronic States of Epitaxial Tetraazanaphthacene on Single-Crystal Pentacene

“…Crystal engineering of coordination polymers attracts increased attention in the field of materials science because of their exceptional chemical and physical properties, such as magnetic [1][2][3] and conductive [4][5][6][7][8][9][10][11][12][13][14][15][16][17], dielectric [18][19][20], gas-absorbing [21][22][23], and catalytic properties [24][25][26][27]. In particular, mixed-valence coordination polymers have attracted considerable interest as a new class of functional materials because of their unique infinite structures and electronic states formed by the combination of different metal ions having versatile coordination architectures and a variety of organic bridging ligands.…”

Synthesis, Crystal Structure, and Electroconducting Properties of a 1D Mixed-Valence Cu(I)–Cu(II) Coordination Polymer with a Dicyclohexyl Dithiocarbamate Ligand