DE10210043A1 - Plasma screen with Pr (III) activated phosphor - Google Patents

Abstract

The invention relates to a plasma screen with a red-emitting, Pr · 3 + · - activated phosphor. The phosphor comprises a host lattice and Pr · 3 + · as an activator, the host lattice of the phosphor being selected from the group of the oxides, the silicates, the niobates, the tantalates and the niobate-tantalate mixed crystals.

Description

The invention relates to a plasma screen equipped with a phosphor layer, which contains a red-emitting phosphor.

Plasma screens allow high resolution, large color images Screen size and are of compact design. A plasma screen shows one hermetically enclosed space, which is filled with a gas, arranged with a grid Electrodes. Individually controllable plasma cells are generated by separating ribs, in a gas discharge is caused by the application of an electrical voltage, that produces light in the ultraviolet range. This light can be absorbed by phosphors visible light converted and emitted through the front panel of the cell to the viewer become.

BO ₃ : Eu is used as the red phosphor in many plasma screens (Y, Gd) because this phosphor shows a higher luminous efficacy when excited by VUV light than other red-emitting phosphors. Considerable disadvantages of this phosphor are on the one hand the color point, which is too orange for video applications with x = 0.643 and y = 0.357, and on the other hand the relatively long decay time of τ _1/10 = 9 ms. For example, US Pat. No. 5,136,207 describes a plasma screen with (Y, Gd) BO ₃ : Eu as the red-emitting phosphor.

The orange color point of (Y, Gd) BO ₃ : Eu results in a reduced color space in plasma screens compared to cathode ray tubes in which Y ₂ O ₂ S: Eu is used as a red phosphor. The latter has a color point of x = 0.659 and y = 0.332.

It is therefore an object of the invention to provide an improved plasma display put.

This object is achieved by a plasma screen equipped with a phosphor layer which contains a phosphor which comprises a host lattice and Pr ³⁺ as an activator, the host lattice of the phosphor being selected from the group of the oxides, the silicates, the niobates, the tantalates and the niobate-tantalate mixed crystals.

According to quantum theoretical model assumptions the lowest 5d energy level of the energy levels ₀ Pr is in these host lattices of the Pr ³⁺ -Karions well below the ¹ S ³⁺ cation.

In Pr ³⁺ -activated phosphors, in which the lowest 5d energy level of the Pr ³⁺ cation is below the ¹ S ₀ energy level of the Pr ³⁺ cation according to qualitative quantum theoretical models, there are no transitions from the ^1st after excitation of the electrons S ₀ energy level takes place in the basic state, in which light is emitted in the UV-C range or blue spectral range. Rather, radiationless relaxation takes place above 5d energy levels lower than the ¹ S ₀ energy level and to lower energy levels. The latter are, for example, the ³ P _J energy level or the ¹ D ₂ energy level. From the ³ P _J energy level or the ¹ D ₂ energy level, the electrons return to the ground state with the emission of red light.

The host lattice is responsible for the size of the splitting of the 5d states of the Pr ³⁺ cation. The advantageously selected host lattices have coordinating anions with a high charge density and thus bring about a large splitting of the 5d states of the Pr ³⁺ cation. In Pr ³⁺ -activated phosphors with these host lattices, the lowest 5d energy level is below the ¹ S ₀ energy level of the Pr ³⁺ cation and a red emission is obtained after excitation with (V) UV radiation.

The advantageously selected Pr ³⁺ -activated phosphors according to claim 2 have a lower y value of the color point than (Y, Gd) BO ₃ : Eu.

Due to the advantageous embodiment according to claim 3, the color point of a red emitting phosphor layer can be varied.

The invention will be explained in more detail below with the aid of four figures. there shows

Fig. 1 shows the structure and operating principle of a single plasma cell in an AC plasma screen,

Fig. 2 shows the energy level diagram of Pr ^3+,

Fig. 3 shows the excitation and emission spectrum of Ca ₂ SiO ₄ : 1% Pr and

Fig. 4 shows the excitation and emission spectrum of Y ₂ O _3: 0.5% Pr.

