A Radical Anion Salt of 2,5‐Dimethyl‐<i>N,N</i>′‐dicyanoquinonediimine with Extremely High Electrical Conductivity

Aumüller, Alexander; Erk, Peter; Klebe, G.; Hünig, Siegfried; Schütz, J.U. von; Werner, H.

doi:10.1002/anie.198607401

Cited by 422 publications

(110 citation statements)

References 13 publications

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“…Firstly, an example is given here to illustrate the structural and electrical properties of molecular CT complexes. Such molecules as DM and DX in Figure 1, generally called R 1 ,R 2 -DCNQI, 34,35 form CT complexes with various kinds of metals to yield fine needle crystals M(R 1 ,R 2 -DCNQI) 2 (M = Li, Na, K, Ag, Cu, NH 4 , etc. ; Figure 2).…”

Section: Firstmentioning

confidence: 99%

Development of a Control Method for Conduction and Magnetism in Molecular Crystals

Naito

2016

Bulletin of the Chemical Society of Japan

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This study concerns development of a non-destructive method to control conduction and magnetism of molecular solids such as single crystals of charge-transfer complexes. The method is named “optical doping”, where appropriate irradiation is utilized under ambient conditions. Owing to this feature, it can be applied to a wide range of substances while measuring the properties during the control. In addition, the method adds unique conduction and magnetic properties to common insulators. Unlike other doping methods, optical doping only affects the properties and/or structures of the irradiated part of a sample while leaving the rest of the sample unchanged. There are two patterns in the optical doping. Irreversible optical doping produces junction-structures on the single molecular crystals, which exhibit characteristic behavior of semiconductor devices such as diodes and varistors. Reversible optical doping produces “giant photoconductors” and “photomagnetic conductors” by realizing unprecedented metallic photoconduction. In the latter case, localized spins are also excited to produce a Kondo system, where carriers and localized spins interact with each other. Not only the control of conduction and magnetism, the optical doping has realized the observation of physical properties in molecular crystals hardly observed under any thermodynamic condition.

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Section: Firstmentioning

confidence: 99%

Development of a Control Method for Conduction and Magnetism in Molecular Crystals

Naito

2016

Bulletin of the Chemical Society of Japan

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“…Charge-transfer complexes with the stoichiometry Cu(DCNQI)2, that incorporate the radical anion DCNQI, have been shown to possess metallic properties and in one instance conductivity increased with decreasing temperature reaching a maximum of 5 x 105Sm -1 at 3.5K (Aumuller, Erk, Klebe, Hunig, Von Schutz & Werner, 1986). These properties are largely the result of the planarity of the radical anion DCNQI molecule and its ability to form ¢r stacks in the solid state (Kato, Kobayashi & Kobayashi, 1989).…”

Section: N~c (I) (Ii)mentioning

confidence: 99%

Structure of 1,4-benzenedicyanamide dianion derivatives

Aquino¹,

Crutchley²,

Lee³

et al. 1993

Acta Crystallogr C

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“…This behavior is due to the interaction between the localized 3d-electron bands of the Cu ions and the p-electron conductive bands of DCNQI.[2] Therefore, the appropriate combination of donors and acceptors as molecular building blocks, which often form an electron-conducting solid, plays an important role in determining the electron-transport character of a molecular crystal.Molecules that form high-conductivity molecular solids, particularly organic acceptors, have been limited thus far to cyanoquinoid derivatives such as TCNQ [3] and DCNQI [4] and the metal complex [M(dmit) 2 ] (dmit = 1,3-dithiole-2-thioxo-4,5-dithiolato).[5] Molecular conductors with various electrondonor frameworks based on heterocyclic structures containing a chalcogen atom such as tetrathiafulvalene (TTF) [6] and tetramethyltetraselenofulvalene (TMTSF) [7] have also been realized, and studies are underway to discover a fundamental molecule with a stable electron-accepting framework to form molecular conductors with a desired transport behavior. Herein, we report a modifiable electron acceptor with 5,6,11,12-tetraazanaphthacene (TANC) as a new fundamental framework and the preparation of a high-conductivity crystal (1) from Cu I -TANC coordination polymers.…”

mentioning

confidence: 99%

“…The high-conductivity crystal 1, which has the composition [{Cu(TANC)}F 0.5 ] n , was obtained from the reaction between TANC and [Cu(MeCN) 4 ]BF 4 in MeOH/MeCN in the form of thin, plate-like, indigo-blue crystals. The presence of half an equivalent of nonstoichiometric F À ions was determined by X-ray photoelectron spectroscopy (XPS) measurements and quantitative chemical analysis for F À ions.…”

mentioning

confidence: 99%

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

et al. 2006

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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 3d-electron bands of the Cu ions and the p-electron conductive bands of DCNQI.[2] Therefore, the appropriate combination of donors and acceptors as molecular building blocks, which often form an electron-conducting solid, plays an important role in determining the electron-transport character of a molecular crystal.Molecules that form high-conductivity molecular solids, particularly organic acceptors, have been limited thus far to cyanoquinoid derivatives such as TCNQ [3] and DCNQI [4] and the metal complex [M(dmit) 2 ] (dmit = 1,3-dithiole-2-thioxo-4,5-dithiolato).[5] Molecular conductors with various electrondonor frameworks based on heterocyclic structures containing a chalcogen atom such as tetrathiafulvalene (TTF) [6] and tetramethyltetraselenofulvalene (TMTSF) [7] have also been realized, and studies are underway to discover a fundamental molecule with a stable electron-accepting framework to form molecular conductors with a desired transport behavior. Herein, we report a modifiable electron acceptor with 5,6,11,12-tetraazanaphthacene (TANC) as a new fundamental framework and the preparation of a high-conductivity crystal (1) from Cu I -TANC coordination polymers.TANC was prepared by modifying a synthetic procedure first reported by Hill.[8] The yellow precipitate obtained from the thermal condensation between o-phenylenediamine and oxamide contains 2,2'-bibenzimidazole and 5,11-dihydro-5,6,11,12-tetraazanaphthacene (FFV) in a 3:1 ratio. This mixture was oxidized with PbO 2 in MeCN to give brown crystals of TANC in 20 % yield. The cyclic voltammogram of TANC in MeCN exhibits two reversible one-step, oneelectron waves in the reverse sweep (E 1 1/2 = À0.20 and E 2 1/2 = À0.88 V vs Ag/AgCl), which means that TANC is a weaker electron acceptor than organic acceptors such as TCNQ and DCNQI that form high-conductivity materials. [9] Unfortunately, TANC cannot be employed as an organic semiconductor with n-type characteristics.The TANC radical anion can be isolated from an electron disproportionate reaction between FFV and TANC under basic conditions. This compound was obtained as a green precipitate under anaerobic conditions, which immediately turns gray upon exposure to air. The ESR spectrum of the precipitate exhibits a typical anisotropic peak (g ? = 2.011 and g k = 2.0091) that stabilizes at room temperature (see the Supporting Information).The high-conductivity crystal 1, which has the composition [{Cu(TANC)}F 0.5 ] n , was obtained from the reaction between TANC and [Cu(MeCN) 4 ]BF 4 in MeOH/MeCN in t...

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A Radical Anion Salt of 2,5‐Dimethyl‐N,N′‐dicyanoquinonediimine with Extremely High Electrical Conductivity

Cited by 422 publications

References 13 publications

Development of a Control Method for Conduction and Magnetism in Molecular Crystals

Development of a Control Method for Conduction and Magnetism in Molecular Crystals

Structure of 1,4-benzenedicyanamide dianion derivatives

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

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