DE10245106A1 - Glass-ceramic material suitable for making electrical phase shift component operating at specific frequencies, has specified relative permittivity - Google Patents

Abstract

The relative permittivity is selected in the range 100-1000, inclusive. An Independent claim is included for the corresponding phase shifter (1).

Description

The invention relates to a glass-ceramic composition with at least one ceramic material and at least one glass material, the ceramic material having ceramic particles with an average grain size d ₅₀ of less than 1.0 μm and a permittivity of the ceramic material depending on an external electric field. In addition, a device for changing a phase position of a periodically changing electrical signal using at least one voltage-dependent capacitance and an electrical component with the device for changing the phase position of an electrical signal are specified.

A glass-ceramic composition is known from WO 01/68554 A1, which is composed of a glass material and a ceramic material. The ceramic material is based, for example, on the barium strontium titanate (Ba ₁ _ _x Sr _x TiO ₃ , BST) system. The glass material is a borosilicate glass mixed with alkaline earth oxides. The well-known glass-ceramic composition is characterized by a low sealing firing temperature of below 950 ° C. As a result, the glass-ceramic composition can be used in LTCC (Low Temperature Cofired Ceramics) technology, in which a passive electrical component made of highly electrically conductive silver or copper can be integrated in the volume of a ceramic multilayer body. In addition, the well-known glass-ceramic composition is characterized by a very high relative permittivity ε of over 10,000 and a temperature response of the permittivity with X7R characteristics. The ceramic materials of the barium strontium titanate system are electrically controllable. This means that depending on an electrical field in which the ceramic materials are located, the respective permittivity changes.

A device of the aforementioned Type is called an electrical phase shifter. Under phase shifter is understood an electrical circuit or other arrangement, the one you want mostly frequency dependent Phase difference between an electrical input variable (AC voltage, Alternating current) and an electrical output variable. As a phase shifter for example, a varactor diode is used. The varactor diode is a semiconductor device with voltage-dependent capacitance. she will for frequency multiplication, frequency conversion and electronic Detuning of resonance circuits used.

Object of the present invention is one way to create a compact device for changing a To obtain the phase position of a periodically changing signal.

To achieve the object, a glass-ceramic composition with at least one ceramic material and at least one glass material is specified, the ceramic material having ceramic particles with an average grain size d ₅₀ of less than 1.0 μm and a permittivity of the ceramic material depending on an electric field, in where the ceramic material is. The glass-ceramic composition is characterized by a relative permittivity selected from the range from 100 to 1000 inclusive. In particular, the permittivity is between 100 and 400.

The task is also solved by a device for changing a phase position of a periodically changing electrical signal with at least one voltage-dependent capacity. The device is characterized in that the voltage dependent capacity of one Capacitor with a dielectric with a glass-ceramic composition is formed.

The glass-ceramic composition consists of at least one glass material and at least one ceramic material. As a glass-ceramic composition is in particular a mixture of several glass materials and several ceramic materials possible. With the glass-ceramic composition For example, the glass material forms a matrix of glass, in the ceramic particles of the ceramic material or various ceramic materials are distributed. The glass-ceramic composition can be a glass ceramic. The glass ceramic shows next to glass also ceramic crystallization products of the glass.

The dielectric is arranged between two electrodes of the capacitor. The permittivity of the dielectric can be changed by applying an electrical voltage to the electrodes and the electrical field generated thereby (ε (V _c = 0) / ε (V _c )). The result is a capacitance that depends on the voltage applied.

Acts as a controllable dielectric component the ceramic material of the glass-ceramic composition. As a ceramic material In principle, any ferroelectric material that is im for the appropriate application needed Temperature range is paraelectric. That is sufficient low dielectric loss can be achieved.

In particular, the ceramic material has a formal composition Ba ₁ _ _x Sr _x TiO ₃ with 0 ≤ x ≤ 1. X is preferably selected from the range from 0.3 to 0.7. The ceramic material can include barium titanate (BaTiO ₃ ), strontium titanate (SrTiO ₃ ), barium strontium titanate (Ba ₁ _ _x Sr _x TiO ₃ with 0 <x <1) or a mixture of these ceramic materials. The dielectric loss of the barium stronti can be caused by a low doping of manganese or tungsten umtitanate be reduced.

In a special configuration exhibits the glass-ceramic composition a glass portion of a glass material of less than 20 vol% and one Ceramic content of a ceramic material of over 80 vol%. The glass portion is enough high chosen, so that due to the resulting low sintering temperature Glass-ceramic composition silver or copper together with the Glass-ceramic composition can be sintered. The glass portion is however also as low as possible chosen to controllability and goodness to maintain the glass-ceramic composition.

