Patent Description:
An organic luminescent device is a device which spontaneously emits light. When charges are injected into an organic film between an electron injection electrode (an anode) and a hole injection electrode (a cathode), electrons and holes are combined and then annihilated to produce light. As compared to other flat display technologies such as liquid crystal display, plasma display device and field emission display, organic electroluminescent display has a series of excellent properties such as tunable luminescence color, active luminescence, high brightness, high efficiency, wide view angle, low energy consumption, simple preparation process, capability of preparing curved and flexible display screen, and so on, and has a wide application prospect in the field of large planar flat panel full color display, so it is considered as the most competitive new generation display technology. Therefore, research on organic electroluminescent technology has attracted more and more attentions and active participation of scientists and technicians in scientific community and industry community, such that the performances of organic electroluminescent device have been developed rapidly over the past decade. Among others, blue organic electroluminescent devices have become hot spots of investigation due to the wide prospect for application in terms of monochrome display, white light modulation, or the like.

R&D (Research and Development) and design of high performance and high quality pure blue organic electroluminescent device have always been key and difficult point in the field. Transition metal complexes are regarded as ideal organic electroluminescent material by the academic community and industry community, due to their advantages such as high luminescence efficiency, tunable luminescence color, and so on. Many research groups, both domestic and abroad, set about material synthesis and device optimization, trying to improve the overall performances of blue organic electroluminescent devices in order to satisfy the requirements for industrialization. However, blue organic electroluminescent devices obtained based on transition metal complexes are usually accompanied by low color purity, low operating life, or low luminescence efficiency. Therefore, more and more research groups tend to replace blue transition metal complexes with blue fluorescence luminescent materials to obtain pure blue fluorescence organic electroluminescent devices. However, pure blue fluorescent materials generally have low luminescence efficiency. In addition, relatively wide energy gap of pure blue fluorescent materials results in great inconvenience for the screening of host materials, finally leading to unbalanced injection, transport and distribution of carriers. As a result, the blue luminescent devices prepared have relatively low luminescence efficiency and relatively high operation voltage.

In order to solve these problems, domestic and abroad research groups devote themselves to design of new pure blue luminescent material and optimization of blue luminescent device structure. For example, <NPL>, which reported that a relatively stable pure blue luminescent device was obtained by incorporating trace amount of <NUM>-hydroxylquinoline aluminum (AlQ), an electron transport material, into N,N'-di(<NUM>-naphthyl)-N,N'-diphenyl-<NUM>,<NUM>'-biphenyl-<NUM>,<NUM>'-diamine (NPB), a hole transport material emitting pure blue light. However, the device obtained had low luminescence efficiency, limiting its wide application in lighting and display fields. In <NPL> that a new deep blue fluorescent material was developed and an excellent deep blue luminescent device was obtained. Although the deep blue device obtained had very excellent color purity and color stability, the high operation voltage thereof not only directly resulted in low power efficiency of the device, but also indirectly reduced the operation stability of the device. Other examples of blue luminescent materials and blue luminescent devices are shown in the following patent documents: <CIT>, <CIT> and <CIT>.

Thus, the overall performances of pure blue organic electroluminescent device comprising color purity, luminescence efficiency, operation stability and so on have not been substantially improved yet.

In view of the above, the technical problem to be solved by the present invention is to provide a blue organic electroluminescent device and a preparation method thereof. The blue organic electroluminescent device has simple structure, and relatively high efficiency, luminance and operation stability.

The present invention provides a blue organic electroluminescent device, comprising:.

Preferably, the light emitting layer has a thickness of from <NUM> to <NUM>.

Preferably, an anode interface layer is further disposed between the anode layer and the light emitting layer, wherein the anode interface layer has a thickness of from <NUM> to <NUM>.

Preferably, a hole transport layer or electron blocking layer is further disposed between the anode layer and the light emitting layer, wherein the hole transport layer or electron blocking layer has a thickness of from <NUM> to <NUM>. In the presence of the anode interface layer, the hole transport layer or electron blocking layer is disposed between the anode interface layer and the light emitting layer.