Referring to FIG. 1, a plasma cell of an AC plasma screen with a coplanar arrangement of electrodes on a front plate 1 and a carrier plate 2. The front plate 1 has a transparent plate 3 , for example made of glass, on which there is a dielectric layer 4 , which preferably contains low-melting glass, and thereon a protective layer 5 , which preferably contains MgO. Parallel, strip-shaped discharge electrodes 6 , 7 are applied to the transparent plate 3 and are covered by the dielectric layer 4 . The discharge electrodes 6 , 7 are, for example, made of metal, ITO or a combination of a metal and ITO. The discharge electrodes 6 , 7 preferably each have a strip of ITO, to each of which a narrower layer of Al or Ag is applied as a bus electrode. The carrier plate 2 is preferably made of glass, and parallel, strip-shaped address electrodes 10 made of, for example, Ag are applied to the carrier plate 2 and run perpendicular to the discharge electrodes 6 , 7 . These are covered by a phosphor layer 9 , which emits light 13 in one of the three primary colors red, green or blue. For this purpose, the phosphor layer 9 is divided into several color segments. Individually controllable plasma cells, in which silent electrical discharges take place, are formed by a rib structure 12 with separating ribs made of preferably dielectric material.

There is a gas in the plasma cell and between the discharge electrodes 6 , 7 , each of which alternately acts as a cathode or anode. The gas can contain, for example, a noble gas, a mixture of noble gases with Xe as the UV light-emitting component, nitrogen or a mixture of nitrogen and at least one noble gas, such as He, Ne, Kr or Xe. After the surface discharge has ignited, as a result of which charges can flow on a discharge path located between the discharge electrodes 6 , 7 in the plasma region 8 , a plasma is formed in the plasma region 8 , by means of which radiation 11 is generated in the UV region, depending on the composition of the gas. The radiation 11 excites the phosphor layer 9 to emit light, which emits visible light 13 , which passes through the front panel 1 and thus represents a luminous point on the screen. The phosphor layer 9 is divided into several color segments. The red, green or blue emitting color segments of the phosphor layer 9 are usually applied in the form of vertical strips of strips. A plasma cell with a color segment forms a so-called sub-pixel. Three adjacent plasma cells, each with a red, green or blue-emitting color segment, together form a pixel, or also called a pixel.

A green-emitting color segment can contain, for example, Zn ₂ SiO ₄ : Mn as a phosphor and a blue-emitting color segment can contain, for example, BaMgAl ₁₀ O ₁₇ : Eu as a phosphor.

A red-emitting color segment contains a red-emitting, Pr ³⁺ -activated phosphor. The host lattice of the Pr ³⁺ activated phosphor is preferably an oxide, a silicate, a niobate, a tantalate or a niobate-tantalate mixed crystal. As Pr ³⁺ -activated phosphor, for example (Y _1-x Gd _x ) ₂ O ₃ : Pr with 0 ≤ x ≤ 1, (Ca _1-x Sr _x ) ₂ SiO ₄ : Pr with 0 ≤ x ≤ 1 or Y (Nb _1-x Ta _x ) O ₄ : Pr with 0 ≤ x ≤ 1 is used in a red-emitting color segment of the phosphor layer 9 .

In FIG. 2, the term scheme of Pr ^3+, and the position of the 5d-states in the novel phosphors is shown. After excitation of an electron into a 5d state of the Pr ³⁺ cation, radiationless relaxation takes place to the ¹ S ₀ energy level. From there, further radiationless relaxation first takes place in a further, lower lying 5d state of the Pr ³⁺ cation and from there into further energy levels, for example ³ P _J , ¹ I ₆ or ¹ D ₂ . From these levels, the electrons return radially to the basic states. The transitions ³ P _J → ³ H ₆ and ¹ D ₂ → ³ H ₄ are responsible for the red emission of these phosphors. Since the lowest 5d state of the Pr ³⁺ cation lies below the ¹ S ₀ energy level of the Pr ³⁺ cation, no radiant transitions from this ¹ S ₀ energy level to the ground state occur with the emission of short-wave, ie, for example in the UV C or in the blue spectral range, instead of light as they are known from other Pr ³⁺ -activated phosphors, such as YPO ₄ : Pr or YBO ₃ : Pr.

