Dielectric composition for high frequency resonators

FIELD OF THE INVENTION

[0001] This invention relates to a dielectric material suitable for use as a dielectric resonator. More particularly, the invention relates to a low loss dielectric material suitable for use as a high frequency dielectric resonator.

BACKGROUND OF THE INVENTION

[0002] Materials of the BaO—MgO—Nb2O5 system (referred to herein as the BMN system) are known as high frequency dielectric materials. Laid-Open Japanese Patent Application No. 60-124305 and Japanese Patent Publication No. 2-60628 describe materials of the BMN system suitable for high frequency use.

[0003] However, the BMN system materials exemplified in the above Japanese patent documents include Ta which is expensive. In order to reduce manufacturing costs, it would be desirable to provide a BMN system material containing no Ta but still having desirable high frequency characteristics.

SUMMARY OF THE INVENTION

[0004] The present invention has as an object thereof to provide a dielectric composition which is based on a BMN system material but which includes no Ta, and in which: (1) the dielectric constant ε is about 30, (2) the Q-value, i.e., the no-load quality coefficient, is large, and (3) the absolute value of τf, the temperature coefficient of the resonant frequency, is comparatively small. As will be understood by those skilled in the art, the parameters Q (sometimes given as Q0) and τf are important quantities in analyzing the characteristics of a dielectric material, with the latter being determined by measuring the change in resonant frequency with temperature.

[0005] In accordance a first aspect of the present invention, there is provided a dielectric material having a composite perovskite crystal structure including K, Ba, Mg and Nb as metallic elements in a main crystal phase, and having a compositional formula represented by:

(1−x)Baα(MgβNb1−β)O3−xKpNbO3,

[0006] wherein x, α, β and p have values satisfying the conditions

0<x≦0.1, 0.9≦α≦1.3, 0.3≦β≦0.35 and 1≦p≦2.

[0007] In accordance with a second aspect of the present invention, there is provided a dielectric material having a composite perovskite crystal structure including K, Mg, Sb, Ba and Nb as metallic elements in the main crystal phase, and having a compositional formula represented by:

(1−x)Baα(MgβNbγSbδ)O3−xKpNbO3,

[0008] wherein x, α, β, γ, δ and p have values satisfying the conditions

0<x≦0.1, 0.9≦α≦1.3, 0.3≦β≦0.35, 0<δ≦0.125, β+γ+δ=1 and 1≦p≦2.

[0009] In accordance with a third aspect of the present invention, there is provided a dielectric material having of a composite perovskite crystal structure including Sn, K, Mg, Sb, Ba and Nb as metallic elements in a main crystal phase, and having a compositional formula represented by:

(1−x){(1−y)Baα(MgβNbγSbδ)O3−yBaSnO3}−xKpNbO3,

[0010] wherein x, y, α, β, γ, δ and p have values satisfying the conditions

0<x≦0.1, 0<y≦0.5, 0.9≦α≦1.3, 0.3≦β≦0.35, 0<δ≦0.125, δ+γ+δ=1 and 1≦p≦2.

[0011] Further features and advantages of the present invention will be set forth in, or apparent from, the detailed description of preferred embodiments thereof which follows.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0012] In the compositional formulas set forth above, the oxygen ratios will naturally depend upon the variables α, β, γ, δ, and p. Accordingly, none of the dielectric compositions of the present invention should be considered as being limited only to an oxygen mole ratio of 3. This is because the most important aspect of the dielectric compositions of the present invention is not whether the mole ratio of oxygen is 3, but, instead, whether the mole ratio of each different metal is prescribed within a certain range. Accordingly, in the dielectric compositions of the present invention, it should be noted that the mole ratio of oxygen is given as 3 for the convenience of avoiding unnecessary complexity in the compositional formulas.

[0013] The dielectric compositions of the present invention are characterized in that sintering can be improved without any deterioration of the high frequency characteristics, by adding KpNbO3 to a specific BMN system material and optionally incorporating a predetermined amount of another specified metal in a specific ratio.