Preferably, a hole blocking layer or electron transport layer is further disposed between the light emitting layer and the cathode layer, wherein the hole blocking layer or electron transport layer has a thickness of from <NUM> to <NUM>.

Preferably, a buffer layer is further disposed between the hole blocking layer or electron transport layer and the cathode layer, wherein the buffer layer has a thickness of from <NUM> to <NUM>.

The present invention further provides a preparation method of a blue organic electroluminescent device, comprising:.

The present invention provides a blue organic electroluminescent device comprising: a substrate; an anode layer disposed on the substrate; a light emitting layer disposed on the anode layer, the light emitting layer being formed from a blue organic fluorescent material and a hole-type organic host material, wherein the blue organic fluorescent material is <NUM>% to <NUM>% by mass of the hole-type organic host material, and an excited state energy of the blue organic fluorescent material is lower than an excited state energy of the hole-type organic host material; and a cathode layer disposed on the light emitting layer, wherein the blue organic fluorescent material is <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole], and the hole-type organic host material is one or more selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM> ,<NUM>-tri (<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl. As compared to prior art, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material with an excited state energy lower than that of the hole-type organic host material selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM> ,<NUM>-tri (<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl, is used as luminescent material in the present invention, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material having both high luminescence efficiency and high color purity as well as good thermostability, such that the color purity and efficiency of the device can be ensured. Meanwhile, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material also has excellent electron transport capability, and as it is doped in the light emitting layer at a high concentration, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material can function as both a host material and a blue luminescent material, which is beneficial for balancing the distribution of holes and electrons in the light emitting region, can confine the recombination of holes and electrons within the narrow region of the light emitting layer, and can effectively balance the distribution of carriers in the light emitting layer. In addition, the device provided in the present invention has simple structure and low cost, and all materials thereof have good thermostability, which is beneficial for improving the lifetime of the device.

The technical solutions in embodiments of the present invention will be detailedly described below in combination with the embodiments of the present invention. Obviously, the embodiments described are only a part of, not all of the embodiments of the present invention.

There are no particular requirements on the substrate in the present invention, as long as it is a well-known substrate for those skilled in the art. The substrate is preferably a plastic substrate, a polymer substrate, a silicon-based substrate or a glass substrate, and more preferably a glass substrate.

An anode layer is disposed on the substrate. The anode layer is formed from a material into which holes can be easily injected, preferably a conductive metal, a conductive metal oxide, or graphene, more preferably indium tin oxide, gold electrode, platinum electrode or graphene electrode, and still more preferably indium tin oxide. The indium tin oxide preferably has a surface resistance of <NUM> to <NUM> ohm.

According to the present invention, an anode interface layer is preferably further disposed on the anode layer. The anode interface layer preferably has a thickness of <NUM> to <NUM>, more preferably <NUM> to <NUM>, still more preferably <NUM> to <NUM>, and the most preferably <NUM>. The anode interface layer is not specifically limited, as long as it is a well-known anode interface layer for those skilled in the art. In the present invention, the anode interface layer is preferably molybdenum trioxide, lithium fluoride or sodium chloride.

In order to improve hole transport capability and meanwhile block electron transport so as to reduce the loss of the device and improve the efficiency of the device, a hole transport layer or electron blocking layer is preferably disposed on the anode interface layer. The hole transport layer or electron blocking layer preferably has a thickness of <NUM> to <NUM>, and more preferably <NUM> to <NUM>. The hole transport layer or electron blocking layer is not specifically limited, as long as it is a well-known hole transport layer or electron blocking layer for those skilled in the art. In the present invention, the hole transport layer or electron blocking layer is preferably formed from one or more selected from the group consisting of <NUM>,<NUM>'-cyclohexylidene-bis[N,N-bis(<NUM>-methylphenyl)aniline] (TAPC), <NUM>,<NUM>'-bis[N-(m-tolyl)-N-phenyl-amino]biphenyl (TPD) and N,N'-di(<NUM>-naphtyl)-N,N'-diphenyl-<NUM>,<NUM>'-biphenyl-<NUM>,<NUM>'-diamine (NPB), the molecular structural formulae of which are shown as follows:
<CHM>
<CHM>.

