JPH03131545A - Resistor paste and ceramics substrate - Google Patents

Abstract

PURPOSE:To make resistor paste capable of baking in a nonoxidizing atmosphere such as nitrogen and to obtain stable resistant value and resistance coefficient of temperature by blending glass powder having a specific composition with electroconductive powder in a specific ratio to form an inorganic component of resistor paste. CONSTITUTION:Inorganic components of resistor paste substantially comprise 20-70wt.% glass powder and 30-80wt.% SnO2 and/or SnO2 powder doped with Sn. The glass powder substantially consists of 7-50wt.% SiO2, 0-20wt.% Al2O3, 10-60wt.% MgO+CaO+SrO, 0-40wt.% MgO, 0-40wt.% CaO, 0-60wt.% SrO, 0-10wt.% Li2O+Na2O+K2O+CS2O, 0-10wt.% PbO, 0-20wt.% ZnO, 0-10wt.% ZrO2+TiO2, 5-40wt.% B2O5, 0-60wt.% Ta2O5; 0-50wt.% Nb2O5 and 0.1-60wt.% Ta2O5+Nb2O5.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a resistor paste suitable for ceramic substrates and a ceramic substrate using the same.

[Prior Art] Conventionally, a resistor in a hybrid integrated circuit is made by forming a silver (Ag) or Ag-palladium (Pd) conductor on or inside a ceramic substrate, printing a resistor paste between them, and placing the conductor in an oxidizing atmosphere such as air. It was formed by firing at about 850 to 900°C.

The resistor paste used at that time was mainly Ru.
It consisted of O2 and glass.

However, recently, due to reliability issues such as migration,
Copper (Cu) conductors are increasingly being used to replace g or Ag--Pd conductors.

However, since the Cu conductor will be oxidized unless it is fired in a non-oxidizing atmosphere such as nitrogen, RII02, which is reduced in a non-oxidizing atmosphere and does not form a resistance, cannot be used.

Therefore, recently, L a B e powder and glass powder, 5n
02 doped products, glass powder, silicide and glass powder, etc. have been proposed.

However, the above combinations are limited by resistance value and temperature coefficient of resistance (TC).
There is a drawback that R) cannot yet be obtained in a sufficiently stable manner.

[Problems to be solved by the invention] The present invention can be fired in a non-oxidizing atmosphere such as nitrogen,
The object of the present invention is to provide a new resistor paste and ceramic substrate that are hitherto unknown and can stably obtain resistance values and temperature coefficients of resistance (TCP).

[Means for Solving the Problem] The present invention has been made to solve the above-mentioned problems, and the inorganic component is substantially 20% by weight of glass powder.
~70 and 5nu2 doped with SnO□ and/or sb
Powder 30-80, the glass powder is substantially 51027-50°A1□030-20, M
gO+CaO+SrO10-60. MgOO~40,
CaOO~40. SrOO~60. Li2O+
NazO+KzO+Cs, 00-10. PbOO~1
0. Zn00~20. Zr0z+Ti0z O~1
0. B2O35-40. Ta2es O~60°N
b2050-50. Ta205+NbzOs o,i
6o is provided.

The present invention will be explained in detail below.

The resistor paste of the present invention is suitable for use in single-layer or multi-layer ceramic substrates, and can be applied to ceramic substrates such as solidified alumina substrates after firing, or by printing or other methods on green sheets for ceramic substrates. After forming, it is fired in a non-oxidizing atmosphere such as a nitrogen atmosphere. Note that % means weight % unless otherwise specified.

The resistor paste of the present invention contains substantially no inorganic components. Glass powder 20-70% Conductive material powder 30-80% These are explained below in order.

The glass powder is preferably SiO□-B203 glass, which has sufficient fluidity at low temperatures (for example, 900'C or lower) and covers and sufficiently wets the conductive material powder during firing and sinters.

If the content of such glass powder is less than 20%, the conductive material powder cannot be sufficiently wetted, and the sintered layer will have many pores. If it exceeds 70%, the adhesion between the conductive material powders will decrease, and the resistance value will become too large, which is not suitable.

The glass powder according to the present invention preferably has a content of 25 to 65% of the above range.

