KR100303848B1 - Red emitting phosphor - Google Patents

Abstract

A red light emitting phosphor used for a display element is disclosed. The red light-emitting phosphor for display elements may comprise a first phosphor material represented by the formula (Y, Gd) BO ₃ : Eu of 10 to 50 weight; And a second phosphor material represented by the chemical formula Y ₂ O ₃ : Eu of 50 to 90 weight. The red light-emitting phosphor has a short afterglow time, which is suitable for realizing a video.

Description

Red emitting phosphor

The present invention relates to a red light emitting phosphor used in a display device, and more particularly, to a red light emitting phosphor that can secure a short afterglow time suitable for realizing a moving image while maintaining an appropriate brightness required for the display device.

Yttrium-based phosphor material is used as a red light-emitting phosphor for image display of a conventional display device. Representative examples of such yttrium-based red light-emitting phosphors include phosphor materials represented by the formula (Y, Gd) BO ₃ : Eu and phosphor materials represented by the formula Y ₂ O ₃ : Eu. The yttrium-based red light-emitting phosphor was generally applied to a display device only in the form of a single component. In particular, a single-component phosphor material represented by the formula (Y, Gd) BO ₃ : Eu is mainly used in plasma display devices.

However, when a single component light emitting phosphor material is used for the display element, it is impossible to retain all the physical properties required for the display element.

The same applies to a single-component phosphor material represented by the general formula (Y, Gd) BO ₃ : Eu, which is generally used in display devices, which has superior advantages over other light emitting phosphor materials. The measured afterglow time is relatively long, and in particular, it does not meet the short afterglow time required for realizing a moving image.

Phosphor materials having a long afterglow time are inadequate in view of recent development trends of display devices, and are particularly unsuitable for display devices, particularly plasma display devices, since afterimages of images remain for a long time in order to realize moving images.

Since the afterglow time described above is relatively long in the case of manufacturing a display device using a phosphor material of a single component, the present invention is to improve the phosphor material unsuitable for realizing moving images. It is also an object of the present invention to provide a red light-emitting phosphor capable of remarkably shortening an afterglow time of a phosphor material to realize a moving image with high quality images.

The red light-emitting phosphor for achieving the above technical problem of the present invention, the first phosphor material represented by the formula (Y, Gd) BO ₃ : Eu of 10 to 50 weight; And a second phosphor material represented by the formula Y ₂ O ₃ : Eu of 50 to 90 weight.

The content of europium (Eu) of the second phosphor material is preferably 0.5 to 3.0 atoms (at) with respect to the second phosphor material.

The display element is not particularly limited as long as it employs a phosphor, but is particularly preferable in the case of a plasma display element or a cathode ray tube.

Although the red light-emitting phosphor has a relatively good luminance characteristic, it is intended to shorten the afterglow time by mixing a predetermined amount of the second phosphor material with the first phosphor material having a long afterglow time. In addition, it is possible to improve the color coordinate characteristics by appropriately adjusting the content of europium of the second phosphor material.

Improvement of the physical properties of such a red light-emitting phosphor is specifically made by the following principle. That is, the first phosphor material has a relatively long afterglow time because of its spin-forbidden properties. Therefore, afterglow time can be shortened by mixing the second phosphor material to alleviate the spin-forbidden property of the first phosphor material. On the other hand, when only the first phosphor material is used as a red light-emitting phosphor, europium +3 ions contained as components are located at the symmetry center of the crystal, and thus the afterglow time is long. In order to reduce the afterglow time, the second phosphor material, which is spin-aloud, is mixed and the content of europium included as a component thereof is adjusted to shorten the afterglow time and improve the color coordinate characteristics.

The red luminescent phosphor actually used is a composition including other components in addition to the first phosphor material and the second phosphor material, and is manufactured in paste form. It is common to proceed the stirring process for a sufficient time to maintain a uniform composition and a viscosity suitable for application immediately before applying the red light-emitting phosphor paste prepared in this way. The most common method of applying a paste-shaped red light-emitting phosphor to a display element is a screen printing method. After applying the red light-emitting phosphor to the display element, it is determined whether or not it is suitable for the display element by measuring the relative luminance, afterglow time, color coordinate value and the like. As described above, the red light-emitting phosphor according to the present invention is particularly suitable for moving picture realization of a plasma display device.