A light emitting layer is disposed on the hole transport layer or electron blocking layer. The light emitting layer is formed from a blue organic fluorescent material and a hole-type organic host material, wherein the blue organic fluorescent material is <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole], and the hole-type organic host material is one or more selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM> ,<NUM>-tri (<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl.

The light emitting layer preferably has a thickness of <NUM> to <NUM>, more preferably <NUM> to <NUM>, still more preferably <NUM> to <NUM>, and the most preferably <NUM>. The blue organic fluorescent material is <NUM>% to <NUM>%, preferably <NUM>% to <NUM>%, more preferably <NUM>% to <NUM>%, and even more preferably <NUM>% to <NUM>% by mass of the hole-type organic host material. The blue organic fluorescent material is a blue organic fluorescent material with matched energy and energy level. One basic principle for energy matching is that energy can be effectively transferred from the host material to the luminescent material, which requires that the excited state energy of the host material is greater than the excited state energy of the luminescent material. One basic principle for energy level matching is that the host material has a wide energy gap, which can effectively include the energy gap of the luminescent material so as to facilitate capture of carriers. In the present invention, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material has an energy level favorable for electron injection into the light emitting region, and meanwhile function as an electron-type auxiliary host material. In the present invention, the blue organic fluorescent material is <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] (DBzA, with a molecular formula as shown in formula I). The blue organic fluorescent material DBzA is the luminescent material, as it has both high luminescence efficiency and high color purity as well as good thermostability, and meanwhile has excellent electron transport capability, capable of effectively balancing the distribution of carriers in the light emitting layer. The hole-type organic host material is selected from the group of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl (CBP, with a molecular formula as shown in formula II), <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene (mCP, with a molecular formula as shown in formula III), <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole (SimCP, with a molecular formula as shown in formula IV), <NUM>,<NUM>,<NUM>-tri(<NUM>-carbazolyl)benzene (TCP, with a molecular formula as shown in formula V), <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine (TcTa, with a molecular formula as shown in formula VI) and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl (BSB, with a molecular formula as shown in formula VII). <CHM>
<CHM>
<CHM>
<CHM>.

In order to improve electron transport capability and meanwhile block hole transport so as to reduce the loss of the device and improve the efficiency of the device, a hole blocking layer or electron transport layer is preferably further disposed on the light emitting layer. The hole blocking layer or electron transport layer preferably has a thickness of <NUM> to <NUM>, more preferably <NUM> to <NUM>, and still more preferably <NUM> to <NUM>. The hole blocking layer or electron transport layer is not specifically limited, as long as it is a well-known hole blocking layer or electron transport layer for those skilled in the art. In the present invention, the hole blocking layer or electron transport layer is preferably formed from one or more selected from the group consisting of tris[<NUM>,<NUM>,<NUM>-trimethyl-<NUM>-(<NUM>-pyridyl)phenyl]borane (3TPYMB), <NUM>,<NUM>,<NUM>-tri[(<NUM>-pyridyl)-<NUM>-phenyl]benzene (TmPyPB), <NUM>,<NUM>-bis[<NUM>,<NUM>-di(<NUM>-pyridyl)phenyl]benzene (BmPyPhB), <NUM>,<NUM>,<NUM>-tris(<NUM>-phenyl-<NUM>-benzoimidazol-<NUM>-yl)benzene (TPBi) and <NUM>,<NUM>,<NUM>-tris{<NUM>-[<NUM>-(pyridin-<NUM>-yl)phenyl]pyridin-<NUM>-yl}benzene (Tm3PyP26PyB), the molecular formulae of which are as shown in formulae VIII, IX, X, XI and XII. <CHM>
<CHM>
<CHM>.

In order to increase the electron injection efficiency to further improve the efficiency of the device, a buffer layer is preferably further disposed on the hole blocking layer or electron transport layer. The buffer layer preferably has a thickness of <NUM> to <NUM>, more preferably <NUM> to <NUM>, and still more preferably <NUM>. The buffer layer is not specifically limited, as long as it is a well-known buffer layer for those skilled in the art. In the present invention, the buffer layer is preferably formed from lithium fluoride, sodium chloride or sodium carbonate.