[0014] When no KpNbO3 is added, the specific BMN (BaO—MgO—Nb2O5) system material cannot be sintered. Further, when the amount, x, of KpNbO3 is greater than 0.1, the Q-value (the no-load quality coefficient) is reduced. Thus, the sintering and dielectric characteristics can be reconciled by prescribing the ratio of KpNbO3 to BMN (BaO—MgO—Nb2O5) material as x.

[0015] When the coefficient p of KpNbO3 is smaller than 1, it is difficult to sinter the specific BMN system material. When the coefficient p of KpNbO3 is greater than 2, the Q-value is reduced.

[0016] A higher Q-value can be obtained by prescribing the quantity of Ba occupying Ba sites within the composite perovskite compound, to a predetermined range. Specifically, the coefficient α of Ba is preferably set to be within the range from 0.9 to 1.3. When α is greater than 1.3, it is difficult to sinter the BMN system material. When α is smaller than 0.9, the Q-value is reduced. The coefficient α preferably ranges from 1.0 to 1.2, and, more preferably, ranges from 1.0 to 1.05. The temperature coefficient (τf) of the resonance frequency can preferably also be set as well as the Q-value.

[0017] The coefficient β of Mg preferably ranges from 0.3 to 0.35. When β is greater than 0.35, it is difficult to sinter the BMN system material. When β is smaller than 0.3, the Q-value is reduced. The coefficient β more preferably ranges from 0.31 to 0.33. The temperature coefficient (τf) of the resonant frequency can preferably also be set as well as the Q-value.

[0018] A higher Q-value can be obtained by using a material (referred to herein as a BMNSb material) in which an Nb site in the dielectric composition of the present invention is partially replaced with Sb. The coefficient δ of Sb is preferably set to be equal to or smaller than 0.125. When δ is greater than 0.125, sintering is more difficult and the reproducibility of the desirable characteristics is also reduced. The coefficient δ more preferably ranges from 0.05 to 0.075 since a high Q-value can then be obtained.

[0019] The temperature coefficient (τf) of the resonance frequency (which can approach zero) can be further improved by partially replacing the B-site of the perovskite crystal structure with Sn in the BMNSb system material. The quantity y of Sn preferably ranges from 0.15 to 0.3 since the temperature coefficient τf can be adjusted to within ±10. An excellent value almost near 0 ppm/K in the temperature coefficient τf is obtained by setting the quantity y of Sn to be within the range of 0.22 to 0.23 (and, more preferably, at 0.225).

[0020] The following Examples illustrate the invention but should not be considered as limiting the scope thereof.

EXAMPLES

Manufacture of Dielectric Composition

[0021] The quantities of commercially available BaCO3, MgO, Nb2O5, Sb2O3 and K2CO3 represented by the corresponding coefficients of x, y, α, β, γ, δ and p, as shown in the following Table 1, and ethanol as a solvent, are wet-blended. The blended powder, which is obtained by drying and removing the solvent, is then calcined for two hours at 1100° C. in air. Next, a wax system binder, a dispersion agent and ethanol are added to the calcined material, and are crushed and mixed by a ball mill so that a slurry is obtained. This slurry is dried and granulated, and the granulated powder is molded in a column 19 mm in diameter and 12 mm in thickness at a pressure of 10 to 20 MPa. This molded body is then processed by a CIP (cold hydrostatic press) at a pressure of 150 MPa. Finally, this CIP-processed molded body is heated for four hours at 1550 to 1650° C. in air to form a calcined body.

Evaluation of Dielectric Characteristics

[0022] The calcined body obtained as described above is formed into a column (14 mm in diameter and 7 mm in height) and surface finished with a surface grinder. The dielectric constant ε, the quantity Qf, which is the product of the Q-value and the resonance frequency f, and the temperature coefficient τf of the resonance frequency (wherein the measurement frequency is 4 to 6 GHz, and the temperature range is 25 to 80° C.) are measured using the known parallel conductor plate type dielectric resonator method. The results are set out in Table 2.