The ceramic portion can be from several ceramic materials can be formed. For example, sets the ceramic part from ceramic materials of the barium strontium titanate system different stoichiometry together. Barium is found in the various ceramic materials and strontium in different relationships. By the use of mixtures of the ceramic materials mentioned can especially the temperature dependence permittivity the glass-ceramic composition can be reduced. In addition to use of ceramic materials of a ceramic base system are also other ceramic materials conceivable as additives, with their help the dielectric properties of the glass-ceramic composition can be varied. By adding a paraelectric ceramic material with lower permittivity (e.g. magnesium oxide, MgO) can affect the permittivity of the glass-ceramic composition be humiliated. To consider is here, however, that the tunability of the glass-ceramic composition is less can be.

The glass portion can be formed from one or more glass materials. In particular, the glass material has at least one substance selected from the group consisting of boron oxide (B ₂ O ₃ ) and / or silicon dioxide (SiO ₂ ) and / or bismuth oxide (Bi ₂ O ₃ ) and / or zinc oxide (ZnO). The glass portion is preferably composed of all of the substances mentioned. Together, these substances form a glass which is particularly reactive towards strontium titanate and barium strontium titanate. Reactive liquid phase sintering can take place during compression (see below). Due to the relatively low proportion of glass, the dielectric properties of the glass-ceramic composition are mainly determined by the ceramic material. However, the glass portion helps to reduce the relative permittivity of the glass-ceramic composition compared to the permittivity of the ceramic materials. Low permittivity is desirable for use at microwave frequencies.

In a special embodiment, the ceramic material has ceramic particles with an average particle size d ₅₀ of less than 1.0 μm and in particular less than 0.5 μm. In order to achieve this, a ceramic powder with an average particle size of well below 1 μm is advantageously used to produce the glass-ceramic composition. For example, the average particle size of such a ceramic powder is less than 0.3 μm. If it is ensured that there is almost no crystal growth of the ceramic particles during compaction, ceramic powders with an average particle size of up to 1.0 μm can also be used. Almost no crystal growth takes place, for example, when the glass-ceramic composition is compacted by viscous flow.

The small ceramic particles lead to a strong oppression of the Curie peak of the ceramic material. This means that the ceramic material with the small ceramic particles compared to the ceramic material from larger ceramic particles a lower permittivity distinguished. additionally carries that Glass material of the glass-ceramic composition to reduce permittivity, so that with the aforementioned Barium strontium titanate system the relative permittivity for example from above 10,000 drops to values below 200. At the same time, the ceramic materials from small ceramic particles a lower temperature dependence permittivity on as ceramic materials with larger ceramic particles. The low temperature dependence permittivity can additionally by mixing different barium strontium titanates different stoichiometric composition can be achieved. Contrary to the strong influence on the height and the temperature dependence permittivity However, the tunability remains with these small ceramic particles permittivity the glass-ceramic composition largely preserved.

In a special configuration exhibits the glass-ceramic composition a sealing firing temperature of less than 910 ° C. This means that the Glass-ceramic composition sintered at a temperature below 910 ° C can be. The glass-ceramic composition is therefore suitable for Application in LTCC technology. Highly conductive line structures Base of silver or copper can sintered together with the device for changing the phase position become. Can be advantageous therefore controllable line and waveguide structures with one low line loss in the LTCC substrate to get integrated.

In order to maintain the low sealing firing temperature, the type of ceramic materials, the type of glass materials, their particle sizes and their proportions are matched to one another in such a way that the sintering temperatures of less than 910 ° C. not only result in compression by viscous flow due to a low temperature Glass transition point of the glass (Tg <550 ° C), but also a densification by reactive liquid phase sintering takes place. This leads to a re action of the glass material with the ceramic material and consequently to a crystallization of the glass. The resulting (ceramic) crystallization products determine the dielectric properties of the glass-ceramic composition in addition to the ceramic material used. With regard to reactive liquid phase sintering, ceramic particles with small particle sizes are particularly advantageous. Small ceramic particles are characterized by a relatively high reactivity due to their relatively large surface area.

The low sealing fire temperature is particularly also with a lead oxide and / or cadmium oxide content the glass-ceramic composition of less than 0.1% by weight and in particular less than 0.001% by weight. The low proportion of these heavy metal compounds contributes to environmental compatibility the device with the glass-ceramic composition.

In a special configuration the electrical signal has a frequency of over 10 GHz. This means, that with the device also the phase position of a high-frequency signal to be changed can. Preferably is plus the relative permittivity the glass-ceramic composition between 100 and 400. In particular a relative permittivity from under 100 to 200 is for Suitable for high frequency applications. The results are manageable Electrical sizes Components.

In particular, an unloaded dielectric quality Qu of the glass-ceramic composition is selected from the range from 10 to 500 inclusive. The dielectric quality factor Q _u is the reciprocal value of the high frequency loss factor tan δ. The dielectric quality Q _u can be adjusted over a wide range. The setting is made via the materials and the manufacture of the glass-ceramic composition.

