EP1896388A2

EP1896388A2 - Oligo-tetracenes, production and use thereof

Info

Publication number: EP1896388A2
Application number: EP06762105A
Authority: EP
Inventors: Matthias Rehahn; Michael Roth; Heinz Von Seggern; Roland Schmechel; Marcus Ahles
Original assignee: Technische Universitaet Darmstadt
Current assignee: Dritte Patentportfolio Beteiligungs GmbH and Co KG
Priority date: 2005-06-25
Filing date: 2006-06-21
Publication date: 2008-03-12
Also published as: KR101156239B1; KR20080027274A; US20080214838A1; CN101203471A; JP5171617B2; WO2007000268A2; DE102005029574A1; WO2007000268A3; WO2007000268B1; CA2610816C; CA2610816A1; US8293957B2; JP2008546728A; KR20120036376A

Abstract

The invention relates to oligo-tetracenes of formula (I) which are either unsubstituted or carry one or several substituents (R and R'), which are selected from the group which consists of halogen, CN, alkyl- or alkoxy radicals having 1 - 18 carbon atoms, aryl radicals having up to 12 carbon atoms which can also contain one or several heteroatoms and/or fluorinated or perfluorinated alkyl- or alkoxy radicals having 1 - 18 carbon atoms, wherein n is a whole number between 1 - 20, preferably 1 - 6, more preferably 1 or 2 and X represents an alklyene group having 1 6 carbon atoms, a hydrocarbon chain having one or several conjugated dual compounds, an aryl group or a system consisting of one or several condensed aromatic rings, for a single compound. In the inventive oligotetracenes, one or several of the six-atomic, condensed, aromatic rings can be replaced by a five-atomic ring which can contain a heteroatom. The invention also relates to a method for producing the known oligo-tetracenes and to the used thereof as a semi-conductor in organic field effect transistors (OFET), organic light-emitting diodes (OLEDs), sensors and organic solar cells.

Description

Oligo-Tetracenes, their preparation and their use

The invention relates to substituted and unsubstituted oligo-tetracenes, their preparation and their use as semiconductors in organic field-effect transistors (OFETS), organic light-emitting diodes (OLEDs), sensors, organic solar cells and in other fields of optics and electronics.

It is well known that the visualization, processing and storage of information are crucial foundations for a society dominated by expertise. All the tools that are required for such procedures must be constantly miniaturized, improved and offered cheaper. With this constant development of the information technology is connected an increasing employment of organic instead of inorganic materials. Organic materials are usually cheaper and easier to process. Moreover, the ever increasing number of publications and patents in the field of information technology shows that, contrary to the widely held belief, organic materials perform the same functions as inorganic materials or even additional functions in the generation, transport and conversion of electrical charges or electromagnetic radiation can. Even the problems associated with the lower stability of organic materials under the harsh conditions of manufacture and application have now been resolved step by step. Many organic materials can already be used today as components in light-emitting diodes, solar cells, in optical switches and thin-film transistors. Organic field-effect transistors (OFETs) allow the use of inexpensive, lightweight and flexible plastic materials as an alternative to glass in liquid crystal displays and displays equipped with light emitting diodes. The best-studied and semiconductive organic material in organic field-effect transistors is α-sexithienyl. Unfortunately, field effect mobility and on / off ratio are still insufficient for most practical applications of this material: for example, the typical field effect mobility of α-sexithienyl based OFETs is about 0.03 cm ² / V xs and as on / off ratio approximately 10 ⁶ , while in amorphous hydrogenated silicone the field effect mobility is greater than 0.5 cm ² Λ / xs and the on / off ratio is greater than 10 ⁸ . Nevertheless, considerable improvements have been achieved with organic semiconductors: a very promising substance is pentacene. Recently, pentacene-containing organic field-effect transistors (OFETs) have been reported to achieve field-effect mobility above 0.5 cm ² / V xs and an on / off ratio greater than 10 ⁸ (FIG. 1). Both results are comparable to those of hydrogenated amorphous silicones and are the best currently available for organic field-effect transistors. However, pentacenes have the considerable disadvantage that they are chemically unstable, readily oxidize and disproportionate, and undergo cycloaddition reactions (2-4). Pentacene must therefore be cleaned and handled with great care under inert conditions. In addition, the chemical derivatization of pentacene is very difficult because of its sensitivity and does not allow the use of conventional aromatic substitution reactions. Therefore, every derivative, if it is accessible at all, requires an individual synthesis. Systematic investigations and optimizations of pentacene derivatives for organic field effect transistors (OFETs) are therefore hardly possible.

