Patent Grant
11322696
This application is a national stage entry, filed pursuant to 35 U.S.C. § 371, of PCT/EP2017/075581, filed Oct. 9, 2017, which claims the benefit of European Patent Application No. 16193529.1, filed Oct. 12, 2016, which is incorporated herein by reference in its entirety.
The present invention relates to binuclear metal complexes suitable for use as emitters in organic electroluminescent devices.
According to the prior art, triplet emitters used in phosphorescent organic electroluminescent devices (OLEDs) are, in particular, bis- and tris-ortho-metallated iridium complexes having aromatic ligands, where the ligands bind to the metal via a negatively charged carbon atom and an uncharged nitrogen atom or via a negatively charged carbon atom and an uncharged carbene carbon atom. Examples of such complexes are tris(phenylpyridyl)iridium(III) and derivatives thereof, where the ligands used are, for example, 1- or 3-phenylisoquinolines, 2-phenyiquinolines or phenylcarbenes. There is generally still need for improvement in these materials, especially with regard to efficiency and lifetime. This is especially also true of the efficiency of red-phosphorescing emitters. As a result of the relatively low triplet level T1 in the case of customary red-phosphorescing emitters, the photoluminescence quantum yield is frequently well below the value theoretically possible since, with low T1, non-radiative channels also play a greater role, especially when the complex has a high luminescence lifetime. An improvement is desirable here by increasing the radiative rates.
An improvement in the stability of the complexes was achieved by the use of polypodal ligands, as described, for example, in WO 2004/081017, U.S. Pat. No. 7,332,232 and WO 2016/124304. Even though these complexes show advantages over complexes which otherwise have the same ligand structure except that the individual ligands therein do not have polypodal bridging, there is still a need for improvement. Thus, in the case of complexes having polypodal ligands too, improvements are still desirable in relation to the properties on use in an organic electroluminescent device, especially in relation to luminescence lifetime of the excited state, efficiency, voltage and/or lifetime.
The problem addressed by the present invention is therefore that of providing novel metal complexes suitable as emitters for use in OLEDs. It is a particular object to provide emitters which exhibit improved properties in relation to efficiency, operating voltage and/or lifetime.
It has been found that, surprisingly, the binuclear rhodium and iridium complexes as described below show distinct improvements in photophysical properties and lead to improved properties when used in an organic electroluminescent device. More particularly, the compounds of the invention have an improved photoluminescence quantum yield. The present invention provides these complexes and organic electroluminescent devices comprising these complexes.
The invention thus provides a compound of the following formula (1):
where the symbols used are as follows:
M1, M2 is the same or different and is iridium or rhodium;
V is a group of the following formula (2) or (3):
When two R or R1 radicals together form a ring system, it may be mono- or polycyclic, and aliphatic, heteroaliphatic, aromatic or heteroaromatic. In this case, the radicals which together form a ring system may be adjacent, meaning that these radicals are bonded to the same carbon atom or to carbon atoms directly bonded to one another, or they may be further removed from one another. Preference is given to this kind of ring formation in radicals bonded to carbon atoms directly bonded to one another or to the same carbon atom.
The wording that two or more radicals together may form a ring, in the context of the present description, shall be understood to mean, inter alia, that the two radicals are joined to one another by a chemical bond with formal elimination of two hydrogen atoms. This is illustrated by the following scheme:
In addition, however, the abovementioned wording shall also be understood to mean that, if one of the two radicals is hydrogen, the second radical binds to the position to which the hydrogen atom was bonded, forming a ring. This shall be illustrated by the following scheme:
The formation of an aromatic ring system shall be illustrated by the following scheme:
An aryl group in the context of this invention contains 6 to 40 carbon atoms; a heteroaryl group in the context of this invention contains 2 to 40 carbon atoms and at least one heteroatom, with the proviso that the sum total of carbon atoms and heteroatoms is at least 5. The heteroatoms are preferably selected from N, O and/or S. An aryl group or heteroaryl group is understood here to mean either a simple aromatic cycle, i.e. benzene, or a simple heteroaromatic cycle, for example pyridine, pyrimidine, thiophene, etc., or a fused aryl or heteroaryl group, for example naphthalene, anthracene, phenanthrene, quinoline, isoquinoline, etc.
An aromatic ring system in the context of this invention contains 6 to 40 carbon atoms in the ring system. A heteroaromatic ring system in the context of this invention contains 1 to 40 carbon atoms and at least one heteroatom in the ring system, with the proviso that the sum total of carbon atoms and heteroatoms is at least 5. The heteroatoms are preferably selected from N, O and/or S. An aromatic or heteroaromatic ring system in the context of this invention shall be understood to mean a system which does not necessarily contain only aryl or heteroaryl groups, but in which it is also possible for a plurality of aryl or heteroaryl groups to be interrupted by a nonaromatic unit (preferably less than 10% of the atoms other than H), for example a carbon, nitrogen or oxygen atom or a carbonyl group. For example, systems such as 9,9′-spirobifluorene, 9,9-diarytfluorene, triarylamine, diaryl ethers, stilbene, etc. shall thus also be regarded as aromatic ring systems in the context of this invention, and likewise systems in which two or more aryl groups are interrupted, for example, by a linear or cyclic alkyl group or by a silyl group. In addition, systems in which two or more aryl or heteroaryl groups are bonded directly to one another, for example biphenyl, terphenyl, quaterphenyl or bipyridine, shall likewise be regarded as an aromatic or heteroaromatic ring system.
A cyclic alkyl group in the context of this invention is understood to mean a monocyclic, bicyclic or polycyclic group.
In the context of the present invention, a C1- to C20-alkyl group in which individual hydrogen atoms or CH2 groups may also be replaced by the abovementioned groups is understood to mean, for example, the methyl, ethyl, n-propyl, i-propyl, cyclopropyl, n-butyl, i-butyl, s-butyl, t-butyl, cyclobutyl, 2-methylbutyl, n-pentyl, s-pentyl, t-pentyl, 2-pentyl, neopentyl, cyclopentyl, n-hexyl, s-hexyl, t-hexyl, 2-hexyl, 3-hexyl, neohexyl, cyclohexyl, 1-methylcyclopentyl, 2-methylpentyl, n-heptyl, 2-heptyl, 3-heptyl, 4-heptyl, cycloheptyl, 1-methylcyclohexyl, n-octyl, 2-ethylhexyl, cyclooctyl, 1-bicyclo[2.2.2]octyl, 2-bicyclo[2.2.2]octyl, 2-(2,6-dimethyl)octyl, 3-(3,7-dimethyl)octyl, adamantyl, trifluoromethyl, pentafluoroethyl, 2,2,2-trifluoroethyl, 1,1-dimethyl-n-hex-1-yl, 1,1-dimethyl-n-hept-1-yl, 1,1-dimethyl-n-oct-1-yl, 1,1-dimethyl-n-dec-1-yl, 1,1-dimethyl-n-dodec-1-yl, 1,1-dimethyl-n-tetradec-1-yl, 1,1-dimethyl-n-hexadec-1-yl, 1,1-dimethyl-n-octadec-1-yl, 1,1-diethyl-n-hex-1-yl, 1,1-diethyl-n-hept-1-yl, 1,1-diethyl-n-oct-1-yl, 1,1-diethyl-n-dec-1-yl, 1,1-diethyl-n-dodec-1-yl, 1,1-diethyl-n-tetradec-1-yl, 1,1-diethyl-n-hexadec-1-yl, 1,1-diethyl-n-octadec-1-yl, 1-(n-propyl)cyclohex-1-yl, 1-(n-butyl)cyclohex-1-yl, 1-(n-hexyl)cyclohex-1-yl, 1-(n-octyl)cyclohex-1-yl and 1-(n-decyl)cyclohex-1-yl radicals. An alkenyl group is understood to mean, for example, ethenyl, propenyl, butenyl, pentenyl, cyclopentenyl, hexenyl, cyclohexenyl, heptenyl, cycloheptenyl, octenyl, cyclooctenyl or cyclooctadienyl. An alkynyl group is understood to mean, for example, ethynyl, propynyl, butynyl, pentynyl, hexynyl, heptynyl or octynyl. A C1- to C20-alkoxy group as present for OR1 or OR2 is understood to mean, for example, methoxy, trifluoromethoxy, ethoxy, n-propoxy, i-propoxy, n-butoxy, i-butoxy, s-butoxy, t-butoxy or 2-methylbutoxy.
An aromatic or heteroaromatic ring system which has 5-40 aromatic ring atoms and may also be substituted in each case by the abovementioned radicals and which may be joined to the aromatic or heteroaromatic system via any desired positions is understood to mean, for example, groups derived from benzene, naphthalene, anthracene, benzanthracene, phenanthrene, benzophenanthrene, pyrene, chrysene, perylene, fluoranthene, benzofluoranthene, naphthacene, pentacene, benzopyrene, biphenyl, biphenylene, terphenyl, terphenylene, fluorene, spirobifluorene, dihydrophenanthrene, dihydropyrene, tetrahydropyrene, cis- or trans-indenofluorene, cis- or trans-monobenzoindenofluorene, cis- or trans-dibenzoindenofluorene, truxene, isotruxene, spirotruxene, spiroisotruxene, furan, benzofuran, isobenzofuran, dibenzofuran, thiophene, benzothiophene, isobenzothiophene, dibenzothiophene, pyrrole, indole, isoindole, carbazole, indolocarbazole, indenocarbazole, pyridine, quinoline, isoquinoline, acridine, phenanthridine, benzo-5,6-quinoline, benzo-6,7-quinoline, benzo-7,8-quinoline, phenothiazine, phenoxazine, pyrazole, indazole, imidazole, benzimidazole, naphthimidazole, phenanthrimidazole, pyridimidazole, pyrazinimidazole, quinoxalinimidazole, oxazole, benzoxazole, naphthoxazole, anthroxazole, phenanthroxazole, isoxazole, 1,2-thiazole, 1,3-thiazole, benzothiazole, pyridazine, benzopyridazine, pyrimidine, benzopyrimidine, quinoxaline, 1,5-diazaanthracene, 2,7-diazapyrene, 2,3-diazapyrene, 1,6-diazapyrene, 1,8-diazapyrene, 4,5-diazapyrene, 4,5,9,10-tetraazaperylene, pyrazine, phenazine, phenoxazine, phenothiazine, fluorubine, naphthyridine, azacarbazole, benzocarboline, phenanthroline, 1,2,3-triazole, 1,2,4-triazole, benzotriazole, 1,2,3-oxadiazole, 1,2,4-oxadiazole, 1,2,5-oxadiazole, 1,3,4-oxadiazole, 1,2,3-thiadiazole, 1,2,4-thiadiazole, 1,2,5-thiadiazole, 1,3,4-thiadiazole, 1,3,5-triazine, 1,2,4-triazine, 1,2,3-triazine, tetrazole, 1,2,4,5-tetrazine, 1,2,3,4-tetrazine, 1,2,3,5-tetrazine, purine, pteridine, indolizine and benzothiadiazole.