On the other hand, the conductive material powder is SnO, which is usually commercially available.
□, Sb doped as oxide, usually 5bz03
nO□ can be used alone or in combination, and the reason is that
This is because such a material has a property of high electrical conductivity, that is, low resistivity, and therefore it is possible to match the resistance value of the resistor according to the present invention, which is a composite of a conductive material and glass, to the target. be.

sb doped into SnO□, undoped Sn
The resistance value is low (compared to O□), and the resistance value increases as the amount of doping increases.
For the following, the appropriate doping amount is 0 to 20% in terms of 5bzOa oxide, and the desirable range is 0.
．． 1 to 15%, a particularly desirable range is 1 to 10%,
Further, if the resistance according to the present invention is IOMΩ or more, the above-mentioned doping amount can be 20% or more in terms of 5b20a oxide.

If the particle size of the glass according to the present invention is too small, the above-mentioned resistance value becomes too large, which is undesirable. If it is too large, the glass cannot be sufficiently wetted, and the sintered layer has many pores, which is not preferable.

The required average particle diameter is 0.5 to 6 μm, and the desirable range is 1 to 5 μm.

On the other hand, if the particle size of the conductive material powder according to the present invention is too small, the resistance value will become large (unpreferably), and if it is too large, it will become uneven on the ceramic substrate and the variation in resistance value will become large (unpreferably). No. Average particle size is 0.01~
The necessary range is 5 μm, and the desirable range is 0.5 μm.
05-3 μm.

The glass powder according to the present invention has an inorganic component of substantially 5iOz 7-50%A1□030-
20% MgO+CaO+Sr0 10-60% (Mg0
0~40%, CaOO~40%, SrOO~60%
) Li20+Na2O+ to 20+C5zOo~to%p
bo o~10%Zn0
0~20% Zr0z+Ti0z 0~10%8203
5~40% TazOs+NbzOs 0.1~60%Ta
zOs 0~60%Nb2O50~5
0%, and these will be explained in turn.

In such a composition, SiO□ is a glass network former, and if it is less than 7%, the softening point becomes too low, the heat resistance decreases, and deformation is likely to occur during re-firing, which is not preferable.

On the other hand, when SiO This is not appropriate because the stability of the resistance will deteriorate. Desirably, it is in the range of 10 to 45%.

Although A1□03 is not essential, its inclusion is effective in improving moisture resistance. If it exceeds 20%, the softening temperature of the glass will become high and the sinterability will deteriorate, making it unsuitable. It is preferably 18% or less.

MgO+CaO+SrO functions to improve the solubility during glass powder production and to adjust the coefficient of thermal expansion. 1
If it is less than 0%, the above-mentioned solubility will not be sufficiently improved, and devitrification will easily occur during glass production. is within the range of

Also, MgO, Ca in the above MgO+CaO+SrO
If O is 40% or more, the coefficient of thermal expansion becomes too large, which is inappropriate. A desirable range is 0-35%. SrO in the above MgO+CaO+SrO is 60
% or more, the coefficient of thermal expansion becomes too thick (too large, which is inappropriate).The desirable range is 0 to 55%.

Although 20+Cs2O is not essential to LizO+NazO+, it can improve the solubility of glass and has the effect of increasing the resistance value. If it exceeds 10%, the coefficient of thermal expansion becomes too large (too much), the matching with the substrate becomes poor, and the possibility of cracks appearing in the thick film after firing becomes large, which is not appropriate.The coefficient of thermal expansion is preferably 8% or less.

Although PbO is not essential, it is effective as a flux component of the glass and also has the effect of increasing the resistance value. 10
% is not suitable because the resistance value becomes unstable. It is preferably 5% or less.

Although ZnO is not essential, it can be contained up to 20% to improve the solubility of the glass, with a desirable range of 15% or less.

Although ZrO□+TiO□ is not essential, adding it can improve the moisture resistance reliability of the resistor. The amount added can be 10%, but is preferably 7% or less.

B20. is used as a flux component, but if it is less than 5%, the softening point will be high, resulting in insufficient sintering, and the sintered layer will have too many pores. Moreover, if it exceeds 40%, the water resistance of the glass decreases and is not suitable. It is preferably in the range of 7 to 38%.