1TABLE 1CompositionSample No.xyαβγδP10.1000.0001.0000.3200.6300.0501.00020.1000.0001.0000.3200.6300.0501.25030.0750.0001.0000.3200.6300.0501.25040.0250.0001.0000.3000.6500.0501.25050.0500.0001.0000.3340.5890.0771.00060.0500.0001.0000.3340.5890.0771.00070.0250.0001.0000.3500.6000.0501.25080.0250.0001.0000.3080.6420.0501.25090.0250.0001.0000.3200.5790.1011.250100.0250.0001.0000.3200.6300.0502.000110.0250.0001.0000.3500.6000.0501.250120.0250.0001.0000.3490.6220.0001.250130.0250.0001.0000.3090.6160.0751.250140.0250.0001.0000.3200.6700.0101.250150.0250.0001.0000.3490.5920.0591.250160.0500.0001.0000.3200.6300.0501.250170.0250.0001.3000.3200.6300.0501.250180.0250.0001.0000.3200.5550.1251.250190.0250.0001.0000.3260.6230.0501.250200.0100.0001.0000.3200.6300.0501.250210.0250.0001.0000.3450.5790.0751.250220.0250.0001.0000.3200.6300.0501.000230.0250.0001.0000.3400.6100.0501.250240.0250.0001.2000.3200.6300.0501.250250.0250.0001.0000.3170.6580.0251.250260.0250.0001.0000.3380.5950.0671.250270.0250.0001.0000.3420.5950.0641.250280.0250.0001.0000.3200.5800.1001.250290.0250.0001.0000.3340.6160.0501.250300.0250.0001.0000.3440.6320.0251.250310.0250.0001.0000.3200.6300.0501.250320.0250.0001.1000.3200.6300.0501.250330.0250.0001.0000.3200.6300.0501.500340.0250.0001.0000.3200.6500.0301.250350.0250.0001.0000.3170.6330.0501.250360.0250.0001.0000.3250.6000.0751.000370.0250.0001.0000.3330.5970.0701.250380.0250.0001.0000.3200.6050.0751.250390.0050.0001.0000.3170.6100.0731.250400.0050.0001.0000.3170.6100.0731.250410.0250.0001.0000.3230.6000.0771.250420.0250.0001.0000.3250.6000.0751.250430.0250.0001.0250.3170.6330.0501.250440.0250.1501.0250.3170.6330.0501.250450.0250.1901.0250.3170.6330.0501.250460.0250.2001.0250.3170.6330.0501.250470.0250.2251.0250.3170.6330.0501.250480.0250.2501.0250.3170.6330.0501.250490.0250.3001.0250.3170.6330.0501.250500.0250.4001.0250.3170.6330.0501.250510.0250.5001.0250.3170.6330.0501.250520.0000.0001.0000.3200.6300.0501.250530.1250.0001.0000.3200.6300.0501.250540.0250.0001.0000.3200.6300.0500.800550.1000.0001.0000.3200.6300.0500.800560.0250.0000.9500.3200.6300.0501.250570.0250.0001.4000.3200.6300.0501.250580.0250.0001.0000.2340.6660.1011.250590.0250.0001.0000.2500.6000.1501.250600.0250.0001.0000.2670.6330.0991.250610.0250.0001.0000.2830.6670.0501.250620.0250.0001.0000.2830.6420.0751.250630.0250.0001.0000.2840.6170.1501.250640.0250.0001.0000.2900.6600.0501.250650.0250.0001.0000.2990.6500.0501.250660.0250.0001.0000.2990.6000.1011.250670.0250.0001.0000.3200.6800.0001.250680.0250.0001.0000.3200.5300.1501.250690.0250.0001.0000.3320.6390.0001.250700.0250.0001.0000.3600.5900.0501.250710.0250.0001.0000.3740.6000.0251.250720.0250.0001.0000.3740.6000.0251.250730.0250.6001.0250.3170.6330.0501.250

[0023]

2

TABLE 2

Characteristics

Water

absorption

coefficient

Sample No.
[%]
Dielectric constant
Qf [GHz]
τf [ppm/K]