For further illustration of the compound, a structure of formula (1) is shown and elucidated hereinafter, where a group of the formula (2) has been chosen here for V. The six A groups bonded to the benzene group in formula (2) are not coplanar with the benzene group, but are twisted out of the plane compared to the benzene group, such that the sub-ligands L1 point above the benzene group and the sub-ligands L2 below the benzene group, as shown in schematic form hereinafter for a ligand in which the A groups are each phenylene groups:
As a result, the three sub-ligands L1 are arranged such that they can coordinate to a first metal M1 above the plane of the central benzene ring, and the three sub-ligands L2 are arranged such that they can coordinate to a second metal M2 below the plane of the central benzene ring. This is shown in schematic form hereinafter for A=CH═CH:
The structure of a metal complex of the invention is depicted in full hereinafter:
In this structure, V is a group of the formula (2). A in each case is a CH═CH group. In this case, the CH═CH groups in the 1, 3 and 5 positions (identified by “a” top right in the scheme) point below the plane of the benzene ring, and the CH═CH groups in the 2, 4 and 6 positions (identified by “b” top right in the scheme) point above the plane of the benzene ring. A sub-ligand L1 or L2 is bonded to each of the alkenyl groups, where the sub-ligands L1 are bonded via the group CH═CH to the central benzene in the 1, 3 and 5 positions and the sub-ligands L2 in the 2, 4 and 6 positions. All sub-ligands L1 and L2 in the scheme depicted above represent phenylpyridine. The three sub-ligands L1 are coordinated to a first iridium atom, and the three sub-ligands L2 are coordinated to a second iridium atom. Each of the two iridium atoms is thus coordinated to three phenylpyridine sub-ligands in each case. The sub-ligands here are joined via the central hexasubstituted benzene unit to form a polypodal system.
When V is a group of the formula (3), the central cycle is a cyclohexane group. This is in a chair form. In this case, the A groups are each bonded equatorially, and so the structure is a trans,cis,trans,cis,trans-substituted cyclohexane as shown in schematic form below:
The dotted bond here in each case represents the bond to L1 or L2.
The expression “bidentate sub-ligand” for L1 and L2 in the context of this application means that this unit would be a bidentate ligand if the group of the formula (2) or (3) were not present. However, as a result of the formal abstraction of a hydrogen atom in this bidentate ligand and the linkage to the bridge of the formula (2) or (3), it is not a separate ligand but a portion of the dodecadentate ligand which thus arises, i.e. a ligand having a total of 12 coordination sites, and so, therefore, the term “sub-ligand” is used for L1 and L2.
The bond of the ligand to M1 or M2 may either be a coordinate bond or a covalent bond, or the covalent fraction of the bond may vary according to the ligand. When it is said in the present application that the ligand or sub-ligand coordinates or binds to M1 or M2, this refers in the context of the present application to any kind of bond of the ligand or sub-ligand to M1 or M2, irrespective of the covalent fraction of the bond.
The compounds of the invention are preferably uncharged, meaning that they are electrically neutral. This is achieved in that Rh or Ir is in each case in the +III oxidation state. In that case, each of the metals M1 and M2 is coordinated by three monoanionic bidentate sub-ligands, so that the sub-ligands compensate for the charge of the complexed metal atom.
As described above, the two metals M1 and M2 in the compound of the invention may be the same or different and are preferably in the +III oxidation state. Possible combinations are therefore Ir/Ir, Ir/Rh and Rh/Rh. In a preferred embodiment of the invention, both metals M1 and M2 are Ir(III).
Recited hereinafter are preferred embodiments for V, i.e. the group of the formula (2) or (3).
Preferred R radicals in formula (2) or formula (3) are as follows:
Particularly preferred R radicals in formula (2) or formula (3) are as follows:
Most preferably, all R radicals in formula (2) and in formula (3) are H.
There follows a description of preferred A groups as occur in the structures of the formulae (2) and (3). The A group may be the same or different at each instance and may be an alkenyl group, an amide group, an ester group, an alkylene group, a methylene ether group or an ortho-bonded arylene or heteroarylene group of the formula (4). When A is an alkenyl group, it is a cis-bonded alkenyl group. In the case of unsymmetric A groups, any orientation of the groups is possible. Thus, when A is an ester group —C(═O)—O—, for example, the carbon atom in the ester group may, identically or differently at each instance, be bonded to the central benzene or cyclohexane ring in formula (2) or (3) and the oxygen atom may be bonded to the sub-ligands L1 or L2, or the oxygen atom of the ester group may be bonded to the central benzene or cyclohexane ring in formula (2) or (3) and the carbon atom may be bonded to the sub-ligands L1 or L2.
In a preferred embodiment of the invention, A is the same or different, preferably the same, at each instance and is selected from the group consisting of —C(═O)—O—, —C(═O)—NR′— and a group of the formula (4).
In a further preferred embodiment, all A are chosen to be the same, in which case they also preferably have the same substitution. The reason for this preference is the better synthetic accessibility of the compounds.
More preferably, all A groups are —C(═O)—O—, or all A groups are —C(═O)—NR′— or all A groups are a group of the formula (4), where the groups of the formula (4) are each chosen to be identical. Most preferably, all A groups are identical groups of the formula (4), preferably optionally substituted phenylene groups.
When A is —C(═O)—NR′—, R′ is preferably the same or different at each instance and is a straight-chain alkyl group having 1 to 10 carbon atoms or a branched or cyclic alkyl group having 3 to 10 carbon atoms or an aromatic or heteroaromatic ring system which has 6 to 24 aromatic ring atoms, and may be substituted in each case by one or more R1 radicals. More preferably, R′ is the same or different at each instance and is a straight-chain alkyl group having 1 to 5 carbon atoms or a branched or cyclic alkyl group having 3 to 6 carbon atoms or an aromatic or heteroaromatic ring system which has 6 to 12 aromatic ring atoms and may be substituted in each case by one or more R1 radicals, but is preferably unsubstituted.
Preferred embodiments of the group of the formula (4) are described hereinafter. The group of the formula (4) may represent a heteroaromatic five-membered ring or an aromatic or heteroaromatic six-membered ring. In a preferred embodiment of the invention, the group of the formula (4) contains not more than two heteroatoms in the aromatic or heteroaromatic unit, more preferably not more than one heteroatom. This does not mean that any substituents bonded to this group cannot also contain heteroatoms. In addition, this definition does not mean that formation of rings by substituents does not give rise to fused aromatic or heteroaromatic structures, for example naphthalene, benzimidazole, etc.
When all X2 groups in formula (4) are carbon atoms, preferred embodiments of the group of the formula (4) are the structures of the following formulae (5) to (21), and, when one X2 group is a nitrogen atom and the other X2 group in the same cycle is a carbon atom, preferred embodiments of the group of the formula (4) are the structures of the following formulae (22) to (29):
where the symbols have the definitions given above.
Particular preference is given to the six-membered aromatic rings and heteroaromatic rings of the formulae (5) to (9) depicted above. Very particular preference is given to ortho-phenylene, i.e. a group of the abovementioned formula (5).
At the same time, it is also possible for adjacent R substituents together to form a ring system, such that it is possible to form fused structures, including fused aryl and heteroaryl groups, for example naphthalene, quinoline, benzimidazole, carbazole, dibenzofuran or dibenzothiophene. Such ring formation is shown schematically below in groups of the abovementioned formula (5), which can lead, for example, to groups of the following formulae (5a) to (5j):
where the symbols have the definitions given above.
In general, the groups fused on may be fused onto any position in the unit of formula (4), as shown by the fused-on benzo group in the formulae (5a) to (5c). The groups as fused onto the unit of the formula (4) in the formulae (5d) to (5j) may therefore also be fused onto other positions in the unit of the formula (4).
The group of the formula (2) can more preferably be represented by the following formulae (2a) to (2e), and the group of the formula (3) can more preferably be represented by the following formulae (3a) to (3e):
where the symbols have the definitions given above. Preferably, X1 is the same or different at each instance and is CR. For synthetic reasons, it is preferable here when the groups bonded in the 1, 3 and 5 positions in each case in formulae (2a) and (3a) are identical and the groups bonded in the 2, 4 and 6 positions in each case are identical.
A preferred embodiment of the groups of the formula (2a) and (3a) is the groups of the following formulae (2a′) and (3a′):
where the symbols have the definitions given above.
More preferably, the R groups in the abovementioned formulae are the same or different and are H, D or an alkyl group having 1 to 4 carbon atoms. Most preferably, R═H. Thus, very particular preference is given to the structures of the following formulae (2a″) and (3a″), especially the structure of the formula (2a″):
where the symbols have the definitions given above.
There follows a description of the bidentate monoanionic sub-ligands L1 and L2. The sub-ligands L1 and L2 may independently be the same or different. It is preferable here when two sub-ligands L1 are the same and the third sub-ligand L1 is the same or different, “the same” meaning that these also have the same substitution. It is also preferable when two sub-ligands L2 are the same and the third sub-ligand L2 is the same or different, “the same” meaning that these also have the same substitution. In a particularly preferred embodiment of the invention, all three sub-ligands L1 are the same, and all three sub-ligands L2 are the same. It may be equally preferable that L1=L2 or L1≠L2.
In a further preferred embodiment of the invention, the coordinating atoms of the bidentate sub-ligands L1 and L2 are the same or different at each instance and are selected from C, N, P, O, S and/or B, more preferably C, N and/or O and most preferably C and/or N. The bidentate sub-ligands L1 and L2 preferably have one carbon atom and one nitrogen atom or two carbon atoms or two nitrogen atoms or two oxygen atoms or one oxygen atom and one nitrogen atom as coordinating atoms. In this case, the coordinating atoms of each of the sub-ligands L1 or L2 may be the same, or they may be different. Preferably, at least two of the bidentate sub-ligands L1 and at least two of the bidentate sub-ligands L2 have one carbon atom and one nitrogen atom or two carbon atoms as coordinating atoms, especially one carbon atom and one nitrogen atom. More preferably, at least all bidentate sub-ligands L1 and L2 have one carbon atom and one nitrogen atom or two carbon atoms as coordinating atoms, especially one carbon atom and one nitrogen atom. Particular preference is thus given to a metal complex in which all sub-ligands are ortho-metallated, i.e. form a metallacycle with the metal in which at least two metal-carbon bonds are present.
It is further preferable when the metallacycle which is formed from the metal and the bidentate sub-ligand L1 or L2 is a five-membered ring, which is preferable particularly when the coordinating atoms are C and N, N and N, or N and O. When the coordinating atoms are O, a six-membered metallacyclic ring may also be preferred. This is shown schematically hereinafter:
where N is a coordinating nitrogen atom, C is a coordinating carbon atom and O represents coordinating oxygen atoms, the carbon atoms shown are atoms of the bidentate sub-ligand L and M is the metal M1 or M2.