A cathode layer is disposed on the buffer layer. The cathode layer preferably has a thickness of <NUM> to <NUM>, more preferably <NUM> to <NUM>, still more preferably <NUM> to <NUM>, and the most preferably <NUM>. The cathode layer is not specifically limited, as long as it is a well-known cathode layer for those skilled in the art. In the present invention, the cathode layer is preferably formed from metal aluminum, magnesium silver alloy or silver.

A schematic structural diagram of the blue organic electroluminescent device provided in the present invention is as shown in <FIG>, wherein <NUM> represents a substrate, <NUM> represents an anode layer, <NUM> represents an anode interface layer, <NUM> represents a hole transport layer/electron blocking layer, <NUM> represents a light emitting layer, <NUM> represents a hole blocking layer/electron transport layer, <NUM> represents a buffer layer, and <NUM> represents a cathode layer. The anode and the cathode of the blue organic electroluminescent device are overlapped with each other to form a light emitting region. When a positive voltage is applied between these two electrodes, the device will emit a pure blue light with a main emission peak around <NUM>.

In the present invention, <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material with an excited state energy lower than that of hole-type organic host material selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM> ,<NUM>-tri (<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl, is used as a luminescent material, wherein the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material has both high luminescence efficiency and high color purity as well as good thermostability. As a result, the color purity and efficiency of the device can be ensured. Meanwhile, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material also has excellent electron transport capability, and as it is doped in the light emitting layer at a high concentration, the <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material can function as both a host material and a blue luminescent material, which is beneficial for balancing the distribution of holes and electrons in the light emitting region, can confine the recombination of holes and electrons within the narrow region of the light emitting layer, and can effectively balance the distribution of carriers in the light emitting layer. In addition, the device provided in the present invention has simple structure and low cost, and all materials thereof have good thermostability, which is beneficial for improving the lifetime of the device.

The present invention also provides a preparation method of the above blue organic electroluminescent device, comprising the following steps:.

According to the present invention, an anode layer is firstly formed on a substrate. The substrate and the anode layer are as described above, and will not be reiterated here. In the present invention, the electrode is preferably obtained by etching the conductive metal, conductive metal oxide, or graphene on the substrate. The shape and size of the electrode formed by etching are not specifically limited in the present invention. For example, a strip electrode with a width of <NUM> and a length of <NUM> may be formed by etching.

Then, an anode interface layer is preferably formed on the anode layer. The anode interface layer is as described above and will not be reiterated here. In the present invention, preferably, the substrate with the anode layer formed thereon is washed and dried, and then the anode interface layer is formed on the anode layer. The process for forming the anode interface layer is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, preferably, the dried substrate with the anode layer formed is firstly subjected to a low pressure oxygen plasma treatment under vacuum condition, and then the anode interface layer is vapor deposited thereon. The vacuum degree for the vacuum condition is preferably <NUM> to <NUM> Pa. The voltage for the low pressure oxygen plasma treatment is <NUM> to <NUM> V. The time for the low pressure oxygen plasma treatment is preferably <NUM> to <NUM>. The vacuum degree for the vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa.

Then, a hole transport layer or electron blocking layer is preferably formed on the anode interface layer. The hole transport layer or electron blocking layer is as described above and will not be reiterated here. The forming process is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, the process is preferably a vacuum vapor deposition process. The vacuum degree for the vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. The evaporation rate of organic material in the vacuum vapor deposition is preferably <NUM> to <NUM>/s.

Then, a light emitting layer is formed on the hole transport layer or electron blocking layer. The light emitting layer is as described above and will not be reiterated here. The forming process is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, the process is preferably a vacuum vapor deposition process. The vacuum degree for the vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. The evaporation rate of blue organic fluorescent material in the vacuum vapor deposition is preferably <NUM> to <NUM>/s. The evaporation rate of hole-type organic host material in the vacuum vapor deposition is preferably <NUM> to <NUM>/s. The <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole] blue organic fluorescent material and the hole-type organic host material selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM> ,<NUM>-tri (<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl, in the mixed organic material are evaporated simultaneously from different evaporation sources. The evaporation rates of these two materials are adjusted such that the blue organic fluorescent material is <NUM>% to <NUM>% by mass of the hole-type organic host material.