It may be advantageous for the red-emitting color segments of the phosphor layer 9 to have a further red-emitting phosphor, in addition to the Pr ³⁺ -activated phosphor, such as (Y _1-x Gd _x ) BO ₃ : Eu with 0 ≤ x ≤ 1, Y (V _1-x P _x ) O ₄ : Eu with 0 ≤ x ≤ 1 or (Y _1-x Gd _x ) ₂ O ₃ : Eu with 0 ≤ x ≤ 1 included.

Embodiment 1

To prepare Ca ₂ SiO ₄ : 1% Pr, 20.00 g CaCO ₃ (199.8 mmol Ca), 6.215 g SiO ₂ (103.4 mmol 51) and 437.0 mg Pr (NO ₃ ) ₃ (H ₂ O) ₆ (1.005 mmol Pr ) dispersed or dissolved in 200 ml of water and then placed in an ultrasonic bath for 10 minutes. The water was removed by distillation and the residue was dried at 100 ° C. Then 1.6 g of NH ₄ Cl were added and the mixture obtained was ground in a mortar. Finally, the mixture was calcined at 850 ° C. in a CO-containing atmosphere (heating rate: 200 ° C./h). After cooling, the powder was ground and sieved through a 36 µm sieve.

Fig. 3 shows the excitation and emission spectrum of Ca ₂ SiO ₄ shows: 1% Pr. The color point (x, y) of the phosphor obtained is x = 0.605, y = 0.350.

Ca ₂ SiO ₄ : 1% Pr was used as a red-emitting phosphor in a plasma display screen, which had an improved color point and short decay times after stimulation for the red-emitting subpixels or color segments.

Embodiment 2

Ca ₂ SiO ₄ : 1% Pr was produced analogously to embodiment 1 and used together with YPO ₄ : Eu in a plasma screen, which had an improved color point and short decay times after stimulation for the red-emitting subpixels or color segments.

Embodiment 3

To prepare Y ₂ O ₃ : 0.5% Pr, 30.00 g of Y (NO ₃ ) ₃ (H ₂ O) ₆ (78.36 mmol Pr) and 167.0 mg g Pr (NO ₃ ) ₃ (H ₂ O) ₆ (396.0 µmol Pr) dissolved in 200 ml of water. The pH was adjusted to 5.0 using 1 M NH ₃ . The solution obtained was heated to 60 ° C. 74.43 g of oxalic acid dihydrate (590.4 mmol of oxalic acid) were dissolved in 500 ml of water and added dropwise to the nitrate-containing solution within 45 minutes. The mixture was then stirred at 60 ° C. for a further 15 minutes. The resulting precipitate was filtered off, washed twice with water and then dried at 120 ° C. The solid was then exposed to air for 1 h at 900 ° C (heating rate: 250 ° C / h), 4 h at 1400 ° C in an atmosphere containing CO (heating rate: 200 ° C / h) and 2 h at 1100 ° C Calcined atmosphere containing CO (heating rate: 300 ° C / h).

Fig. 4 shows the excitation and emission spectrum of Y ₂ O _3: 0.5% Pr. The color point (x, y) of the phosphor obtained is x = 0.671, y = 0.304.

Y ₂ O ₃ : 0.5% Pr was used as a red-emitting phosphor in a plasma display screen, which had an improved color point and short decay times after stimulation for the red-emitting subpixels or color segments.

Claims (3)

1. Plasma screen equipped with a phosphor layer which contains a phosphor which comprises a host lattice and Pr ³⁺ as an activator, characterized in that the host lattice of the phosphor is selected from the group of oxides, silicates, niobates, tantalates and niobate tantalate solid solution. 2. Plasma display according to claim 1, characterized in that the phosphor is selected from the group (Y _1-x Gd _x ) ₂ O ₃ : Pr with 0 ≤ x ≤ 1, (Ca _1-x Sr _x ) ₂ SiO ₄ : Pr with 0 ≤ x ≤ 1 and Y (Nb _1-x Ta _x ) O ₄ : Pr with 0 ≤ x ≤ 1. 3. Plasma display according to claim 1, characterized in that the phosphor layer additionally a further red-emitting phosphor selected from the group (Y _1-x Gd _x ) BO ₃ : Eu with 0 ≤ x ≤ 1, Y (V _1-x P _x ) O ₄ : Eu with 0 ≤ x ≤ 1 and (Y _1-x Gd _x ) ₂ O ₃ : Eu with 0 ≤ x ≤ 1 contains.