In a preferred embodiment of the invention, at least one of the sub-ligands L1 and at least one of the sub-ligands L2, preferably at least two of the sub-ligands L1 and at least two of the sub-ligands L2 and more preferably all bidentate sub-ligands L1 and L2 are the same or different at each instance and are selected from the structures of the following formulae (L-1), (L-2) and (L-3):
where the dotted bond represents the bond of the sub-ligand L1 or L2 to V, i.e. to the group of the formulae (2) or (3) or the preferred embodiments, and the other symbols used are as follows:
At the same time, CyD in the sub-ligands of the formulae (L-1) and (L-2) preferably coordinates via an uncharged nitrogen atom or via a carbene carbon atom, especially via an uncharged nitrogen atom. Further preferably, one of the two CyD groups in the ligand of the formula (L-3) coordinates via an uncharged nitrogen atom and the other of the two CyD groups via an anionic nitrogen atom. Further preferably, CyC in the sub-ligands of the formulae (L-1) and (L-2) coordinates via anionic carbon atoms.
When two or more of the substituents, especially two or more R radicals, together form a ring system, it is possible for a ring system to be formed from substituents bonded to directly adjacent carbon atoms. In addition, it is also possible that the substituents on CyC and CyD in the formulae (L-1) and (L-2) or the substituents on the two CyD groups in formula (L-3) together form a ring, as a result of which CyC and CyD or the two CyD groups may also together form a single fused aryl or heteroaryl group as bidentate ligand.
In a preferred embodiment of the present invention, CyC is an aryl or heteroaryl group having 6 to 13 aromatic ring atoms, more preferably having 6 to 10 aromatic ring atoms, most preferably having 6 aromatic ring atoms, especially a phenyl group, which coordinates to the metal via a carbon atom, which may be substituted by one or more R radicals and which is bonded to CyD via a covalent bond.
Preferred embodiments of the CyC group are the structures of the following formulae (CyC-1) to (CyC-20):
where CyC binds in each case to the position in CyD indicated by # and coordinates to the metal at the position indicated by *, R has the definitions given above and the further symbols used are as follows:
Preferably, a total of not more than two symbols X in CyC are N, more preferably not more than one symbol X in CyC is N, and most preferably all symbols X are CR, with the proviso that, when CyC is bonded directly within the group of the formula (2) or (3), one symbol X is C and the bridge of the formula (2) or (3) or the preferred embodiments is bonded to this carbon atom.
Particularly preferred CyC groups are the groups of the following formulae (CyC-1a) to (CyC-20a):
where the symbols have the definitions given above and, when CyC is bonded directly within the group of the formula (2) or (3), one R radical is not present and the group of the formula (2) or (3) or the preferred embodiments is bonded to the corresponding carbon atom. When the CyC group is bonded directly to the group of the formula (2) or (3), the bond is preferably via the position marked by “∘” in the formulae depicted above, and so the R radical in this position in that case is preferably absent. The above-depicted structures which do not contain any carbon atom marked by “∘” are preferably not bonded directly to the group of the formula (2) or (3).
Preferred groups among the (CyC-1) to (CyC-20) groups are the (CyC-1), (CyC-3), (CyC-8), (CyC-10), (CyC-12), (CyC-13) and (CyC-16) groups, and particular preference is given to the (CyC-1a), (CyC-3a), (CyC-8a), (CyC-10a), (CyC-12a), (CyC-13a) and (CyC-16a) groups.
In a further preferred embodiment of the invention, CyD is a heteroaryl group having 5 to 13 aromatic ring atoms, more preferably having 6 to 10 aromatic ring atoms, which coordinates to the metal via an uncharged nitrogen atom or via a carbene carbon atom and which may be substituted by one or more R radicals and which is bonded via a covalent bond to CyC.
Preferred embodiments of the CyD group are the structures of the following formulae (CyD-1) to (CyD-14):
where the CyD group binds to CyC in each case at the position indicated by # and coordinates to the metal at the position indicated by *, and where X, W and R have the definitions given above, with the proviso that, when CyD is bonded directly within the group of the formula (2) or (3), one symbol X is C and the bridge of the formula (2) or (3) or the preferred embodiments is bonded to this carbon atom. When the CyD group is bonded directly to the group of the formula (2) or (3), the bond is preferably via the position marked by “∘” in the formulae depicted above, and so the symbol X marked by “∘” in that case is preferably C. The above-depicted structures which do not contain any symbol X marked by “∘” are preferably not bonded directly to the group of the formula (2) or (3), since such a bond to the bridge is not advantageous for steric reasons.
In this case, the (CyD-1) to (CyD-4), (CyD-7) to (CyD-10), (CyD-13) and (CyD-14) groups coordinate to the metal via an uncharged nitrogen atom, the (CyD-5) and (CyD-6) groups via a carbene carbon atom and the (CyD-11) and (CyD-12) groups via an anionic nitrogen atom.
Preferably, a total of not more than two symbols X in CyD are N, more preferably not more than one symbol X in CyD is N, and especially preferably all symbols X are CR, with the proviso that, when CyD is bonded directly within the group of the formula (2) or (3), one symbol X is C and the bridge of the formula (2) or (3) or the preferred embodiments is bonded to this carbon atom.
Particularly preferred CyD groups are the groups of the following formulae (CyD-1a) to (CyD-14b):
where the symbols used have the definitions given above and, when CyD is bonded directly within the group of the formula (2) or (3), one R radical is not present and the bridge of the formula (2) or (3) or the preferred embodiments is bonded to the corresponding carbon atom. When CyD is bonded directly to the group of the formula (2) or (3), the bond is preferably via the position marked by “∘” in the formulae depicted above, and so the R radical in this position in that case is preferably absent. The above-depicted structures which do not contain any carbon atom marked by “∘” are preferably not bonded directly to the group of the formula (2) or (3).
Preferred groups among the (CyD-1) to (CyD-14) groups are the (CyD-1), (CyD-2), (CyD-3), (CyD-4), (CyD-5) and (CyD-6) groups, especially (CyD-1), (CyD-2) and (CyD-3), and particular preference is given to the (CyD-1a), (CyD-2a), (CyD-3a), (CyD-4a), (CyD-5a) and (CyD-6a) groups, especially (CyD-1a), (CyD-2a) and (CyD-3a).
In a preferred embodiment of the present invention, CyC is an aryl or heteroaryl group having 6 to 13 aromatic ring atoms, and at the same time CyD is a heteroaryl group having 5 to 13 aromatic ring atoms. More preferably, CyC is an aryl or heteroaryl group having 6 to 10 aromatic ring atoms, and at the same time CyD is a heteroaryl group having 5 to 10 aromatic ring atoms. Most preferably, CyC is an aryl or heteroaryl group having 6 aromatic ring atoms, especially phenyl, and CyD is a heteroaryl group having 6 to 10 aromatic ring atoms. At the same time, CyC and CyD may be substituted by one or more R radicals.
The abovementioned preferred (CyC-1) to (CyC-20) and (CyD-1) to (CyD-14) groups may be combined with one another as desired in the sub-ligands of the formulae (L-1) and (L-2), provided that at least one of the CyC or CyD groups has a suitable attachment site to the group of the formula (2) or (3), suitable attachment sites being signified by “∘” in the formulae given above. It is especially preferable when the CyC and CyD groups specified above as particularly preferred, i.e. the groups of the formulae (CyC-1a) to (CyC-20a) and the groups of the formulae (CyD1-a) to (CyD-14b), are combined with one another, provided that at least one of the preferred CyC or CyD groups has a suitable attachment site to the group of the formula (2) or (3), suitable attachment sites being signified by “∘” in the formulae given above. Combinations in which neither CyC nor CyD has such a suitable attachment site to the bridge of the formula (2) or (3) are therefore not preferred.
It is very particularly preferable when one of the (CyC-1), (CyC-3), (CyC-8), (CyC-10), (CyC-12), (CyC-13) and (CyC-16) groups and especially the (CyC-1a), (CyC-3a), (CyC-8a), (CyC-10a), (CyC-12a), (CyC-13a) and (CyC-16a) groups is combined with one of the (CyD-1), (CyD-2) and (CyD-3) groups and especially with one of the (CyD-1a), (CyD-2a) and (CyD-3a) groups.
Preferred sub-ligands (L-1) are the structures of the following formulae (L-1-1) and (L-1-2), and preferred sub-ligands (L-2) are the structures of the following formulae (L-2-1) to (L-2-3):
where the symbols used have the definitions given above, * indicates the position of the coordination to the iridium and “∘” represents the position of the bond to the group of the formula (2) or (3).
Particularly preferred sub-ligands (L-1) are the structures of the following formulae (L-1-1a) and (L-1-2b), and particularly preferred sub-ligands (L-2) are the structures of the following formulae (L-2-1a) to (L-2-3a):
where the symbols used have the definitions given above and “∘” represents the position of the bond to the group of the formula (2) or (3).
It is likewise possible for the abovementioned preferred CyD groups in the sub-ligands of the formula (L-3) to be combined with one another as desired, by combining an uncharged CyD group, i.e. a (CyD-1) to (CyD-10), (CyD-13) or (CyD-14) group, with an anionic CyD group, i.e. a (CyD-11) or (CyD-12) group, provided that at least one of the preferred CyD groups has a suitable attachment site to the group of the formula (2) or (3), suitable attachment sites being signified by “∘” in the formulae given above.
When two R radicals, one of them bonded to CyC and the other to CyD in the formulae (L-1) and (L-2) or one of them bonded to one CyD group and the other to the other CyD group in formula (L-3), form an aromatic ring system with one another, this may result in bridged sub-ligands and also in sub-ligands which represent a single larger heteroaryl group overall, for example benzo[h]quinoline, etc. The ring formation between the substituents on CyC and CyD in the formulae (L-1) and (L-2) or between the substituents on the two CyD groups in formula (L-3) is preferably via a group according to one of the following formulae (30) to (39):
where R1 has the definitions given above and the dotted bonds signify the bonds to CyC or CyD. At the same time, the unsymmetric groups among those mentioned above may be incorporated in each of the two possible orientations; for example, in the group of the formula (39), the oxygen atom may bind to the CyC group and the carbonyl group to the CyD group, or the oxygen atom may bind to the CyD group and the carbonyl group to the CyC group.
At the same time, the group of the formula (36) is preferred particularly when this results in ring formation to give a six-membered ring, as shown below, for example, by the formulae (L-22) and (L-23).
Preferred ligands which arise through ring formation between two R radicals in the different cycles are the structures of the formulae (L-4) to (L-31) shown below:
where the symbols used have the definitions given above and “∘” indicates the position at which this sub-ligand is joined to the group of the formula (2) or (3).
In a preferred embodiment of the sub-ligands of the formulae (L-4) to (L-31), a total of one symbol X is N and the other symbols X are CR, or all symbols X are CR.
