Electroluminescent device

Electric lamp and discharge devices – With luminescent solid or liquid material – Solid-state type

Reexamination Certificate

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C428S690000

Reexamination Certificate

active

06384528

ABSTRACT:

BACKGROUND OF THE INVENTION
This invention relates to electroluminescent devices, especially those that have a conjugated polymer as a light-emitting layer.
One type of electroluminescent device is described in PCT/W090/13148, the contents of which are incorporated herein by reference. The basic structure of this device is a light-emitting polymer film (for instance a film of a poly(p-phenylenevinylene)—“PPV”) sandwiched between two electrodes, one of which injects electrons and the other of which injects holes. It is believed that the electrons and holes excite the polymer film, emitting photons. These devices are useful as flat panel displays, in which case one of the electrodes is transparent—for example being made of indium-tin oxide (“ITO”).
Numerous structures have been developed in which there are two or more organic layers between the electrodes. For example, EP 0 653 149 discloses devices having several organic light-emissive semiconductor polymer layers, each of a different band-gap. In these devices all of the light-emissive layers emit significantly when the device is in use. This makes it complex to precisely tailor the output of such a device precisely.
In other devices the organic layer between the electrodes is formed as a blend of a light-emitting organic material with another material, such as polyvinylcarbazole (“PVK”). (See, for example, J Kido et al., Appl. Phys. Left. 67 (1995) 2281). Trap states in the PVK can be used to help localise charge-carriers and excited states and thereby suppress diffusion of these states and energy transfer to lower energy sites within the PVK/emitter blend or to an adjacent layer.
Organic light emitting materials have potential for multi-colour displays, for example with each pixel of the display having red-, green- and blue-emitting sub-pixels. However, manufacturing such a display in which each sub-pixel emits light as an individual electroluminescent device has been thought to require optimisation of the charge-injecting layers for each colour. This would be very complex. Therefore, one solution has been to provide a single electroluminescent layer (e.g. a blue-emitting layer) which can initiate light emission for each sub-pixel. The sub-pixels that are required to emit light of the other colours (e.g. red and green) are provided with fluorescent layers of those colours, located outside the charge-injecting layers of the device, to convert emissions from the electroluminescent layer by absorbing and re-emitting photons. (See, for example, C Hosokawa et al., 49th Annual Conference of the Society for Imaging Science and Technology, May 1996, Minneapolis, p388). This approach reduces the overall efficiency of the device.
SUMMARY OF THE INVENTION
According to one aspect of the present invention there is provided an electroluminescent device comprising: a first charge-carrier injecting layer for injecting positive charge-carriers; a second charge-carrier injecting layer for injecting negative charge-carriers; a layer of a first organic material located between the charge-carrier injecting layers; and located between the layer of a first organic material and one of the charge-carrier injecting layers: a first light-emissive region comprising a light-emissive second organic material having an energy-gap less than that of the first organic material; and a second light-emissive region comprising a first component of a light-emissive third organic material having an energy-gap greater than that of the first organic material, and a second component having at least one energy level off-set from that of the first component; such that when charge-carriers are injected in the first region by the charge-carrier injecting layers light is emitted principally from the second organic material and when charge-carriers are injected in the second region by the charge-carrier injecting layers light is emitted principally from the third organic material.
The or each energy level may be a conduction band (lumo) energy level and/or a valence band (homo) energy level and/or an additional energy level, such as a trap state, within the band gap.
Preferably the said one of the charge-injecting layers is the first charge-injecting layer and the other of the charge-injecting layers is the second charge-injecting layer.
The first charge-carrier injecting layer is preferably formed of a transparent material. The first charge-carrier injecting layer is preferably conductive, most preferably a conductive oxide such as ITO.
The second charge-carrier injecting layer is preferably formed of a low work-function metal or alloy. The metal or alloy preferably has a work function of less than 3.5eV, most preferably less than 3eV. The layer preferably comprises calcium and/or lithium. The layer is suitably deposited by evaporation or sputtering, most preferably DC magnetron sputtering.
The first organic material is suitably a partially or fully conjugated material. It is preferably a polymer, and most preferably a semiconductive conjugated polymer such as PPV, which could be derived from a precursor route. The first organic material is preferably a light-emissive material, being capable of emitting light by means of, for example, molecules, oligomers or polymers.
The term “conjugated” indicates a polymer for which the main chain is either fully conjugated, possessing extended pi molecular orbitals along the length of the chain, or is substantially conjugated, but with interruptions to conjugation at various positions, either random or regular, along the main chain. It includes within its scope homopolymers and copolymers.
The composition of the second light-emissive region, suitably together with the thickness selected for the layer of a first organic material, preferably acts to suppress (and most preferably to suppress essentially) light emission from the layer of a first organic material. This approach suitably allows the same layer of a first organic material, and preferably also the same charge-carrier injecting layer, to overly the first and second light-emissive regions without significantly compromising the emission colouros of the first and second light-emissive regions.
The thickness of the layer of a first organic material is suitably less than 500Å and preferably less than or around 200Å.
The layer of a first organic material preferably abuts one of the charge-carrier injecting layers, suitably that for injecting negative charge-carriers.
The layer of a first organic material may also be amenable to sputter deposition, most preferably being resistant to degradation during a sputter deposition operation—for example during sputter deposition of a subsequent and/or adjacent layer. The layer of a first organic material is preferably capable of acting as a sputter protection layer for another layer of the device. For example, the layer of a first organic material may serve to protect the material of one or both of the first and second light-emissive regions from damage during sputter deposition of one of the charge-carrier injecting layers, suitably the one (if any) that abuts the layer of a first organic material.
Thus, according to the present invention from a second aspect there is provided a method for producing an electroluminescent device, comprising the steps of: depositing a first charge-carrier injecting layer for injecting positive charge-carriers; depositing a first light-emissive region comprising a light-emissive first organic material; and depositing a second light-emissive region comprising a first component of a light-emissive second organic material, and a second component having at least one energy level off-set from that of the first component; depositing a layer of a third organic material resistant to degradation during a sputter deposition process and having an energy gap greater than that of the first organic material and less than that of the second organic material; and depositing a second charge-carrier injecting layer for injecting negative charge-carriers; to provide a device such that when charge-carriers are injected i

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