It was therefore an object to develop substances which have the good electrical properties of pentacene, but are more accessible and easier to clean and also can be used in the usual production process for organic semiconductors. In order to be as efficient as possible in solving this task, key parameters responsible for the excellent properties of pentacene-based OFETs had to be identified. Recently, there has also been reported an association of the high mobility of the high molecular weight charge carriers in pentacene films. Furthermore Seems to crystallize pentacene in molecular arrays in which the individual fused aromatic ring systems adopt mutual positions and orientations, which are almost ideal for the movement of the charge carriers over longer distances. Finally, the highest occupied molecular orbital (HOMO) level (5.07eV) is also well matched to gold, which is commonly used as the material for aodes and cathodes. On the other hand, tetracene, which consists of four rather than five condensed benzene rings, is much more chemically stable, but exhibits much worse semiconductor properties. OFETs based on polycrystalline tetracenes generally have field effect mobilities of 0.05 cm ² / V xs and an on / off ratio of about 10 ⁶ . However, tetracene has an equally well delocalized π-electron system that is very similar to that of the pentacene. It is therefore not easy to understand the enormous differences between the semiconducting properties of both substances. One explanation might be seen in the less advantageous or less perfect molecular orientation in tetracene thin films and deeper HOMO sheets, which makes it difficult to introduce holes from a metal electrode. The HOMO level of polycrystalline tetracene is about 5.4 eV (5), which means that it is not possible to perform an obstacle-free injection of holes of metal electrodes. Therefore, to test this working hypothesis, several strategies have been developed that allow for an increase or perhaps a change in the molecular arrangement in thin layers of tetracene without losing their chemical stability. A higher molecular order could also allow the number of exchange reactions between the molecules and an increase in the HOMO.

One way to achieve this goal might be to extend the tetracene, because one crucial difference between the tetracene and the pentacene is that the tetracene is shorter. This could be the cause of lower order and less favorable transistor properties. If this assumption is correct, one solution to the problem might be to increase the length of the tetracene molecule increase without impairing its chemical and semiconducting properties. The attachment of hydrocarbons or simple aromatic groups to the longitudinal axis of the tetracenes is probably not the best way to do so because it may result in a reduction of the conductive properties and disturbances of the advantageous arrangement of the tetracene molecules associated with an increase in the sensitivity of the molecules to oxidation. A conceptually simpler, but nevertheless promising, alternative could be to connect two tetracene molecules together to produce a significantly larger molecule length. This strategy would also avoid introducing any deviant chemical substances into the system and, because of the angle at which the two interconnected tetracene molecules are at least in the dissolved state, then perhaps no significant changes in stability would occur during production or purification. On the other hand, in the solid state, after deposition on a thin layer, some planarization may be expected, which may consist in even improved mobility and lower ionization energy over the original tetracene

Of course, these considerations seem somewhat simple, because so much change in the shape of the tetracene can have significant and unexpected consequences for the arrangement of the molecules, which also affect the mobility of the charges. On the other hand, there was already a certain chance for a considerable improvement of the transistor properties. Therefore, the idea for the development of test devices from ditetracenes was developed. It also shows how these new organic molecules can be made and what their properties are in organic field-effect transistors. The invention therefore relates to the tetracenes of the formula I. which are either unsubstituted or carry one or more substituents R and R 'selected from the group consisting of

Halogen,

CN,

Alkyl or alkoxy radicals having 1 to 18 carbon atoms,

Aryl radicals with up to 10 carbon atoms, which are also one or more

May contain heteroatoms and / or fluorinated or perfluorinated alkyl or alkoxy radicals having 1 to 18

Carbon atoms

where n is an integer from 1 to 20, preferably from 1 to 6, very particularly preferably 1 or 2, and X is a single bond, an alkylene group having 1-6 carbon atoms, a hydrocarbon chain having one or more conjugated double bonds, an aryl group or a system consisting of a plurality of fused, aromatic rings. In the oligotetracene of the present invention, one or more of the six-atom condensed aromatic rings may be replaced by a five-atom ring which may also contain a heteroatom.

In the oligotetracene of the present invention, the bridging aryl group may be one or more phenyl rings unsubstituted or containing 1-18 carbon atoms, or a double unsaturated heteroatom containing five-membered ring or a ferrocenylene unit.