In a further embodiment of the invention, it is preferable if, in the groups (CyC-1) to (CyC-20) or (CyD-1) to (CyD-14) or in the sub-ligands (L-1-1) to (L-2-3), (L-4) to (L-31), one of the atoms X is N when an R group bonded as a substituent adjacent to this nitrogen atom is not hydrogen or deuterium. This applies analogously to the preferred structures (CyC-1a) to (CyC-20a) or (CyD-1a) to (CyD-14b) in which a substituent bonded adjacent to a non-coordinating nitrogen atom is preferably an R group which is not hydrogen or deuterium. In this case, this substituent R is preferably a group selected from CF3, OR1 where R1 is an alkyl group having 1 to 10 carbon atoms, alkyl groups having 1 to 10 carbon atoms, especially branched or cyclic alkyl groups having 3 to 10 carbon atoms, a dialkylamino group having 2 to 10 carbon atoms, aromatic or heteroaromatic ring systems or aralkyl or heteroaralkyl groups. These groups are sterically demanding groups. Further preferably, this R radical may also form a cycle with an adjacent R radical.
A further suitable bidentate sub-ligand is the sub-ligand of the following formula (L-32) or (L-33)
where R has the definitions given above, * represents the position of coordination to the metal, “∘” represents the position of linkage of the sub-ligand to the group of the formula (2) or (3) and the other symbols used are as follows:
When two R radicals bonded to adjacent carbon atoms in the sub-ligands (L-32) and (L-33) form an aromatic cycle with one another, this cycle together with the two adjacent carbon atoms is preferably a structure of the following formula (40):
where the dotted bonds symbolize the linkage of this group within the sub-ligand and Y is the same or different at each instance and is CR1 or N and preferably not more than one symbol Y is N. In a preferred embodiment of the sub-ligand (L-32) or (L-33), not more than one group of the formula (40) is present. In a preferred embodiment of the invention, in the sub-ligand of the formulae (L-32) and (L-33), a total of 0, 1 or 2 of the symbols X and, if present, Y are N. More preferably, a total of 0 or 1 of the symbols X and, if present, Y are N.
Further suitable bidentate sub-ligands are the structures of the following formulae (L-34) to (L-38), where preferably not more than one of the two bidentate sub-ligands L per metal is one of these structures,
where the sub-ligands (L-34) to (L-36) each coordinate to the metal via the nitrogen atom explicitly shown and the negatively charged oxygen atom, and the sub-ligands (L-37) and (L-38) coordinate to the metal via the two oxygen atoms, X has the definitions given above and “∘” indicates the position via which the sub-ligand L is joined to the group of the formula (2) or (3).
The above-recited preferred embodiments of X are also preferred for the sub-ligands of the formulae (L-34) to (L-36).
Preferred sub-ligands of the formulae (L-34) to (L-36) are therefore the sub-ligands of the following formulae (L-34a) to (L-36a):
where the symbols used have the definitions given above and “∘” indicates the position via which the sub-ligand L is joined to the group of the formula (2) or (3).
More preferably, in these formulae, R is hydrogen, where “∘” indicates the position via which the sub-ligand L is joined within the group of the formula (2) or (3) or the preferred embodiments, and so the structures are those of the following formulae (L-34b) to (L-36b):
where the symbols used have the definitions given above.
There follows a description of preferred substituents as may be present on the above-described sub-ligands, but also on A when A is a group of the formula (4).
In a preferred embodiment of the invention, the compound of the invention contains two substituents R which are bonded to adjacent carbon atoms and together form an aliphatic ring according to one of the formulae described hereinafter. In this case, the two R substituents which form this aliphatic ring may be present on the bridge of the formulae (2) or (3) or the preferred embodiments and/or on one or more of the bidentate sub-ligands L. The aliphatic ring which is formed by the ring formation by two substituents R together is preferably described by one of the following formulae (41) to (47):
where R1 and R2 have the definitions given above, the dotted bonds signify the linkage of the two carbon atoms in the ligand and, in addition:
In a preferred embodiment of the invention, R3 is not H.
In the above-depicted structures of the formulae (41) to (47) and the further embodiments of these structures specified as preferred, a double bond is depicted in a formal sense between the two carbon atoms. This is a simplification of the chemical structure when these two carbon atoms are incorporated into an aromatic or heteroaromatic system and hence the bond between these two carbon atoms is formally between the bonding level of a single bond and that of a double bond. The drawing of the formal double bond should thus not be interpreted so as to limit the structure; instead, it will be apparent to the person skilled in the art that this is an aromatic bond.
When adjacent radicals in the structures of the invention form an aliphatic ring system, it is preferable when the latter does not have any acidic benzylic protons. Benzylic protons are understood to mean protons which bind to a carbon atom bonded directly to the ligand. This can be achieved by virtue of the carbon atoms in the aliphatic ring system which bind directly to an aryl or heteroaryl group being fully substituted and not containing any bonded hydrogen atoms. Thus, the absence of acidic benzylic protons in the formulae (41) to (43) is achieved by virtue of Z1 and Z3, when they are C(R3)2, being defined such that R3 is not hydrogen. This can additionally also be achieved by virtue of the carbon atoms in the aliphatic ring system which bind directly to an aryl or heteroaryl group being the bridgeheads in a bi- or polycyclic structure. The protons bonded to bridgehead carbon atoms, because of the spatial structure of the bi- or polycycle, are significantly less acidic than benzylic protons on carbon atoms which are not bonded within a bi- or polycyclic structure, and are regarded as non-acidic protons in the context of the present invention. Thus, the absence of acidic benzylic protons in formulae (44) to (47) is achieved by virtue of this being a bicyclic structure, as a result of which R1, when it is H, is much less acidic than benzylic protons since the corresponding anion of the bicyclic structure is not mesomerically stabilized. Even when R1 in formulae (44) to (47) is H, this is therefore a non-acidic proton in the context of the present application.
In a preferred embodiment of the structure of the formulae (41) to (47), not more than one of the Z1, Z2 and Z3 groups is a heteroatom, especially O or NR3, and the other groups are C(R3)2 or C(R1)2, or Z and Z3 are the same or different at each instance and are O or NR3 and Z2 is C(R1)2. In a particularly preferred embodiment of the invention, Z1 and Z3 are the same or different at each instance and are C(R3)2, and Z2 is C(R1)2 and more preferably C(R3)2 or CH2.
Preferred embodiments of the formula (41) are thus the structures of the formulae (41-A), (41-B), (41-C) and (41-D), and a particularly preferred embodiment of the formula (41-A) is the structures of the formulae (41-E) and (41-F):
where R1 and R3 have the definitions given above and Z1, Z2 and Z3 are the same or different at each instance and are O or NR3.
Preferred embodiments of the formula (42) are the structures of the following formulae (42-A) to (42-F):
where R1 and R3 have the definitions given above and Z1, Z2 and Z3 are the same or different at each instance and are O or NR3.
Preferred embodiments of the formula (43) are the structures of the following formulae (43-A) to (43-E):
where R1 and R3 have the definitions given above and Z1, Z2 and Z3 are the same or different at each instance and are O or NR3.
In a preferred embodiment of the structure of formula (44), the R1 radicals bonded to the bridgehead are H, D, F or CH3. Further preferably, Z2 is C(R1)2 or 0, and more preferably C(R3)2. Preferred embodiments of the formula (44) are thus structures of the formulae (44-A) and (44-B), and a particularly preferred embodiment of the formula (44-A) is a structure of the formula (44-C):
where the symbols used have the definitions given above.
In a preferred embodiment of the structure of formulae (45), (46) and (47), the R1 radicals bonded to the bridgehead are H, D, F or CH3. Further preferably, Z2 is C(R1)2. Preferred embodiments of the formulae (45), (46) and (47) are thus the structures of the formulae (45-A), (46-A) and (47-A):
where the symbols used have the definitions given above.
Further preferably, the G group in the formulae (44), (44-A), (44-B), (44-C), (45), (45-A), (46), (46-A), (47) and (47-A) is a 1,2-ethylene group which may be substituted by one or more R2 radicals, where R2 is preferably the same or different at each instance and is H or an alkyl group having 1 to 4 carbon atoms, or an ortho-arylene group which has 6 to 10 carbon atoms and may be substituted by one or more R2 radicals, but is preferably unsubstituted, especially an ortho-phenylene group which may be substituted by one or more R2 radicals, but is preferably unsubstituted.
In a further preferred embodiment of the invention, R3 in the groups of the formulae (41) to (47) and in the preferred embodiments is the same or different at each instance and is F, a straight-chain alkyl group having 1 to 10 carbon atoms or a branched or cyclic alkyl group having 3 to 20 carbon atoms, where one or more nonadjacent CH2 groups in each case may be replaced by R2C═CR2 and one or more hydrogen atoms may be replaced by D or F, or an aromatic or heteroaromatic ring system which has 5 to 14 aromatic ring atoms and may be substituted in each case by one or more R2 radicals; at the same time, two R3 radicals bonded to the same carbon atom may together form an aliphatic or aromatic ring system and thus form a spiro system; in addition, R3 may form an aliphatic ring system with an adjacent R or R1 radical.
In a particularly preferred embodiment of the invention, R3 in the groups of the formulae (41) to (47) and in the preferred embodiments is the same or different at each instance and is F, a straight-chain alkyl group having 1 to 3 carbon atoms, especially methyl, or an aromatic or heteroaromatic ring system which has 5 to 12 aromatic ring atoms and may be substituted in each case by one or more R2 radicals, but is preferably unsubstituted; at the same time, two R3 radicals bonded to the same carbon atom may together form an aliphatic or aromatic ring system and thus form a spiro system; in addition, R3 may form an aliphatic ring system with an adjacent R or R1 radical.
Examples of particularly suitable groups of the formula (41) are the groups depicted below:
Examples of particularly suitable groups of the formula (42) are the groups depicted below:
Examples of particularly suitable groups of the formulae (43), (46) and (47) are the groups depicted below:
Examples of particularly suitable groups of the formula (44) are the groups depicted below:
Examples of particularly suitable groups of the formula (45) are the groups depicted below:
When R radicals are bonded within the bidentate sub-ligands or ligands or within the bivalent arylene or heteroarylene groups of the formula (4) bonded within the formulae (2) or (3) or the preferred embodiments, these R radicals are the same or different at each instance and are preferably selected from the group consisting of H, D, F, Br, I, N(R1)2, CN, Si(R1)3, B(OR1)2, C(═O)R1, a straight-chain alkyl group having 1 to 10 carbon atoms or an alkenyl group having 2 to 10 carbon atoms or a branched or cyclic alkyl group having 3 to 10 carbon atoms, where the alkyl or alkenyl group may be substituted in each case by one or more R1 radicals, or an aromatic or heteroaromatic ring system which has 5 to 30 aromatic ring atoms and may be substituted in each case by one or more R1 radicals; at the same time, two adjacent R radicals together or R together with R1 may also form a mono- or polycyclic, aliphatic or aromatic ring system. More preferably, these R radicals are the same or different at each instance and are selected from the group consisting of H, D, F, N(R1)2, a straight-chain alkyl group having 1 to 6 carbon atoms or a branched or cyclic alkyl group having 3 to 10 carbon atoms, where one or more hydrogen atoms may be replaced by D or F, or an aromatic or heteroaromatic ring system which has 5 to 24 aromatic ring atoms and may be substituted in each case by one or more R1 radicals; at the same time, two adjacent R radicals together or R together with R1 may also form a mono- or polycyclic, aliphatic or aromatic ring system.