Hereinafter, the present invention will be described in more detail with reference to Examples according to the present invention and comparative examples for specifically describing the critical effects of the present invention.

Example 1

A red luminescent phosphor was prepared comprising a 90 weight first phosphor material represented by the formula (Y, Gd) BO ₃ : Eu and a 10 weight second phosphor material represented by the formula Y ₂ O ₃ : Eu. Meanwhile, the content of europium (Eu) of the second phosphor material is adjusted to be 2.0 atoms (at) with respect to the second phosphor material. That is, 36 g of the first phosphor material, 4 g of the second phosphor material, 6 g of ethyl cellulose and 0.6 g of terpinol are mixed in 53.4 g of BCA (buthyl carbitol acetate) as a solvent, followed by stirring for at least one day to prepare a red light-emitting phosphor of the mixture. It was. The red light-emitting phosphor thus prepared has a suitable viscosity in paste form and is suitable for application to a display element. Paste-shaped red light-emitting phosphor was applied to the plasma display panel by the screen printing method.

Thereafter, the luminance characteristics and the afterglow time of the red light-emitting phosphor material manufactured according to the above-described process and applied to the plasma display panel were measured, and the results are shown in Table 1 below. After exciting a sample using the afterglow facility which is a flash xenon lamp, the change of the afterglow time was measured with an oscilloscope. The luminance characteristic was excited by a deuterium lamp (147 nm), and then the light emission spectrum of the phosphor was measured with a spectrophotometer to calculate various luminance characteristics of the phosphor by calculating luminance and color coordinates.

Example 2

Except that the content of the first phosphor material of Example 1 is 80 weight (32g) and the content of the second phosphor material is 20 weight (8g), the specific details of the second embodiment is the above embodiment Same as 1 The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Example 3

Except that the content of the first phosphor material of Example 1 is 70 weight (28g), and the content of the second phosphor material is 30 weight (12g), the details of the third embodiment is the above embodiment Same as 1 The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Example 4

Except that the content of the first phosphor material of Example 1 is 60 weight (24g), and the content of the second phosphor material is 40 weight (16g), the details of the fourth embodiment is the above embodiment Same as 1 The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Example 5

Except that the content of the first phosphor material of Example 1 is 50 weight (20g) and the content of the second phosphor material is 50 weight (20g), the specific details of the fifth embodiment is the above embodiment Same as 1 The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Comparative Example 1

Except that the content of the first phosphor material of Example 1 is 100 weight (40g) and the content of the second phosphor material is 0 weight (0g), the specific content of Comparative Example 1 is the embodiment Same as 1 The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Comparative Example 2

Except that the content of the first phosphor material of Example 1 is 91 weight (36.4g), and the content of the second phosphor material is 9 weight (3.6g), the specific content of Comparative Example 2 is It is the same as that of Example 1. The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

Comparative Example 3

Except that the content of the first phosphor material of Example 1 is 49 weights (19.6g) and the content of the second phosphor material is 51 weights (20.4g), the specific content of Comparative Example 3 is It is the same as that of Example 1. The luminance characteristic and the afterglow time of the light-emitting phosphor thus prepared were measured and the results are shown in Table 1 below.

division Content of Second Phosphor Material (Weight) Relative luminance () Afterglow time (ms) Example 1 10 98 7.2 Example 2 20 97 6.5 Example 3 30 95 5.9 Example 4 40 94 5.2 Example 5 50 93 4.3 Comparative Example 1 0 100 8.0 Comparative Example 2 5 99 7.8 Comparative Example 3 55 80 4.2

In Table 1, as the content of the second phosphor material gradually increases in a certain range, it can be seen that the afterglow time of the phosphor material according to the embodiment gradually decreases. On the other hand, it can be seen from Table 1 that the relative luminance decreases with the reduction of afterglow time. By the way, while the maximum decrease in afterglow time is about 50, the decrease in relative luminance is insignificant (up to 5 or less), and this is not a problem since it is sufficiently acceptable in the display element. That is, the minimum relative luminance value applicable to the display element should have a value of at least 85, and the suitable afterglow time should be shorter than 7.2 ms to realize a moving image. From Table 1, it can be seen that the embodiments satisfy these two conditions simultaneously. On the other hand, Comparative Example 1 is a known light emitting phosphor material, the relative luminance is good, but the long afterglow time is not suitable for the implementation of the moving image, which is also described in Comparative Example 2. On the other hand, although Comparative Example 3 has the advantage that the afterglow time is the shortest, its relative luminance is about 85, which is not suitable for use in display elements.