According to the present invention, a hole blocking layer or electron transport layer is preferably formed on the light emitting layer. The hole blocking layer or electron transport layer is as described above and will not be reiterated here. The forming process is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, the process is preferably a vacuum vapor deposition process. The vacuum degree for the vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. The evaporation rate of organic material in the vacuum vapor deposition is preferably <NUM> to <NUM>/s.

Then, a buffer layer is preferably formed on the hole blocking layer or electron transport layer. The buffer layer is as described above and will not be reiterated here. The forming process is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, the process is preferably a vacuum vapor deposition process. The vacuum degree for the vacuum vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. The evaporation rate is preferably <NUM> to <NUM>/s.

Finally, a cathode layer is formed on the buffer layer, thereby obtaining a blue organic electroluminescent device. The cathode layer is as described above, and will not be reiterated here. The forming process is not specifically limited, as long as it is a well-known process for those skilled in the art. In the present invention, the process is preferably a vacuum vapor deposition process. The vacuum degree for the vacuum vapor deposition is preferably <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa.

The blue organic electroluminescent device provided in the present invention has a simple structure, which is favorable for simplifying the preparation process of the device. Meanwhile, according to claim <NUM> generally have relatively low prices, which is favorable for lowering the manufacture cost of the device. In addition, all the materials used have good thermostability, which is favorable for improving the device lifetime.

By optimizing the device structure design and simplifying the device structure and the preparation process, the present invention improves the efficiency, luminance and operation stability of the device and reduces the manufacture cost of the device, on the premise that it is ensured that the color purity of the device is not reduced.

In order to further illustrate the present invention, the blue organic electroluminescent device and the preparation method thereof provided in the present invention will be described in detail below with reference to examples.

All reagents used in the following examples are commercially available.

An ITO anode layer on an ITO glass was laser-etched into a patterned electrode, then ultrasonically washed with a cleaning liquid and deionized water sequentially for <NUM>, and placed in an oven for drying. The dried substrate was then placed in a pretreating vacuum chamber. The ITO anode was subjected to a low-pressure oxygen plasma treatment for <NUM> under an atmosphere having a vacuum degree of <NUM> Pa with a voltage of <NUM> V, and then transferred to a metal vapor deposition chamber to vapor deposit <NUM> MoO<NUM> anode interface layer <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Then, the uncompleted device was transferred to an organic vapor deposition chamber to sequentially vapor deposit a TAPC hole transport layer/electron blocking layer <NUM> with a thickness of <NUM>, a DBzA doped TcTa light emitting layer <NUM> with a thickness of <NUM>, and a TmPyPB hole blocking layer/electron transport layer <NUM> with a thickness of <NUM> on the anode interface layer <NUM> under a vacuum atmosphere having a vacuum degree of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Next, the uncompleted device was transferred to a metal vapor deposition chamber to vapor deposit a LiF buffer layer with a thickness of <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Finally, a metal Al electrode with a thickness of <NUM> was vapor deposited on the LiF layer through a specially-made mask plate to prepare a blue organic electroluminescent device having a structure of ITO/MoO<NUM>/TAPC/DBzA (<NUM> wt%):TcTa/TmPyPB/LiF/Al. The evaporation rates for DBzA and TcTa in the light emitting layer <NUM> were controlled at <NUM>/s and <NUM>/s, respectively. The evaporation rates for TAPC and TmPyPB were controlled at <NUM>/s. The evaporation rate for MoO<NUM> was controlled at <NUM>/s. The evaporation rate for LiF was controlled at <NUM>/s. The evaporation rate for Al was controlled at <NUM>/s.