Preferred R1 radicals bonded to R are the same or different at each instance and are H, D, F, N(R2)2, CN, a straight-chain alkyl group having 1 to 10 carbon atoms or an alkenyl group having 2 to 10 carbon atoms or a branched or cyclic alkyl group having 3 to 10 carbon atoms, where the alkyl group may be substituted in each case by one or more R2 radicals, or an aromatic or heteroaromatic ring system which has 5 to 24 aromatic ring atoms and may be substituted in each case by one or more R2 radicals; at the same time, two or more adjacent R1 radicals together may form a mono- or polycyclic aliphatic ring system. Particularly preferred R1 radicals bonded to R are the same or different at each instance and are H, F, CN, a straight-chain alkyl group having 1 to 5 carbon atoms or a branched or cyclic alkyl group having 3 to 5 carbon atoms, each of which may be substituted by one or more R2 radicals, or an aromatic or heteroaromatic ring system which has 5 to 13 aromatic ring atoms and may be substituted in each case by one or more R2 radicals; at the same time, two or more adjacent R1 radicals together may form a mono- or polycyclic aliphatic ring system.
Preferred R2 radicals are the same or different at each instance and are H, F or an aliphatic hydrocarbyl radical having 1 to 5 carbon atoms or an aromatic hydrocarbyl radical having 6 to 12 carbon atoms; at the same time, two or more R2 substituents together may also form a mono- or polycyclic aliphatic ring system.
The abovementioned preferred embodiments can be combined with one another as desired. In a particularly preferred embodiment of the invention, the abovementioned preferred embodiments apply simultaneously.
Examples of compounds of the invention are the structures adduced below:
The compounds of the invention are chiral structures. According to the exact structure of the complexes and ligands, the formation of diastereomers and of several pairs of enantiomers is possible. In that case, the complexes of the invention include both the mixtures of the different diastereomers or the corresponding racemates and the individual isolated diastereomers or enantiomers.
The complexes of the invention can especially be prepared by the route described hereinafter. For this purpose, the 12-dentate ligand is prepared and then coordinated to the metals M by an o-metalation reaction. In general, for this purpose, an iridium salt or rhodium salt is reacted with the corresponding free ligand.
Therefore, the present invention further provides a process for preparing the compound of the invention by reacting the corresponding free ligands with metal alkoxides of the formula (48), with metal ketoketonates of the formula (49), with metal halides of the formula (50) or with metal carboxylates of the formula (51)
where M is iridium or rhodium, R has the definitions given above, Hal=F, Cl, Br or I and the iridium reactants or rhodium reactants may also take the form of the corresponding hydrates. R here is preferably an alkyl group having 1 to 4 carbon atoms.
It is likewise possible to use iridium compounds or rhodium compounds bearing both alkoxide and/or halide and/or hydroxyl radicals and ketoketonate radicals. These compounds may also be charged. Corresponding iridium compounds of particular suitability as reactants are disclosed in WO 2004/085449. Particularly suitable are [IrCl2(acac)2]−, for example Na[IrCl2(acac)2], metal complexes with acetylacetonate derivatives as ligand, for example Ir(acac)3 or tris(2,2,6,6-tetramethylheptane-3,5-dionato)iridium, and IrCl3.xH2O where x is typically a number from 2 to 4.
The synthesis of the complexes is preferably conducted as described in WO 2002/060910 and in WO 2004/085449. In this case, the synthesis can, for example, also be activated by thermal or photochemical means and/or by microwave radiation. In addition, the synthesis can also be conducted in an autoclave at elevated pressure and/or elevated temperature.
The reactions can be conducted without addition of solvents or melting aids in a melt of the corresponding ligands to be o-metalated. It is optionally possible to add solvents or melting aids. Suitable solvents are protic or aprotic solvents such as aliphatic and/or aromatic alcohols (methanol, ethanol, isopropanol, t-butanol, etc.), oligo- and polyalcohols (ethylene glycol, propane-1,2-diol, glycerol, etc.), alcohol ethers (ethoxyethanol, diethylene glycol, triethylene glycol, polyethylene glycol, etc.), ethers (di- and triethylene glycol dimethyl ether, diphenyl ether, etc.), aromatic, heteroaromatic and/or aliphatic hydrocarbons (toluene, xylene, mesitylene, chlorobenzene, pyridine, lutidine, quinoline, isoquinoline, tridecane, hexadecane, etc.), amides (DMF, DMAC, etc.), lactams (NMP), sulfoxides (DMSO) or sulfones (dimethyl sulfone, sulfolane, etc.). Suitable melting aids are compounds that are in solid form at room temperature but melt when the reaction mixture is heated and dissolve the reactants, so as to form a homogeneous melt. Particularly suitable are biphenyl, m-terphenyl, triphenyls, R- or S-binaphthol or else the corresponding racemate, 1,2-, 1,3- or 1,4-bisphenoxybenzene, triphenylphosphine oxide, 18-crown-6, phenol, 1-naphthol, hydroquinone, etc. Particular preference is given here to the use of hydroquinone.
A further suitable process for synthesis of the complexes of the invention involves first synthesizing a precursor of the ligand containing the V group and the three sub-ligands L1, but containing reactive leaving groups, for example halogen groups, rather than the three sub-ligands L2. This precursor of the ultimate ligand may then be coordinated to the metal M1. In a next step, by a coupling reaction, for example a Suzuki coupling, the three sub-ligands L2 are coupled to V and reacted with M2 in a further reaction to give the complex of the invention.
It is possible by these processes, if necessary followed by purification, for example recrystallization or sublimation, to obtain the inventive compounds of formula (1) in high purity, preferably more than 99% (determined by means of 1H NMR and/or HPLC).
The compounds of the invention may also be rendered soluble by suitable substitution, for example by comparatively long alkyl groups (about 4 to 20 carbon atoms), especially branched alkyl groups, or optionally substituted aryl groups, for example xylyl, mesityl or branched terphenyl or quaterphenyl groups. Another particular method that leads to a distinct improvement in the solubility of the metal complexes is the use of fused-on aliphatic groups, as shown, for example, by the formulae (41) to (47) disclosed above. Such compounds are then soluble in sufficient concentration at room temperature in standard organic solvents, for example toluene or xylene, to be able to process the complexes from solution. These soluble compounds are of particularly good suitability for processing from solution, for example by printing methods.
For the processing of the metal complexes of the invention from the liquid phase, for example by spin-coating or by printing methods, formulations of the metal complexes of the invention are required. These formulations may, for example, be solutions, dispersions or emulsions. For this purpose, it may be preferable to use mixtures of two or more solvents. Suitable and preferred solvents are, for example, toluene, anisole, o-, m- or p-xylene, methyl benzoate, mesitylene, tetralin, veratrole, THF, methyl-THF, THP, chlorobenzene, dioxane, phenoxytoluene, especially 3-phenoxytoluene, (−)-fenchone, 1,2,3,5-tetramethylbenzene, 1,2,4,5-tetramethylbenzene, 1-methylnaphthalene, 2-methylbenzothiazole, 2-phenoxyethanol, 2-pyrrolidinone, 3-methylanisole, 4-methylanisole, 3,4-dimethylanisole, 3,5-dimethylanisole, acetophenone, α-terpineol, benzothiazole, butyl benzoate, cumene, cyclohexanol, cyclohexanone, cyclohexylbenzene, decalin, dodecylbenzene, ethyl benzoate, indane, NMP, p-cymene, phenetole, 1,4-diisopropylbenzene, dibenzyl ether, diethylene glycol butyl methyl ether, triethylene glycol butyl methyl ether, diethylene glycol dibutyl ether, triethylene glycol dimethyl ether, diethylene glycol monobutyl ether, tripropylene glycol dimethyl ether, tetraethylene glycol dimethyl ether, 2-isopropylnaphthalene, pentylbenzene, hexylbenzene, heptylbenzene, octylbenzene, 1,1-bis(3,4-dimethylphenyl)ethane, hexamethylindane, 2-methylbiphenyl, 3-methylbiphenyl, 1-methylnaphthalene, 1-ethylnaphthalene, ethyl octanoate, diethyl sebacate, octyl octanoate, heptylbenzene, menthyl isovalerate, cyclohexyl hexanoate or mixtures of these solvents.
The present invention therefore further provides a formulation comprising at least one compound of the invention and at least one further compound. The further compound may, for example, be a solvent, especially one of the abovementioned solvents or a mixture of these solvents. The further compound may alternatively be a further organic or inorganic compound which is likewise used in the electronic device, for example a matrix material. This further compound may also be polymeric.
The above-described metal complex of the invention or the preferred embodiments detailed above can be used as active component or as oxygen sensitizers in the electronic device. The present invention thus further provides for the use of a compound of the invention in an electronic device or as oxygen sensitizer. The present invention still further provides an electronic device comprising at least one compound of the invention.
An electronic device is understood to mean any device comprising anode, cathode and at least one layer, said layer comprising at least one organic or organometallic compound. The electronic device of the invention thus comprises anode, cathode and at least one layer containing at least one metal complex of the invention. Preferred electronic devices are selected from the group consisting of organic electroluminescent devices (OLEDs, PLEDs), organic integrated circuits (O-ICs), organic field-effect transistors (O-FETs), organic thin-film transistors (O-TFTs), organic light-emitting transistors (O-LETs), organic solar cells (O-SCs), the latter being understood to mean both purely organic solar cells and dye-sensitized solar cells, organic optical detectors, organic photoreceptors, organic field-quench devices (O-FQDs), light-emitting electrochemical cells (LECs), oxygen sensors and organic laser diodes (O-lasers), comprising at least one metal complex of the invention in at least one layer. Particular preference is given to organic electroluminescent devices. Active components are generally the organic or inorganic materials introduced between the anode and cathode, for example charge injection, charge transport or charge blocker materials, but especially emission materials and matrix materials. The compounds of the invention exhibit particularly good properties as emission material in organic electroluminescent devices. A preferred embodiment of the invention is therefore organic electroluminescent devices. In addition, the compounds of the invention can be used for production of singlet oxygen or in photocatalysis.