1
<0.1
26.4
10879
22

2
<0.1
27.0
10993
25

3
<0.1
27.9
11927
24

4
<0.1
31.7
12318
20

5
<0.1
28.0
12841
24

6
<0.1
28.6
13055
23

7
<0.1
26.9
13099
19

8
<0.1
32.1
14206
24

9
<0.1
28.5
14271
24

10
<0.1
31.5
15049
23

11
<0.1
27.1
15217
22

12
<0.1
27.3
15224
18

13
<0.1
30.7
15381
20

14
<0.1
30.7
15723
22

15
<0.1
28.2
16201
20

16
<0.1
28.3
16222
21

17
<0.1
30.8
16247
18

18
<0.1
28.7
17216
24

19
<0.1
30.3
17224
21

20
<0.1
29.1
17320
18

21
<0.1
27.9
18273
25

22
<0.1
30.2
18902
23

23
<0.1
28.0
18903
21

24
<0.1
30.5
18957
19

25
<0.1
32.8
19242
24

26
<0.1
28.3
19746
23

27
<0.1
27.8
19900
20

28
<0.1
29.3
20723
21

29
<0.1
29.2
21010
18

30
<0.1
28.1
21132
16

31
<0.1
31.3
21895
20

32
<0.1
31.0
22006
21

33
<0.1
30.9
22015
23

34
<0.1
30.2
22017
21

35
<0.1
31.5
22169
26

36
<0.1
26.7
22345
23

37
<0.1
28.8
23017
21

38
<0.1
29.8
23519
23

39
<0.1
28.7
24373
16

40
<0.1
28.6
24830
15

41
<0.1
28.5
24943
22

42
<0.1
27.0
26824
22

43
<0.1
29.6
27031
17

44
<0.1
27.4
24048
6

45
<0.1
27.2
24143
3

46
<0.1
27.0
23351
3

47
<0.1
26.7
21717
1

48
<0.1
26.9
16300
4

49
<0.1
25.7
15232
−3

50
<0.1
25.1
12403
−8

51
<0.1
24.4
10082
−12

52
>0.1
—
—
—

53
<0.1
26.0
5279
25

54
>0.1
—
—
—

55
>0.1
—
—
—

56
<0.1
Very small
Very small
—

resonance
resonance

57
>0.1
—
—
—

58
<0.1
Very small
Very small
—

resonance
resonance

59
<0.1
Very small
Very small
—

resonance
resonance

60
<0.1
Very small
Very small
—

resonance
resonance

61
<0.1
Very small
Very small
—

resonance
resonance

62
<0.1
Very small
Very small
—

resonance
resonance

63
<0.1
Very small
Very small
—

resonance
resonance

64
<0.1
Very small
Very small
—

resonance
resonance

65
<0.1
32.1
5972
23

66
<0.1
29.3
7021
26

67
<0.1
31.2
7895
23

68
<0.1
28.3
3689
25

69
<0.1
28.9
9722
25

70
>0.1
—
—
—

71
>0.1
—
—
—

72
>0.1
—
—
—

73
<0.1
23.9
6051
−20

[0024] It can be seen from the results set out in Table 2 that for the dielectric compositions of the present invention, the dielectric constant ε is about 30, the value of Qf is advantageously high and the temperature coefficient τf of the resonance frequency has a small value in the range of ±25 ppm/K. No data, except for the water absorption coefficient, are shown for samples numbers 52, 54, 55, 57 and 70 to 72; no data measurements were taken for these samples because of a sintering defect.

[0025] The dielectric materials of the present invention have a high Q-values and are able to be used for high frequency purposes but include no expensive Ta. Further, the materials have dielectric constants of about 30 and have reduced absolute values of the temperature coefficient τf of the resonance frequency. Moreover, dielectric materials having such excellent high frequency characteristics can be obtained without using special powder processes or sintering methods.

[0026] This application is based on Japanese Patent Application No. 2001-187008, filed Jun. 20, 2001, which is incorporated herein by reference in its entirety.

[0027] While the invention has been described in detail and with reference to the specific embodiments thereof, it will be apparent to one skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope thereof.

Dielectric composition for high frequency resonators

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Priority Claims (1)