A particularly preferred oligotetracene is the 2- (tetracen-2-yl) tetracene of formula II

in which R and R 'can be hydrogen or have the meanings given for formula I.

Another preferred dietetracen corresponds to the formula III

in which R and R 'may have hydrogen or the meanings given for formula I.

The above-mentioned oligo-tetracenes and ditetracenes are prepared by an oligomerization or dimerization of the corresponding tetracenes by, for example, a coupling reaction controlled by transition metals. Typically, these processes require halogenated starting materials. Thus, a tetracene derivative containing a chlorine or bromine atom in the 2-position was needed. Direct selective bromination of the tetracene leading to such a derivative is not possible. Therefore, a new process for the preparation of 2-bromotetracene has been developed. In this case, one in any position, in particular in the 1-, 2- or 4-position, mono- or poly-substituted, preferably halogenated, in particular brominated tetracene oligomerized. Particularly preferred is the oligomerization of a substituted in the 2-position tetracene using an organometallic compound in a cross Coupling reaction (eg Suzuki or Stille reaction). Subsequently, the product obtained is then purified by vacuum sublimation.

The synthesis of a 2-position brominated tetracene is exemplified by the following:

In a first step, α-chloro-o-xylene 1 was subjected to pyrolysis at about 800 ^° C. and 0.5 mbar. Benzocyclobutene 2 was obtained in 45% yield. Its selective bromination was carried out by treating benzocyclobutene dissolved in acetic acid with a mixture of bromine and iodine at room temperature. This gave 4-bromobenzocyclobutene 3. By dissolving in toluene and heating with a small molar excess of 1, 4-dihydro-1, 4-epoxynaphthalin 4 to 220 ⁰ C for 20 hours this resulted in 80% yield a pure endo / exo Mixture of the Diels-Alder adduct 5, which is a colorless crystalline material. This was refluxed in acetic anhydride in the presence of concentrated hydrochloric acid to form the 9-bromo-6,11-dihydrotetracene 6. The Yamamoto coupling then led to 2- (5,12-dihydrotetracene-2-yl) -5,12-dihydrotetracene 7. The coupling reaction was carried out with about 80% yield in a mixture of Dimethylformamide and Tolyol carried out at 80 ⁰ C, with bis (cyclooctadienyl) nickel (O) in stoichiometric. Quantities was used. After recrystallization from o-dichlorobenzene, dehydrogenation of 7 was achieved by treatment with 2,3-dichloro-5,6-dicyano-p-benzoquinone (DDQ) in boiling o-xylene. After purification by repeated vacuum sublimation, orange-red crystals of 2- (tetracen-2-yl) tetracene 8 were recovered in 75% yield. All intermediates were characterized by ¹ H and ¹³ C NMR spectroscopy and mass spectroscopy. Compound 8 was characterized by UV-vis spectroscopy.

Fig. 1A shows a representative spectrum taken in a thin layer of 8 on a quartz wafer. FIG. 1B additionally shows the photoluminescence spectrum of FIG. 8 when excited with light having a wavelength of λ = 345 nm.

In general, one can say that the synthesis of the oligo- and ditetracenes according to the invention can be carried out in particular successfully, when oligomerizing or dimerizing a two-position halogenated, preferably brominated tetracene. Particularly suitable for this purpose are the dimerizations, e.g. with the help of organoboron compounds in a cross-coupling reaction, which is widely known as the Suzuki or Stille reaction in chemistry.

The ditetracenes described above can be advantageously used as semiconductors in organic field-effect transistors (OFETs). This is conveniently done e.g. follow these steps:

To use the erfindungemäßen ditetracenes which had been purified by repeated kuumsublimation Vak-, devices have been prepared in which these materials were used as s semiconductor in ^OFETs'. The device described in FIG. 2 was used. The OFET transistors according to the invention were covered with heavily doped n-type silicone materials (3-5 ohm cm resistivity), nm with a thermally generated SiO ₂ with a thickness of about the 230th A thin layer of chromium was deposited on the entire surface and then a 50nm thick gold layer attached. The gold electrodes were photolithographically structured. They are arranged interdigitally with channel lengths of L = 7 μm and a channel width of W = 20 cm. The design of the transistor electrodes is also shown in FIG.