The organic electroluminescent device comprises cathode, anode and at least one emitting layer. Apart from these layers, it may comprise still further layers, for example in each case one or more hole injection layers, hole transport layers, hole blocker layers, electron transport layers, electron injection layers, exciton blocker layers, electron blocker layers, charge generation layers and/or organic or inorganic pin junctions. At the same time, it is possible that one or more hole transport layers are p-doped, for example with metal oxides such as MoO3 or WO3 or with (per)fluorinated electron-deficient aromatic systems, and/or that one or more electron transport layers are n-doped. It is likewise possible for interlayers to be introduced between two emitting layers, these having, for example, an exciton-blocking function and/or controlling the charge balance in the electroluminescent device. However, it should be pointed out that not necessarily every one of these layers need be present.
In this case, it is possible for the organic electroluminescent device to contain an emitting layer, or for it to contain a plurality of emitting layers. If a plurality of emission layers are present, these preferably have several emission maxima between 380 nm and 750 nm overall, such that the overall result is white emission; in other words, various emitting compounds which may fluoresce or phosphoresce are used in the emitting layers. Three-layer systems are especially preferred, where the three layers exhibit blue, green and orange or red emission, or systems having more than three emitting layers. Preference is additionally also given to tandem OLEDs. The system may also be a hybrid system wherein one or more layers fluoresce and one or more other layers phosphoresce. White-emitting organic electroluminescent devices may be used for lighting applications or else with color filters for full-color displays.
In a preferred embodiment of the invention, the organic electroluminescent device comprises the metal complex of the invention as emitting compound in one or more emitting layers.
When the metal complex of the invention is used as emitting compound in an emitting layer, it is preferably used in combination with one or more matrix materials. The mixture of the metal complex of the invention and the matrix material contains between 0.1% and 99% by weight, preferably between 1% and 90% by weight, more preferably between 3% and 40% by weight and especially between 5% and 25% by weight of the metal complex of the invention, based on the overall mixture of emitter and matrix material. Correspondingly, the mixture contains between 99.9% and 1% by weight, preferably between 99% and 10% by weight, more preferably between 97% and 60% by weight and especially between 95% and 75% by weight of the matrix material, based on the overall mixture of emitter and matrix material.
The matrix material used may generally be any materials which are known for the purpose according to the prior art. The triplet level of the matrix material is preferably higher than the triplet level of the emitter.
Suitable matrix materials for the compounds of the invention are ketones, phosphine oxides, sulfoxides and sulfones, for example according to WO 2004/013080, WO 2004/093207, WO 2006/005627 or WO 2010/006680, triarylamines, carbazole derivatives, e.g. CBP (N,N-biscarbazolylbiphenyl), m-CBP or the carbazole derivatives disclosed in WO 2005/039246, US 2005/0069729, JP 2004/288381, EP 1205527, WO 2008/086851 or US 2009/0134784, indolocarbazole derivatives, for example according to WO 2007/063754 or WO 2008/056746, indenocarbazole derivatives, for example according to WO 2010/136109 or WO 2011/000455, azacarbazoles, for example according to EP 1617710, EP 1617711, EP 1731584, JP 2005/347160, bipolar matrix materials, for example according to WO 2007/137725, silanes, for example according to WO 2005/111172, azaboroles or boronic esters, for example according to WO 2006/117052, diazasilole derivatives, for example according to WO 2010/054729, diazaphosphole derivatives, for example according to WO 2010/054730, triazine derivatives, for example according to WO 2010/015306, WO 2007/063754 or WO 2008/056746, zinc complexes, for example according to EP 652273 or WO 2009/062578, dibenzofuran derivatives, for example according to WO 2009/148015, WO 2015/169412 or the as yet unpublished applications EP16158460.2 or EP16159829.7, or bridged carbazole derivatives, for example according to US 2009/0136779, WO 2010/050778, WO 2011/042107 or WO 2011/088877.
It may also be preferable to use a plurality of different matrix materials as a mixture, especially at least one electron-conducting matrix material and at least one hole-conducting matrix material. A preferred combination is, for example, the use of an aromatic ketone, a triazine derivative or a phosphine oxide derivative with a triarylamine derivative or a carbazole derivative as mixed matrix for the metal complex of the invention. Preference is likewise given to the use of a mixture of a charge-transporting matrix material and an electrically inert matrix material having no significant involvement, if any, in the charge transport, as described, for example, in WO 2010/108579. Preference is likewise given to the use of two electron-transporting matrix materials, for example triazine derivatives and lactam derivatives, as described, for example, in WO 2014/094964.
Depicted below are examples of compounds that are suitable as matrix materials for the compounds of the invention.
Examples of triazines and pyrimidines which can be used as electron-transporting matrix materials are the following compounds:
Examples of lactams which can be used as electron-transporting matrix materials are the following compounds:
Examples of ketones which can be used as electron-transporting matrix materials are the following compounds:
Examples of metal complexes which can be used as electron-transporting matrix materials are the following compounds:
Examples of phosphine oxides which can be used as electron-transporting matrix materials are the following compounds:
Examples of indolo- and indenocarbazole derivatives in the broadest sense which can be used as hole- or electron-transporting matrix materials according to the substitution pattern are the following compounds:
Examples of carbazole derivatives which can be used as hole- or electron-transporting matrix materials according to the substitution pattern are the following compounds:
Examples of bridged carbazole derivatives which can be used as hole-transporting matrix materials are the following compounds:
Examples of biscarbazoles which can be used as hole-transporting matrix materials are the following compounds:
Examples of amines which can be used as hole-transporting matrix materials are the following compounds:
Examples of materials which can be used as wide bandgap matrix materials are the following compounds:
It is further preferable to use a mixture of two or more triplet emitters together with a matrix. In this case, the triplet emitter having the shorter-wave emission spectrum serves as co-matrix for the triplet emitter having the longer-wave emission spectrum. For example, it is possible to use the metal complexes of the invention as co-matrix for longer-wave-emitting triplet emitters, for example for green- or red-emitting triplet emitters. In this case, it may also be preferable when both the shorter-wave- and the longer-wave-emitting metal complex is a compound of the invention. Suitable compounds for this purpose are especially also those disclosed in WO 2016/124304 and WO 2017/032439.
Examples of suitable triplet emitters that may be used as co-dopants for the compounds of the invention are depicted in the table below.
The metal complexes of the invention can also be used in other functions in the electronic device, for example as hole transport material in a hole injection or transport layer, as charge generation material, as electron blocker material, as hole blocker material or as electron transport material, for example in an electron transport layer, according to the choice of metal and the exact structure of the ligand. When the metal complex of the invention is an aluminum complex, it is preferably used in an electron transport layer. It is likewise possible to use the metal complexes of the invention as matrix material for other phosphorescent metal complexes in an emitting layer.
Preferred cathodes are metals having a low work function, metal alloys or multilayer structures composed of various metals, for example alkaline earth metals, alkali metals, main group metals or lanthanoids (e.g. Ca, Ba, Mg, Al, In, Mg, Yb, Sm, etc.). Additionally suitable are alloys composed of an alkali metal or alkaline earth metal and silver, for example an alloy composed of magnesium and silver. In the case of multilayer structures, in addition to the metals mentioned, it is also possible to use further metals having a relatively high work function, for example Ag, in which case combinations of the metals such as Mg/Ag, Ca/Ag or Ba/Ag, for example, are generally used. It may also be preferable to introduce a thin interlayer of a material having a high dielectric constant between a metallic cathode and the organic semiconductor. Examples of useful materials for this purpose are alkali metal or alkaline earth metal fluorides, but also the corresponding oxides or carbonates (e.g. LiF, Li2O, BaF2, MgO, NaF, CsF, Cs2CO3, etc.). Likewise useful for this purpose are organic alkali metal complexes, e.g. Liq (lithium quinolinate). The layer thickness of this layer is preferably between 0.5 and 5 nm.
Preferred anodes are materials having a high work function. Preferably, the anode has a work function of greater than 4.5 eV versus vacuum. Firstly, metals having a high redox potential are suitable for this purpose, for example Ag, Pt or Au. Secondly, metal/metal oxide electrodes (e.g. Al/Ni/NiOx, Al/PtOx) may also be preferred. For some applications, at least one of the electrodes has to be transparent or partly transparent in order to enable either the irradiation of the organic material (O-SC) or the emission of light (OLED/PLED, O-LASER). Preferred anode materials here are conductive mixed metal oxides. Particular preference is given to indium tin oxide (ITO) or indium zinc oxide (IZO). Preference is further given to conductive doped organic materials, especially conductive doped polymers, for example PEDOT, PANI or derivatives of these polymers. It is further preferable when a p-doped hole transport material is applied to the anode as hole injection layer, in which case suitable p-dopants are metal oxides, for example MoO3 or WO3, or (per)fluorinated electron-deficient aromatic systems. Further suitable p-dopants are HAT-CN (hexacyanohexaazatriphenylene) or the compound NPD9 from Novaled. Such a layer simplifies hole injection into materials having a low HOMO, i.e. a large HOMO in terms of magnitude.
In the further layers, it is generally possible to use any materials as used according to the prior art for the layers, and the person skilled in the art is able, without exercising inventive skill, to combine any of these materials with the materials of the invention in an electronic device.
The device is correspondingly (according to the application) structured, contact-connected and finally hermetically sealed, since the lifetime of such devices is severely shortened in the presence of water and/or air.
Additionally preferred is an organic electroluminescent device, characterized in that one or more layers are coated by a sublimation process. In this case, the materials are applied by vapor deposition in vacuum sublimation systems at an initial pressure of typically less than 10−5 mbar, preferably less than 10−6 mbar. It is also possible that the initial pressure is even lower or even higher, for example less than 10−7 mbar.
Preference is likewise given to an organic electroluminescent device, characterized in that one or more layers are coated by the OVPD (organic vapor phase deposition) method or with the aid of a carrier gas sublimation. In this case, the materials are applied at a pressure between 10−5 mbar and 1 bar. A special case of this method is the OVJP (organic vapor jet printing) method, in which the materials are applied directly by a nozzle and thus structured.
Preference is additionally given to an organic electroluminescent device, characterized in that one or more layers are produced from solution, for example by spin-coating, or by any printing method, for example screen printing, flexographic printing, offset printing or nozzle printing, but more preferably LITI (light-induced thermal imaging, thermal transfer printing) or inkjet printing. For this purpose, soluble compounds are needed, which are obtained, for example, through suitable substitution. In a preferred embodiment of the invention, the layer comprising the compound of the invention is applied from solution.
The organic electroluminescent device can also be produced as a hybrid system by applying one or more layers from solution and applying one or more other layers by vapor deposition. For example, it is possible to apply an emitting layer comprising a metal complex of the invention and a matrix material from solution, and to apply a hole blocker layer and/or an electron transport layer thereto by vapor deposition under reduced pressure.
It is preferable when the compounds of the invention are processed from solution.
These methods are known in general terms to those skilled in the art and can be applied by those skilled in the art without difficulty to organic electroluminescent devices comprising compounds of formula (1) or (2) or the above-detailed preferred embodiments.