TazOs and Nb2O5 are used to adjust the resistance value and temperature coefficient of resistance (TCR).

By introducing Taxes and NbzOs, it is possible to move the resistance value in a higher direction, and there is also the effect of moving the TCR in a positive direction. The mouse decides to match the target resistance value.

However, Taxes is 60%, Nb2O is 50%, Ta
When the content of 205+NbzOs exceeds 60%, vitrification becomes difficult, and when the content of 20g of TazOs+Nb is 0.1 or less, the effect is small. The desirable range of Ta205 is 0-50%
, the desirable range of Nb2O5 is 0-45%, Ta205
The desirable range of +Nb2O5 is 1 to 50%.

Ta205. The necessary and desirable ranges of Nb2O5 and TazOs+NbzOs are shown in FIGS. 1, 2, and 3, respectively.

Figure 1 is an explanatory diagram showing the necessary and desirable ranges for the resistance value of the amount of TaJs when Ta2es is used alone (NbzOs:O), and Figure 2 is an explanatory diagram showing the necessary and desirable ranges for the resistance value of TaJs when Ta2es is used alone (NbzOs:O). Fig. 3 is an explanatory diagram showing the necessary range and desirable range of the resistance value of the amount of TazOs + NbzOs when used. Furthermore, the main points of Figures 1 to 3 are summarized below.

Usage range of Taz05+NbJs for each resistance value when TaaOs and Nb2O5 are used alone Usage range of Ta2es and NbzOs for each resistance value when TazOs and Nb2O5 are used together Desirable composition of the glass powder described above The scope can be summarized as follows.

Si0□ 10~45% Al2O30~
18% MgO+CaO+SrO15-55% (Mg00-35%, Ca00-35%, Sr00
~55%) LizO+NazO+KzO+C5zOO~
8%pbo o~5% ZnO0~15% Zr0z+Ti0z Q~7%
8203 7-38%Taz
Os+NbzOs 1~50%Ta2
05 0-50%Nb2O5O
~45% The composition of the resistor paste of the present invention is one in which each powder is mixed in the above ratio, and below is an example of the method for producing the resistor paste of the present invention and the production of a thick film circuit using the same. I will explain about it.

An organic vehicle consisting of an organic binder and a solvent is added to the composition of the resistor paste of the present invention and mixed to form a paste. The organic binder includes ethyl cellulose, acrylic resin, ethylene-vinyl acetate copolymer resin, polyα-methylstyrene resin, and the solvent includes α-
Terpineol; butylcarpitol acetate; butylcarpitol, 2,2,4-1-limethylbencunediol-1,3,-monoisobutyrate; diethylene glycol di-n-butyl ether, etc. can be commonly used. Furthermore, a surfactant may be added as a dispersant.

Next, in order to create a conductor on the solidified alumina substrate after firing or a ceramic substrate such as a glass-ceramic substrate, a conductor paste such as Cu paste containing Cu as a main component is formed into a predetermined circuit pattern by a method such as printing. After drying, it is fired at about 800 to 1000° C. for about 5 to 30 minutes in a non-oxidizing atmosphere such as a nitrogen atmosphere with an oxygen concentration of about 20 ppm or less. The desirable range of this firing condition is 880 to 9
20°C, 7 to 15 minutes. Next, the resistor paste of the present invention is printed on a predetermined location where a resistor is to be provided, dried, and heated at about 800 to 10 °C in the nitrogen atmosphere at 5°C.
Bake in about 30 minutes. The preferred range of firing conditions is 880-920°C and 7-15 minutes.

In the case of bulk firing of multilayer ceramic substrates, ceramic gnome sheets for ceramic substrates printed with the above-mentioned Cu paste and the resistor paste of the present invention are laminated after thermocompression bonding, and then heated for 800 min in a non-oxidizing atmosphere such as the above-mentioned nitrogen atmosphere. ~
About 1000℃.

Batch firing is performed in a few minutes to several hours to create a multilayer board.

Note that 0 to 5% of a coloring pigment such as a metal oxide or a heat-resistant inorganic pigment can be added to the resistor paste of the present invention for coloring.