The blue organic electroluminescent device obtained in Example <NUM> exhibited a pure blue light emission with a main peak at <NUM> under a direct voltage driving. As the operation voltage varied, the color coordinate of the device was stabilized in a range of from (<NUM>, <NUM>) to (<NUM>, <NUM>). When the luminance was <NUM> cd/m<NUM>, the color coordinate of the device was (<NUM>, <NUM>).

<FIG> shows the curves of voltage-current density-luminance of the blue organic electroluminescent device obtained in Example <NUM>. As seen from <FIG>, the lighting-up voltage of the device was <NUM> V, and the maximal luminance of the device was <NUM> cd/m<NUM>.

<FIG> shows the characteristic curves of current density-power efficiency-current efficiency of the blue organic electroluminescent device obtained in Example <NUM>. As seen from <FIG>, the maximal current efficiency of the device is <NUM> cd/A, and the maximal power efficiency is <NUM> lm/W.

<FIG> shows a spectrum of the blue organic electroluminescent device obtained in Example <NUM> when the luminance is <NUM> cd/m<NUM>. The color coordinate of the device was (<NUM>, <NUM>).

An ITO anode layer on an ITO glass was laser-etched into a patterned electrode, then ultrasonically washed with a cleaning liquid and deionized water sequentially for <NUM>, and placed in an oven for drying. The dried substrate was then placed in a pretreating vacuum chamber. The ITO anode was subjected to a low-pressure oxygen plasma treatment for <NUM> under an atmosphere having a vacuum degree of <NUM> Pa with a voltage of <NUM> V, and then transferred to a metal vapor deposition chamber to vapor deposit <NUM> MoO<NUM> anode interface layer <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Then, the uncompleted device was transferred to an organic vapor deposition chamber to sequentially vapor deposit a TAPC hole transport layer/electron blocking layer <NUM> with a thickness of <NUM>, a DBzA doped TcTa light emitting layer <NUM> with a thickness of <NUM>, and a Tm3PyP26PyB hole blocking layer/electron transport layer <NUM> with a thickness of <NUM> on the anode interface layer <NUM> under a vacuum atmosphere having a vacuum degree of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Next, the uncompleted device was transferred to a metal vapor deposition chamber to vapor deposit a LiF buffer layer with a thickness of <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Finally, a metal Al electrode with a thickness of <NUM> was vapor deposited on the LiF layer through a specially-made mask plate to prepare a blue organic electroluminescent device having a structure of ITO/MoO<NUM>/TAPC/DBzA (<NUM> wt%):TcTa/Tm3PyP26PyB/LiF/Al. The evaporation rates for DBzA and TcTa in the light emitting layer <NUM> were controlled at <NUM>/s and <NUM>/s, respectively. The evaporation rates for TAPC and TmPyPB were controlled at <NUM>/s. The evaporation rate for MoO<NUM> was controlled at <NUM>/s. The evaporation rate for LiF was controlled at <NUM>/s. The evaporation rate for Al was controlled at <NUM>/s.

<FIG> shows the curves of voltage-current density-luminance of the blue organic electroluminescent device obtained in Example <NUM>. As seen from <FIG>, the luminance of the device increased as the current density and the driving voltage increased, the lighting-up voltage of the device was <NUM> V, and the maximal luminance of the device was <NUM> cd/m<NUM>.

<FIG> shows the characteristic curves of current density-power efficiency-current efficiency of the blue organic electroluminescent device obtained in Example <NUM>. As seen from <FIG>, the maximal current efficiency of the device is <NUM> cd/A, and the maximal power efficiency is <NUM> Im/W.

The blue organic electroluminescent device obtained in Example <NUM> exhibited a pure blue light emission with a main peak at <NUM> under a direct voltage driving. As the operation voltage varied, the color coordinate of the device was stabilized in a range of from (<NUM>, <NUM>) to (<NUM>, <NUM>). When the luminance was <NUM> cd/m<NUM>, the color coordinate of the device was (<NUM>, <NUM>). The lighting-up voltage of the device was <NUM> V, and the maximal luminance of the device was <NUM> cd/m<NUM>. The maximal current efficiency of the device is <NUM> cd/A, and the maximal power efficiency is <NUM> lm/W.