The electronic devices of the invention, especially organic electroluminescent devices, are notable for one or more of the following surprising advantages over the prior art:
These abovementioned advantages are not accompanied by a deterioration in the further electronic properties.
The invention is illustrated in more detail by the examples which follow, without any intention of restricting it thereby. The person skilled in the art will be able to use the details given, without exercising inventive skill, to produce further electronic devices of the invention and hence to execute the invention over the entire scope claimed.
The syntheses which follow, unless stated otherwise, are conducted under a protective gas atmosphere in dried solvents. The metal complexes are additionally handled with exclusion of light or under yellow light. The solvents and reagents can be purchased, for example, from Sigma-ALDRICH or ABCR. The respective figures in square brackets or the numbers quoted for individual compounds relate to the CAS numbers of the compounds known from the literature.
A mixture of 28.1 g (100 mmol) of 2-phenyl-5-(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)pyridine [789291-27-7], 28.2 g (100 mmol) of 1-bromo-2-iodobenzene [583-55-1], 31.8 g (300 mmol) of sodium carbonate, 787 mg (3 mmol) of triphenylphosphine, 225 mg (1 mmol) of palladium(II) acetate, 300 ml of toluene, 150 ml of ethanol and 300 ml of water is heated under reflux for 60 h. After cooling, the mixture is extended with 500 ml of toluene, and the organic phase is removed, washed once with 500 ml of water and once with 500 ml of saturated sodium chloride solution, and dried over magnesium sulfate. After the solvent has been removed, the residue is recrystallized from ethyl acetate/n-heptane or chromatographed on silica gel (toluene/ethyl acetate, 9:1 v/v). Yield: 22.7 g (73 mmol), 73%. Purity: about 97% by 1H NMR.
The compounds which follow can be prepared in an analogous manner, and recrystallization can be accomplished using solvents such as ethyl acetate, cyclohexane, toluene, acetonitrile, n-heptane, ethanol or methanol, for example. It is also possible to use these solvents for hot extraction, or to purify by chromatography on silica gel in an automated column system (Torrent from Axel Semrau).
A mixture of 41.8 g (100 mmol) of 1,3,5-tribromo-2,4,6-trichlorobenzene [13075-02-0], 91.4 g (360 mmol) of bis(pinacolato)diborane [73183-34-3], 88.3 g (900 mmol) of potassium acetate, [1,1′-bis(diphenylphosphino)ferrocene]dichloropalladium(II) [72287-26-4], 1300 ml of 1,4-dioxane and 100 g of glass beads (diameter 3 mm) is heated under reflux for 50 h. The dioxane is removed by rotary evaporation on a rotary evaporator, and the black residue is worked up by extraction in a separating funnel with 1000 ml of ethyl acetate and 500 ml of water. The organic phase is washed once with 300 ml of water and once with 150 ml of saturated sodium chloride solution, and filtered through a silica gel bed. The silica gel is washed twice with 250 ml each time of ethyl acetate. The filtrate is dried over sodium sulfate and concentrated. The residue is chromatographed with heptane/ethyl acetate on silica gel. Yield: 10.6 g (19 mmol), 19%. Purity: about 98% by 1H NMR.
a) S200a—Suzuki Coupling:
A mixture of 55.9 g (100 mmol) of S100, 102.4 g (330 mmol) of S1, 63.3 g (600 mmol) of sodium carbonate, 4.6 g (4 mmol) of tetrakis(triphenylphosphine)palladium(0), 1500 ml of 1,2-dimethoxyethane and 750 ml of water is heated under reflux for 48 h. After cooling, the precipitated solids are filtered off with suction and washed twice with 20 ml of ethanol. The solids are dissolved in 500 ml of dichloromethane and filtered through a Celite bed. The filtrate is concentrated down to 100 ml, then 400 ml of ethanol are added and the precipitated solids are filtered off with suction. The crude product is recrystallized once from ethyl acetate. Yield: 24.3 g (28 mmol), 28%. Purity: about 96% by 1H NMR.
b) S200—Borylation:
A well-stirred mixture of 17.4 g (20 mmol) of S200a, 16.8 g (66 mmol) of bis(pinacolato)diborane [73183-34-3], 19.6 g (120 mmol) of potassium acetate (anhydrous), 50 g of glass beads (diameter 3 mm), 1027 mg (2.4 mmol) of SPhos [657408-07-6], 270 g (1.2 mmol) of palladium(II) acetate and 300 ml of 1,4-dioxane is heated under reflux for 16 h. The dioxane is removed by rotary evaporation on a rotary evaporator, and the black residue is worked up by extraction in a separating funnel with 300 ml of toluene and 200 ml of water. The organic phase is washed once with 100 ml of water and once with 50 ml of saturated sodium chloride solution, and filtered through a Celite bed. The filtrate is dried over sodium sulfate and then concentrated to dryness. The residue is chromatographed with dichloromethane/ethyl acetate on silica gel (Torrent automated column system from A. Semrau). Yield: 13.8 g (12 mmol), 60%. Purity: about 95% by 1H NMR.
The compounds which follow can be prepared in an analogous manner, and recrystallization can be accomplished using solvents such as ethyl acetate, cyclohexane, toluene, acetonitrile, n-heptane, ethanol or methanol, for example. It is also possible to use these solvents for hot extraction, or to purify purified by chromatography on silica gel in an automated column system (Torrent from Axel Semrau).
A mixture of 11.4 g (10.0 mmol) of S200, 12.4 g (40.0 mmol) of S1, 20.7 g (90 mmol) of potassium phosphate monohydrate, 507 mg (0.6 mmol) of XPhos palladacycle Gen.3 [1445085-55-1], 200 ml of tetrahydrofuran and 100 ml of water is heated under reflux for 20 h. After cooling, the precipitated solids are filtered off with suction and washed twice with 30 ml each time of water and twice with 30 ml each time of ethanol. The solids are dissolved in 200 ml of dichloromethane (DCM) and filtered through a silica gel bed in the form of a DCM slurry. The filtrate is concentrated, and the residue is chromatographed with dichloromethane/ethyl acetate on silica gel (Torrent automated column system from A. Semrau). Yield: 2.5 g (2.2 mmol) 22%. Purity: about 95% by 1H NMR.
The compounds which follow can be prepared in an analogous manner, and recrystallization can be accomplished using solvents such as ethyl acetate, cyclohexane, toluene, acetonitrile, n-heptane, ethanol or methanol, for example. It is also possible to use these solvents for hot extraction, to purify purified by chromatography on silica gel in an automated column system (Torrent from Axel Semrau).
Ir2(L1)
A mixture of 14.6 g (10 mmol) of ligand L1, 9.9 g (20 mmol) of trisacetylacetonatoiridium(III) [15635-87-7] and 150 g of hydroquinone [123-31-9] is initially charged in a 1000 ml two-neck round-bottom flask with a glass-sheathed magnetic bar. The flask is provided with a water separator (for media of lower density than water) and an air condenser with argon blanketing and placed into a metal heating bath. The apparatus is purged with argon from the top via the argon blanketing system for 15 min, allowing the argon to flow out of the side neck of the two-neck flask. Through the side neck of the two-neck flask, a glass-sheathed Pt-100 thermocouple is introduced into the flask and the end is positioned just above the magnetic stirrer bar. Then the apparatus is thermally insulated with several loose windings of domestic aluminum foil, the insulation being run up to the middle of the riser tube of the water separator. Then the apparatus is heated rapidly with a heated laboratory stirrer system to 250° C., measured with the Pt-100 thermal sensor which dips into the molten stirred reaction mixture. Over the next 2 h, the reaction mixture is kept at 250° C., in the course of which a small amount of condensate is distilled off and collects in the water separator. The reaction mixture is left to cool down to 190° C., then 100 ml of ethylene glycol are added dropwise. The mixture is left to cool down further than to 80° C., then 500 ml of methanol are added dropwise and the mixture is heated at reflux for 1 h. The suspension thus obtained is filtered through a double-ended frit, and the solids are washed twice with 50 ml of methanol and then dried under reduced pressure. Further purification is effected by hot extraction five times with dichloromethane (amount initially charged in each case about 350 ml, extraction thimble: standard Soxhlet thimbles made from cellulose from Whatman) with careful exclusion of air and light. Finally, heat treatment is effected at 300° C. under high vacuum. Yield: 10.5 g (5.7 mmol), 57%. Purity: >99.9% by 1H NMR.
ΔΔ and ∧∧ isomers are obtained, which are enantiomeric and form a racemate. Racemate separation into the two enantiomers is possible by standard methods, such as chromatography on chiral media or fractional crystallization, for example with chiral acids (e.g. camphorsulfonic acid).
The compounds shown below can be synthesized in an analogous manner. The compounds can in principle be purified by chromatography (typically use of an automated column system (Torrent from Axel Semrau), recrystallization or hot extraction). Residual solvents can be removed by heat treatment under high vacuum at typically 250-330° C.
In an analogous manner, by the addition of first 10 mmol of Ir(acac)3 and conducting the reaction at 250° C. for 1 h and then addition of 10 mmol of Rh(acac)3 [14284-92-5] and continuing the reaction at 250° C. for 1 h and subsequent workup and purification as described above, it is possible to obtain mixed metallic Rh—Ir complexes.
1) Halogenation of the Iridium Complexes:
To a solution or suspension of 1 mmol of a complex bearing A×C—H groups (with A=1-6) in the para position to the iridium in the bidentate sub-ligand in 200 ml to 2000 ml of dichloromethane according to the solubility of the metal complexes is added, in the dark and with exclusion of air, at −30 to +30° C., A×1.05 mmol of N-halosuccinimide (halogen: Cl, Br, I), and the mixture is stirred for 20 h. Complexes of sparing solubility in DCM may also be converted in other solvents (TCE, THF, DMF, chlorobenzene, etc.) and at elevated temperature. Subsequently, the solvent is substantially removed under reduced pressure. The residue is extracted by boiling with 30-100 ml of methanol, and the solids are filtered off with suction, washed three times with 20 ml of methanol and then dried under reduced pressure. This gives the iridium complexes brominated/halogenated in the para position to the iridium. Complexes having a HOMO (CV) of about −5.1 to −5.0 eV and of smaller magnitude have a tendency to oxidation (Ir(III)→Ir(IV)), the oxidizing agent being bromine released from NBS. This oxidation reaction is apparent by a distinct green hue or brown hue in the otherwise yellow to red solutions/suspensions of the emitters. In such cases, 1-2 further equivalents of NBS are added. For workup, 30-100 ml of methanol and 0.5 ml of hydrazine hydrate as reducing agent are added, which causes the green or brown solution or suspension to turn yellow or red (reduction of Ir(IV)→Ir(III)). Then the solvent is substantially drawn off under reduced pressure, 50 ml of methanol are added, and the solids are filtered off with suction, washed three times with 20 ml each time of methanol and dried under reduced pressure.