In some cases, the SiO 2 surface was treated with a silane coupling reagent to improve the homogeneity of the organic film and substrate coverage. The substrates thus prepared were introduced directly into a vacuum chamber and the influence of ambient air was avoided. The ditetracene 8 was x 10 ^-6 mbar thermally deposited at a pressure of 1 to structures with prepared at room temperature or at 140 ⁰ C. Electrical characterization was performed using an HP 4155 A semiconductor inert property analyzer. On standard devices with an untreated SiO ₂ surface, the organic field-effect transistors produced with ditetracene as semiconductors were tested for their characteristic properties. The representative properties are shown in FIG.

The curves show the characteristic properties of monopolar field effect transistors with good saturation property.

The electrical transfer characteristics shown in Fig. 4 were used for further evaluation.

At saturation, the current can be described by the Shockley equation:

W μ _h (v ₀ -vJ ^! In this formula means

C = capacitance of the insulator L = channel length M _h = charge carrier mobility (holes) Gate voltage VTH = threshold voltage W = channel width

The method according to the invention thus demonstrates an efficient synthesis method which can be used in a very general manner, according to which bis- (tetracenyl aromatics) can be prepared. These compounds are suitable for highly efficient organic field-effect transistors with increased charge mobility. The charge mobility reaches in some derivatives values of up to μh = O, 5 cm ² / V x s. They can also be used for organic light-emitting diodes (OLEDs), sensors and organic solar cells.

References:

(1) CD. Dimitrakopoulos and Patrick R.L. Malenfant, Adv.Mater.2002,14, No.2, January 2001

(2-4) J.E. Northrup and M.L. Chabinyc, Phys.Rev. 68, 041202 (2003) D.V.

Lang, X. Chi, T. Siegrist, A.M. Sergent, A.R. Ramirez, Phys.Rev. Lett.93 (7) Art. 076601 Aug 15, 2004

Ch. Pannemann, T. Diekmann and U. Hillerungmann, J. Mater. Res., Vol. 19, No. 7, July 2004.

(5) Electronic Processes in Organic Crystals and Polymers by Martin Pope; Charles E. Swenberg, Oxford Univ. Pr., June 1, 1982

Claims

claims:

1. Oligo-tetracene of the formula

characterized in that it is either unsubstituted or carries one or more substituents R and R 'selected from the group consisting of

halogen

CN

Alkyl or alkoxy radicals having 1 to 18 carbon atoms

Aryl radicals having up to 12 carbon atoms, which may also contain one or more heteroatoms and / or fluorinated or perfluorinated alkyl or alkoxy radicals having 1 to 18

Carbon atoms

where n is an integer from 1 to 20, preferably from 1 to 6, most preferably 1 or 2, and X is a single bond, an alkylene group having 1-6 carbon atoms, a hydrocarbon chain having one or more conjugated double bonds, an aryl group or a system consisting of a plurality of fused, aromatic rings.

2. Oligo-tetracene according to claim 1, characterized in that one or more of the six-atom condensed aromatic rings is replaced by a pentatomic ring, which may also contain a heteroatom.

3. oligo-tetracene according to claims 1 and 2, characterized in that the bridging aryl group is one or more, unsubstituted or substituted with 1-18 carbon atoms containing alkyl groups substituted phenylene rings, or a diunsaturated, a heteroatom-containing five-membered ring or a ferrocenylene unit.

4. oligo-tetracene according to claim 1, characterized in that it is the 2- (tetracen-2-yl) -tetracene of the formula II

in which R and R 'may be hydrogen or have the meanings given in claim 1.

5. Oligo-tetracene according to claim 1, characterized in that it may have the following structure of the formula III, wherein Z = O, S or NH

in which R and R 'may have hydrogen or the meanings given in claim 1.

6. A process for the preparation of oligo-tetracenes according to claims 1 to 5, characterized in that one in any position, in particular in 1-, 2-, or 4-position, singly or multiply substituted, preferably halogenated, in particular brominated tetracene oligomerized.

7. The method according to claim 6, characterized in that one oligomerizes a substituted in the 2-position tetracene with the aid of an organometallic compound in a cross-coupling reaction (Suzuki or Stille reaction).

8. A process for the preparation of oligo-tetracenes according to claims 6 and 7, characterized in that the resulting product is subsequently cleaned by a vacuum sublimation.

9. Use of oligo-tetracenes according to claims 1 to 5 as semiconductors in organic field-effect transistors (= OFETs), organic light-emitting diodes (OLEDs), sensors and organic solar cells.

10. Organic field effect transistor (OFETS), characterized in that its active layer consists of an oligo-tetracene of claims 1-5.