An ITO anode layer on an ITO glass was laser-etched into a patterned electrode, then ultrasonically washed with a cleaning liquid and deionized water sequentially for <NUM>, and placed in an oven for drying. The dried substrate was then placed in a pretreating vacuum chamber. The ITO anode was subjected to a low-pressure oxygen plasma treatment for <NUM> under an atmosphere having a vacuum degree of <NUM> Pa with a voltage of <NUM> V, and then transferred to a metal vapor deposition chamber to vapor deposit <NUM> MoO<NUM> anode interface layer <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Then, the uncompleted device was transferred to an organic vapor deposition chamber to sequentially vapor deposit a TAPC hole transport layer/electron blocking layer <NUM> with a thickness of <NUM>, a DBzA doped TcTa light emitting layer <NUM> with a thickness of <NUM>, and a TmPyPB hole blocking layer/electron transport layer <NUM> with a thickness of <NUM> on the anode interface layer <NUM> under a vacuum atmosphere having a vacuum degree of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Next, the uncompleted device was transferred to a metal vapor deposition chamber to vapor deposit a LiF buffer layer with a thickness of <NUM> under a vacuum atmosphere of <NUM> × <NUM>-<NUM> to <NUM> × <NUM>-<NUM> Pa. Finally, a metal Al electrode with a thickness of <NUM> was vapor deposited on the LiF layer through a specially-made mask plate to prepare an organic electroluminescent device having a structure of ITO/MoO<NUM>/TAPC/DBzA (<NUM> wt%):TcTa/TmPyPB/LiF/Al. The evaporation rates for DBzA and TcTa in the light emitting layer <NUM> were controlled at <NUM>/s and <NUM>/s, respectively. The evaporation rates for TAPC and TmPyPB were controlled at <NUM>/s. The evaporation rate for MoO<NUM> was controlled at <NUM>/s. The evaporation rate for LiF was controlled at <NUM>/s. The evaporation rate for Al was controlled at <NUM>/s.

The blue organic electroluminescent device obtained in Example <NUM> exhibited a pure blue light emission with a main peak at <NUM> under a direct voltage driving. As the operation voltage varied, the color coordinate of the device was stabilized in a range of from (<NUM>, <NUM>) to (<NUM>, <NUM>). When the luminance was <NUM> cd/m<NUM>, the color coordinate of the device was (<NUM>, <NUM>). The lighting-up voltage of the device was <NUM> V, and the maximal luminance of the device was <NUM> cd/m<NUM>. The maximal current efficiency of the device is <NUM> cd/A, and the maximal power efficiency is <NUM> Im/W.

Claim 1:
A blue organic electroluminescent device, comprising:
a substrate (<NUM>);
an anode layer (<NUM>) disposed on the substrate;
a light emitting layer (<NUM>) disposed on the anode layer, the light emitting layer being formed from a blue organic fluorescent material and a hole-type organic host material, wherein an excited state energy of the blue organic fluorescent material is lower than an excited state energy of the hole-type organic host material; and
a cathode layer (<NUM>) disposed on the light emitting layer,
wherein the blue organic fluorescent material is <NUM>,<NUM>'-(<NUM>,<NUM>-anthracenediyl-di-<NUM>,<NUM>-phenylene)bis[<NUM>-methyl-benzothiazole], and characterized in that
the blue organic fluorescent material is <NUM>% to <NUM>% by mass of the hole-type organic host material, and
the hole-type organic host material is one or more selected from the group consisting of <NUM>,<NUM>'-di(<NUM>-carbazolyl)biphenyl, <NUM>,<NUM>-di(carbazol-<NUM>-yl)benzene, <NUM>,<NUM>'-(<NUM>-(triphenylsilyl)-<NUM>,<NUM>-phenylene)bis-<NUM>-carbazole, <NUM>,<NUM>,<NUM>-tri(<NUM>-carbazolyl)benzene, <NUM>,<NUM>',<NUM>"-tri(carbazol-<NUM>-yl)triphenylamine and <NUM>,<NUM>'-bis(triphenylsilyl)biphenyl.