Substoichiometric brominations, for example mono-, dibrominations etc., of complexes having 6 C—H groups para position the iridium atoms usually proceed less selectively than the stoichiometric brominations. The crude products of these brominations can be separated by chromatography (CombiFlash Torrent from A. Semrau).
To a suspension of 1.61 g (1.0 mmol) of Ir2(L1) in 200 ml of DCM are added 1.16 g (6.5 mmol) of N-bromosuccinimide (NBS) all at once and then the mixture is stirred for 20 h. 0.5 ml of hydrazine hydrate in 30 ml of MeOH is added. After removing about 180 ml of the solvent under reduced pressure, the yellow solids are filtered off with suction, washed three times with about 20 ml of methanol and then dried under reduced pressure. Yield: 2.02 g (0.97 mmol), 97%; purity: >99.5% by NMR.
The following compounds can be synthesized in an analogous manner:
2) Suzuki Coupling with the Brominated Iridium Complexes:
Variant A, Biphasic Reaction Mixture
To a suspension of 1 mmol of a brominated complex, 1.2-2 mmol of boronic acid or boronic ester per Br function and 6-10 mmol of tripotassium phosphate in a mixture of 50 ml of toluene, 20 ml of dioxane and 50 ml of water are added 0.36 mmol of tri-o-tolylphosphine and then 0.06 mmol of palladium(II) acetate, and the mixture is heated under reflux for 16 h. After cooling, 50 ml of water and 50 ml of toluene are added, the aqueous phase is removed, and the organic phase is washed three times with 50 ml of water and once with 50 ml of saturated sodium chloride solution and dried over magnesium sulfate. The mixture is filtered through a Celite bed in the form of a toluene slurry and washed through with toluene, the toluene is removed almost completely under reduced pressure, 50 ml of methanol are added, and the precipitated crude product is filtered off with suction, washed three times with 30 ml each time of methanol and dried under reduced pressure. The crude product is columned on silica gel in an automated column system (Torrent from Semrau). Subsequently, the complex is purified further by hot extraction in solvents such as ethyl acetate, toluene, dioxane, acetonitrile, cyclohexane, ortho- or para-xylene, n-butyl acetate, chlorobenzene etc. Alternatively, it is possible to recrystallize from these solvents and high boilers such as dimethylformamide, dimethyl sulfoxide or mesitylene. The metal complex is finally heat-treated or sublimed. The heat treatment is effected under high vacuum (p about 10−6 mbar) within the temperature range of about 200-300° C.
Variant B, Monophasic Reaction Mixture:
To a suspension of 1 mmol of a brominated complex, 1.2-2 mmol of boronic acid or boronic ester per Br function and 2-4 mmol of the base per Br function (potassium fluoride, tripotassium phosphate (anhydrous, monohydrate or trihydrate), potassium carbonate, cesium carbonate etc.) and 10 g of glass beads (diameter 3 mm) in 30-50 ml of an aprotic solvent (THF, dioxane, xylene, mesitylene, dimethylacetamide, NMP, DMSO, etc.) is added 0.01 mmol per Br function of tetrakis(triphenylphosphine)palladium(0) [14221-01-3], and the mixture is heated under reflux for 24 h. Alternatively, it is possible to use other phosphines such as triphenylphosphine, tri-tert-butylphosphine, SPhos, XPhos, RuPhos, XanthPhos, etc. in combination with Pd(OAc)2, the preferred phosphine:palladium ratio in the case of these phosphines being 3:1 to 1.2:1. The solvent is removed under reduced pressure, the product is taken up in a suitable solvent (toluene, dichloromethane, ethyl acetate, etc.) and purification is effected as described in Variant A.
In the case of sparingly soluble reactant complexes, it may be advantageous first to conduct the Suzuki coupling by variant B and to subject the crude product obtained to another Suzuki coupling by variant A in order to achieve maximum conversion. After the crude product has been isolated, trace contaminations by remaining bromine can be removed by boiling the crude product in 100 ml of toluene with addition of 10 mg of palladium(II) acetate and 1 ml of hydrazine hydrate for 16 h. Thereafter, the crude product is purified as described above.
Variant B:
Use of 2.08 g (1.0 mmol) of Ir(L1-6Br) and 2.31 g (12.0 mmol) of [4-(2,2-dimethylpropyl)phenyl]boronic acid [186498-04-4], 4.15 g (18.0 mmol) of tripotassium phosphate monohydrate, 70 mg (0.06 mmol) of tetrakis(triphenylphosphine)palladium(0), 50 ml of dry dimethyl sulfoxide, 100° C., 16 h. Chromatographic separation on silica gel with DCM/n-heptane (automated column system, Torrent from Axel Semrau), followed by hot extraction five times with toluene. Yield: 1.44 g (0.53 mmol), 53%. Purity: about 99.9% by HPLC.
In an analogous manner, it is possible to prepare the following compounds:
Table 1 summarizes the thermal and photochemical properties and oxidation potentials of the comparative materials and the selected materials of the invention. The compounds of the invention have improved thermal stability and photostability compared to the non-polypodal materials according to the prior art. While non-polypodal materials according to the prior art exhibit brown discoloration and ashing after thermal storage at 380° C. for 7 days and secondary components in the region of >2 mol % can be detected in the 1H NMR, the complexes of the invention are inert under these conditions. In addition, the compounds of the invention have very good photostability in anhydrous C6D6 solution under irradiation with light of wavelength about 455 nm. More particularly, in contrast to non-polypodal prior art complexes containing bidentate ligands, no facial-meridional isomerization is detectable in the 1H NMR. As can be inferred from Table 1, the compounds of the invention in solution show universally very high photoluminescence quantum efficiencies (PLQE).
Production of the OLEDs
The complexes of the invention can be processed from solution and lead, compared to vacuum-processed OLEDs, to more easily producible OLEDs having properties that are nevertheless good. There are already many descriptions of the production of completely solution-based OLEDs in the literature, for example in WO 2004/037887. There have likewise been many previous descriptions of the production of vacuum-based OLEDs, including in WO 2004/058911. In the examples discussed hereinafter, layers applied in a solution-based and vacuum-based manner are combined within an OLED, and so the processing up to and including the emission layer is effected from solution and the subsequent layers (hole blocker layer and electron transport layer) from vacuum. For this purpose, the previously described general methods are matched to the circumstances described here (layer thickness variation, materials) and combined as follows. The general structure is as follows: substrate/ITO (50 nm)/hole injection layer (HIL)/hole transport layer (HTL)/emission layer (EML)/hole blocker layer (HBL)/electron transport layer (ETL)/cathode (aluminum, 100 nm). Substrates used are glass plates coated with structured ITO (indium tin oxide) of thickness 50 nm. For better processing, they are coated with PEDOT:PSS (poly(3,4-ethylenedioxy-2,5-thiophene) polystyrenesulfonate, purchased from Heraeus Precious Metals GmbH & Co. KG, Germany). PEDOT:PSS is spun on from water under air and subsequently baked under air at 180° C. for 10 minutes in order to remove residual water. The hole transport layer and the emission layer are applied to these coated glass plates. The hole transport layer used is crosslinkable. A polymer of the structures shown below is used, which can be synthesized according to WO 2010/097155 or WO 2013/156130:
The hole transport polymer is dissolved in toluene. The typical solids content of such solutions is about 5 g/I when, as here, the layer thickness of 20 nm which is typical of a device is to be achieved by means of spin-coating. The layers are spun on in an inert gas atmosphere, argon in the present case, and baked at 180° C. for 60 minutes.
The emission layer is always composed of at least one matrix material (host material) and an emitting dopant (emitter). In addition, mixtures of a plurality of matrix materials and co-dopants may occur. Details given in such a form as TMM-A (92%):dopant (8%) mean here that the material TMM-A is present in the emission layer in a proportion by weight of 92% and dopant in a proportion by weight of 8%. The mixture for the emission layer is dissolved in toluene or optionally chlorobenzene. The typical solids content of such solutions is about 17 g/l when, as here, the layer thickness of 60 nm which is typical of a device is to be achieved by means of spin-coating. The layers are spun on in an inert gas atmosphere, argon in the present case, and baked at 150° C. for 10 minutes. The materials used in the present case are shown in Table 2.
The materials for the hole blocker layer and electron transport layer are applied by thermal vapor deposition in a vacuum chamber. The electron transport layer, for example, may consist of more than one material, the materials being added to one another by co-evaporation in a particular proportion by volume. Details given in such a form as ETM1:ETM2 (50%:50%) mean here that the ETM1 and ETM2 materials are present in the layer in a proportion by volume of 50% each. The materials used in the present case are shown in Table 3.
The cathode is formed by the thermal evaporation of a 100 nm aluminum layer. The OLEDs are characterized in a standard manner. For this purpose, the electroluminescence spectra, current-voltage-luminance characteristics (IUL characteristics) assuming Lambertian radiation characteristics and the operating lifetime are determined. The IUL characteristics are used to determine parameters such as the operating voltage (in V) and the efficiency (cd/A) at a particular brightness. The electroluminescence spectra are measured at a luminance of 1000 cd/m2, and the CIE 1931 x and y color coordinates are calculated therefrom. The lifetime is defined as the time after which the luminance has fallen from a particular starting luminance to a certain proportion. The figure LT90 means that the lifetime specified is the time at which the luminance has dropped to 90% of the starting luminance, i.e. from, for example, 1000 cd/m2 to 900 cd/m2. According to the emission color, different starting brightnesses are chosen. The values for the lifetime can be converted to a figure for other starting luminances with the aid of conversion formulae known to those skilled in the art. In this context, the lifetime for a starting luminance of 1000 cd/m2 is a standard figure. Alternatively, lifetimes can be determined for a particular initial current, e.g. 60 mA/cm2. The EML mixtures and structures of the OLED components examined are shown in tables 4 and 5. The corresponding results can be found in table 6.
The following inventive compounds Ir2(L2), Ir2(L3), Ir2(L4), Ir2(L6), Ir2(L7), Ir2(L8), Ir2(L9), Ir2(L10), Ir2(L11), Ir2(L12), Ir2(L13), Ir2(L14), Ir2(L15), Ir2(L16), Ir2(L17), Ir2(L18), Ir2(L19), Ir2(L20), Ir2(L21), Ir2(L22), Ir2(L23), Ir2(L24), Ir2(L25), Ir2(L26), Ir2(L27), Ir2(L28), Ir2(L29), Rh—Ir(L4), Ir22, Ir24, Ir25, Ir27, Ir28, Ir29, Ir210, Ir211, Ir213, Ir214, Ir215 can likewise be incorporated in OLED devices and show yellow-green or red electroluminescence, good efficiencies and long lifetimes.
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|---|---|---|---|
| PCT/EP2017/075581 | 10/9/2017 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2018/069197 | 4/19/2018 | WO | A |
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