According to a second aspect of the invention, an electrical component with a device for changing the phase position of a periodically changing electrical signal is specified. The electrical component is selected from the group of voltage-controlled oscillators and / or frequency filters and / or delay lines. Depending on which electrical component is to be equipped with the device, the dielectric quality Q _{u of} the glass-ceramic composition differs. In the voltage-controlled oscillator (VCO), the dielectric quality Qu is, for example, between 100 and 500, in the frequency filter between 10 and 50 and in the delay line between 10 and 100.

In a special configuration of the component is the device for changing the phase position in one ceramic multilayer body integrated. In particular, the multilayer body is an LTCC substrate. The The device is a capacitor integrated in the ceramic multilayer body. The The dielectric of the capacitor is, for example, due to the glass-ceramic composition a ceramic layer of the ceramic multilayer body is formed. We add the glass-ceramic composition as a ceramic green sheet integrated in the LTCC substrate. It is also conceivable that the glass-ceramic composition with Is integrated using a screen printing paste. For example in a green sheet an opening made from any glass-ceramic composition, into which the paste is applied using a screen printing technique. The following Printing with a metal paste, lamination with other ceramic Green sheets Debinding and sintering leads to a ceramic multilayer body, in the volume of which Capacitor is integrated.

The device advantageously comes in a multilayer waveguide phase shifter for phased array Transmitting antennas, in a stripline and coplanar phase shifter and used in an electrically adjustable frequency filter.

• – Es wird eine Glas-Keramik-Zusammensetzung angegeben, die trotz Glasanteil zur Reduzierung der Dichtbrandtemperatur eine gute Steuerbarkeit in einem für die Hochfrequenztechnik geeigneten Permittivitätsbereich aufweist.
• – Mit Hilfe der Glas-Keramik-Zusammensetzung ist eine kompakte spannungsabhängige Kapazität zum Verändern einer Phasenlage eines sich periodisch ändernden elektrischen Signals zugänglich.
• – Die Vorrichtung mit der spannungsabhängigen Kapazität kann mit relativ einfachen Mitteln und kostengünstig mit Hilfe der LTCC-Technologie in einem keramischen Mehrschichtkörper integriert werden.
• – Die Vorrichtung kann zusammen mit eine Vielzahl elektrischer Bauteile im keramischen Mehrschichtkörper integriert werden.
• – Die Vorrichtung zeichnet sich durch eine hohe Leistungsverträglichkeit und hohe Schaltungsgeschwindigkeit auch bei hohen Frequenzen von über 10 GHz aus.
• – Mit der Glas-Keramik-Zusammensetzung ist eine an die entsprechende Anwendung angepasste dielektrische Güte Q_u erzielbar, was zu einer relativ niedrigen Leitungsdämpfung und damit zu einem relativ niedrigen Verlust insbesondere im Hochfrequenzbereich führt.

In summary, the following significant advantages result from the invention:

• - A glass-ceramic composition is specified which, despite the glass content to reduce the sealing firing temperature, has good controllability in a permittivity range suitable for high-frequency technology.
• - With the help of the glass-ceramic composition, a compact voltage-dependent capacitance for changing a phase position of a periodically changing electrical signal is accessible.
• - The device with the voltage-dependent capacitance can be integrated in a ceramic multilayer body with relatively simple means and inexpensively with the help of LTCC technology.
• - The device can be integrated together with a large number of electrical components in the ceramic multilayer body.
• - The device is characterized by high performance compatibility and high switching speed even at high frequencies of over 10 GHz.
• - With the glass-ceramic composition, a dielectric quality Q _u adapted to the corresponding application can be achieved, which leads to a relatively low line attenuation and thus to a relatively low loss, especially in the high-frequency range.

Using several exemplary embodiments and the associated one Figures the invention is presented below. The figures is schematic and does not represent a true-to-scale illustration.

1 shows a section of a device for changing the phase position in a ceramic multilayer body

2 shows a section of a further device for changing the phase position in a ceramic body

3 shows a device for changing the phase position on a ceramic multilayer body.

The device 1 To change the phase position is a phase shifter, which is in a ceramic multilayer body 2 is integrated in the form of an LTCC substrate ( 1 and 2 ).

In an alternative embodiment, the phase shifter is applied to a ceramic body ( 3 ).

The voltage dependent capacitance is from a capacitor 3 educated. The condenser 3 consists of two electrodes 4 and 5 and one between the electrodes 4 and 5 arranged dielectric 6 , The dielectric 6 is a glass-ceramic composition. The electrodes 4 and 5 of the capacitor 3 can via the electrical vias 7 and 8th can be controlled electrically. The device 1 is part of an electrical component 9 , The ceramic multilayer body has further ceramic layers for the integration of electrical components (not shown) 12 . 13 and 14 from a glass-ceramic composition that differs from the glass-ceramic composition of the dielectric.