On the other hand, when the europium (Eu) atomic concentration (at) content in the second phosphor material included in the red light-emitting phosphor prepared in the above embodiment is properly adjusted within a predetermined range of 0.5 to 3.0, maintaining the luminance characteristic and improving the afterglow characteristic In addition to the effect, it can be seen that the color coordinate characteristics are improved. In order to describe this in more detail, reference is made to examples according to the present invention and comparative examples for embodying the critical effects of the present invention.

Example 6

Compared to Example 4, all the specific details were the same except that the content of the second phosphor material was 40 weights and the content of europium in the second phosphor material was 0.5 atoms (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 3 below. Afterglow time and luminance characteristics were measured using the same method as in Example 1, and the color coordinates were obtained by the color coordinate calculation method after obtaining the emission spectrum.

Example 7

Compared to Example 4, all the specific embodiments were the same except that the second phosphor material content was 40 weights and the europium content in the second phosphor material was 1.0 atom (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 2 below.

Example 8

Compared to Example 4, all the specific details were the same except that the second phosphor material content was 40 weights and the europium content in the second phosphor material was 2.0 atoms (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 2 below.

Example 9

Compared to Example 4, all the specific embodiments were the same except that the second phosphor material content was 40 weights and the europium content in the second phosphor material was 3.0 atoms (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 2 below.

Comparative Example 4

Compared to Example 4, all the specific details were the same except for the case where the second phosphor material content was 40 weights and the europium content in the second phosphor material was 0.4 atoms (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 2 below.

Comparative Example 5

Compared to Example 4, all the specific embodiments were the same except that the second phosphor material content was 40 weights and the europium content in the second phosphor material was 3.1 atoms (at). In this case, the relative luminance, the x value of the color coordinates and the afterglow time of the red light-emitting phosphor in the form of the prepared composition were measured and shown in Table 2 below.

division Atomic concentration of europium (at) Relative luminance () Color coordinates Afterglow time (ms) Example 6 0.5 92 0.630 5.1 Example 7 1.0 93 0.635 5.2 Example 8 2.0 94 0.638 5.2 Example 9 3.0 95 0.640 5.4 Comparative Example 4 0.3 83 0.620 5.0 Comparative Example 5 3.5 84 0.655 6.0

The red light emitting phosphor used in the display element, in particular the plasma display element, is almost the same as the color coordinate x value of the red light emitting phosphor represented by the formula (Y, Gd) BO ₃ : Eu, which is used as a conventional single component, that is, x = 0.640 Its usefulness must have a value of ± 0.010. Therefore, from Table 2, it can be seen that the measurement data for the x-coordinate values of Comparative Examples 4 and 5 clearly shows the critical effect of the embodiment according to the present invention.

On the other hand, if the above-mentioned embodiments should not be used for the purpose of limiting the scope of the present invention, those skilled in the art can be variously modified based on the above-described embodiments.

The red light-emitting phosphor material according to the present invention described above does not significantly change the luminance characteristics of the red light-emitting phosphor represented by the formula (Y, Gd) BO ₃ : Eu, which is used in a display device, in particular, a plasma display panel. While minimizing, the afterglow time can be significantly shortened. In addition, color coordinate characteristics may be remarkably improved by controlling the content of europium in the second phosphor material. Accordingly, the red light-emitting phosphor for a display device according to the present invention can realize a better video by providing a phosphor material having improved sufficiently short afterglow time and color coordinate characteristics, which are the most important factors when implementing a video.

Claims (3)

In the red light-emitting phosphor for display elements, A first phosphor material represented by the formula (Y, Gd) BO ₃ : Eu of 10 to 50 weight; And A red light emitting phosphor comprising 50 to 90 weight of a second phosphor material represented by the formula Y ₂ O ₃ : Eu. The method of claim 1, The amount of europium (Eu) of the second phosphor material is 0.5 to 3.0 atoms (at) relative to the second phosphor material. The method according to claim 1 or 2, The display element is a red light emitting phosphor, characterized in that the plasma display element.