Further, during glass production, 0 to 5% of nitrates, arsenous acid, sulfates, fluorides, chlorides, etc. can be added as clarifying agents and melting accelerators.

[Example] Each raw material of the glass powder according to the present invention is shown in terms of oxides.
Mix the proportions shown in 1, put this in a platinum crucible, and 13
The mixture was heated and stirred at 50 to 1500°C for 2 to 3 hours. Next, this was pulverized into water or flakes, and further pulverized using a pulverizer to an average particle size of 0.5 to 6 μm to produce glass powder. Next, SnO□ powder doped with 5% of SnO□ and/or sb as a conductive material in terms of 5b2o oxide was adjusted to have an average particle size of 0.01 to 51 tm. Next, these glass powders and the above-mentioned conductive material powder were mixed in the proportions shown in Table 1 to obtain a composition for the resistor paste of the present invention.

Next, an organic vehicle consisting of ethyl cellulose as an organic binder and α-terpineol as a solvent was added and kneaded to prepare a paste having a viscosity of 30×10′ cps. Next, on the solidified alumina substrate, a Cu paste was screen printed as a resistor electrode according to the present invention in a predetermined circuit, dried, and fired at 900° C. for 10 minutes in a nitrogen atmosphere with an oxygen concentration of 20 ppm or less.

Next, the above resistor paste was screen printed on a predetermined location of the resistor using a 200 mesh screen, dried, and the oxygen concentration was reduced to 2.
It was fired at 900° C. for 10 minutes in a nitrogen atmosphere of 0 ppm or less. The fired film thickness was about 15 μm.

In this way, a circuit was created on the ceramic substrate. Regarding this circuit, the resistance value, temperature coefficient of resistance (TCP), and resistance value drift due to high temperature storage were measured. These results are shown in Table 1. As is clear from Table 1, the resistor paste according to the present invention has excellent resistance characteristics and is recognized to have characteristics that can be used sufficiently as a resistor paste for thick film circuits.

As a comparative example, similar evaluations were conducted on resistor pastes other than the resistor paste according to the present invention, which are listed in Table 1.

The method for measuring each characteristic is as follows.

i) Resistance value and temperature coefficient of resistance (TCR) 25°C, -5
Resistance value at 5℃, +125℃ (R25゜R-ss +
R+zs) was measured using a resistance meter in a constant temperature bath, and calculated using the following formula.

ii) Resistance value drift due to high temperature storage The resistance value was calculated by the following formula after being left in a constant temperature bath at 150° C. for 100 hours.

In the above formula R100I’l” Resistance value after 100 hours R.

=Initial value of resistance [Effects of the invention] The resistor paste of the present invention can be fired in a non-oxidizing atmosphere such as a nitrogen atmosphere, and a stable and highly reliable resistor can be formed on a ceramic substrate. In particular, the effect of excellent resistance value drift characteristics when left at high temperatures is also recognized.

[Brief explanation of the drawing]

FIG. 1: An explanatory diagram showing the necessary range and desirable range of the amount of Ta1ls with respect to the resistance value when Ta*Os is used alone (Nb20g=0). Figure 2: Explanatory diagram showing the necessary range and desirable range of the resistance value of the amount of NbJs when Nb2O5 is used alone (Ta20s"0). Figure 3: The necessary range of the resistance value of the amount of TaJs + NbaOs Explanatory diagram showing ranges and desirable ranges.

Claims (2)

[Claims] (1) The inorganic component is substantially 2% by weight of glass powder.
Sn doped with 0-70 and SnO_2 and/or Sb
It consists of O_2 powder 30-80, and the glass powder is substantially SiO_27-50, Al_2O_3 in weight%.
0~20, MgO+CaO+SrO10~60, MgO
0~40, CaO0~40, SrO0~60, Li_2
O+Na_2O+K_2O+Cs_2O0~10,Pb
O0~10, ZnO0~20, ZrO_2+TiO_2
0~10, B_2O_35~40, Ta_2O_50~
60, Nb_2O_50~50, Ta_2O_5+Nb
A resistor paste consisting of _2O_50.1 to 60. (2) A ceramic substrate fired using the resistor paste described in item 1.