According to the first embodiment, the electrical component 9 an electrical delay line that goes into the dielectric 6 is embedded. Two ceramic layers form 10 and 11 of the ceramic multilayer body 2 the dielectric 6 ( 1 ). By stacking the corresponding green foils in the LTCC manufacturing process, laminating and sintering, the ceramic multilayer body is 2 available.

In a further embodiment according to 2 is the component 9 a voltage controlled oscillator. The capacitor 3 made with the help of a printable, ceramic paste. For this purpose, a green sheet is first coated with metallization to form the electrode 5 printed. The ceramic paste is then printed onto the metallization using a screen printing process. Finally, the metallization to form the electrode 4 printed on the printed ceramic paste. The ceramic green sheet printed in this way is stacked, laminated and sintered together with other green sheets. It becomes a multi-layer body 2 get in the volume of the condenser 3 is integrated.

In a further exemplary embodiment, the phase shifter is on a ceramic body 2 upset ( 3 ). The component 9 is again a delay line. The ceramic body is a ceramic multilayer body in which the dielectric 6 from the top ceramic layer 10 is formed. The ceramic layer is approximately 50 μm thick. The capacitor is on this ceramic layer 3 with the electrodes 4 and 5 educated. As a carrier layer 15 serves a ceramic layer made of aluminum oxide.

The glass-ceramic composition has a ceramic portion of the ceramic material of approximately 90 vol.% and a glass portion of the glass material of about 10% by volume.

The ceramic portion is made up of about 80% by weight of barium strontium titanate with the stoichiometric composition Ba _0.5 Sr _0.5 TiO ₃ and about 20% by weight of magnesium oxide. The average particle size d _{0 5} of these ceramic materials is about 0.5 microns.

The glass material is composed from 27% by weight boron oxide, 35% by weight bismuth oxide, 32% by weight zinc oxide and 6% by weight of silicon dioxide.

The glass-ceramic composition has a sealing firing temperature of about 900 ° C. For integration of the glass-ceramic composition in the ceramic multilayer body 2 is sintered at a temperature of 900 ° C for about an hour. The relative permittivity ε of the resulting glass-ceramic composition is approximately 520 and the high-frequency loss factor tan δ is approximately 0.008 (at 10 GHz). This corresponds to a quality factor Q _u of 125. The voltage dependence of the permittivity (ε (V _c = 0) / ε (V _c )) is approximately 1.07 at V _c = 2V / μm.

Claims (12)

Glass-ceramic composition with - at least one ceramic material and - at least one glass material, wherein - the ceramic material has a ceramic particle with an average grain size d ₅₀ of less than 1.0 μm and - a permittivity of the ceramic material depends on an external electric field, characterized by - a relative permittivity selected from the range of 100 to 1000 inclusive. A glass-ceramic composition according to claim 1, wherein the average grain size of the ceramic particles less than 0.5 μm is. Glass-ceramic composition according to claim 1 or 2, with a glass content of a glass material of less than 20 vol% and a ceramic portion of a ceramic material of over 80 vol%. Glass-ceramic composition according to one of claims 1 to 3, with a sealing firing temperature below 910 ° C. Glass-ceramic composition according to one of claims 1 to 4, wherein the ceramic material has a formal composition Ba ₁ _ _x Sr _x TiO ₃ with 0 ≤ x ≤ 1. Glass-ceramic composition according to one of claims 1 to 5, wherein the glass material at least one from the group boron oxide and / or silicon dioxide and / or bismuth oxide and / or zinc oxide selected substance having. Glass-ceramic composition according to one of claims 1 to 6, wherein a lead oxide portion and / or a cadmium oxide portion of the glass-ceramic composition is less than 0.1% by weight, in particular less than 0.001% by weight. A glass-ceramic composition according to any one of claims 1 to 7, having an unloaded dielectric grade Q _u selected from the range of 10 to 500 inclusive. Contraption ( 1 ) for changing a phase position of a periodically changing electrical signal with the aid of at least one voltage-dependent capacitance, characterized in that the voltage-dependent capacitance of a capacitor ( 3 ) is formed with a dielectric with a glass-ceramic composition, in particular with a glass-ceramic composition according to one of claims 1 to 8. The apparatus of claim 9, wherein the electrical Signal a frequency of over 10 GHz. Electrical component with a device for Change the phase position of a periodically changing electrical signal of claim 9 or 10, wherein the electrical component from the Group of voltage controlled oscillators and / or frequency filters and / or delay line selected is. Electrical component according to claim 10, wherein the device for changing the phase position in a ceramic multilayer body ( 2 ) integrated and / or applied to a ceramic multilayer body.