DE2720474A1 - SENSOR FOR SENSING THE CONCENTRATION OF A SPECIES IN A FLUID - Google Patents

Description

Dipl-lng

E. Prince

Parentanwaiie

Dipl.-Chem

Dr. G. Hauser

Ernsbergerstrasse

8 Munich 60

Dipl-lng

G. Quieter

THOMSON - CSP

173, vol. Haussmann

75008 PARIS / France

May 6, 1977

Our reference: T 2192

Sensor for sensing the concentration of a species in a fluid

The invention relates to a new electrochemical sensor for sensing the concentration of a chemical species in a fluid and in particular a gas based on the principle of the concentration element.

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Several sensors of this type are known.

The sensor according to the invention, in which of the solid-state technology and use of thin film technology allows low temperature operation with response times compatible with real-time measurement.

The probe for sensing the concentration of a particular species in a fluid, with two electrodes that are connected by one solid electrolytes are separated from each other, wherein the first electrode is immersed in the fluid to be analyzed and for the species to be investigated is able to bring about its conversion into ions by catalysis, and the second electrode is capable of an electrochemical reference potential by exchanging the ions with the electrolyte to create, is characterized according to the invention in that the first electrode, the solid electrolyte and the second Electrode form three thin layers superimposed on one another on a substrate, the solid electrolyte and the substrate separate the second electrode from the fluid to be analyzed, and that means for connecting the two electrodes are provided with the two terminals of a voltmeter.

Several exemplary embodiments of the invention are described in more detail below with reference to the accompanying drawings described. Show it:

Fig. 1 is a cross section through a first

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- 3r -

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Embodiment of the invention, FIG. 2 an explanatory curve,

3 shows a section through a second

Embodiment of the invention,

4 in a perspective illustration

a third embodiment of the invention, and

5 its electrical equivalent circuit diagram,

In the following, as a non-limiting example, oxygen is assumed as the species to be analyzed. As is well known, its ionization reaction is:

O ₂ + 4e-2 O ² "

Fig. 1 shows an exemplary embodiment of the sensor according to the invention.

It contains a substrate 1, which is responsible for the strength of the overall arrangement and that in the present case it is a good electrical conductor. For example, it can be metal Act.

Several layers are applied to this substrate: a layer 2, the properties of which are given below; this layer is in a layer 3 of one solid electrolyte embedded; on the latter

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Layer is a conductive layer 4 applied. The overall arrangement is immersed in an oxygen atmosphere.

The different layers are structured as follows:

a) Layer 2: this layer consists of a material that is a good electrical conductor. It contains ions of the to be analyzed and it is able to exchange ions of this type, i.e. to give up or to receive ions.

2-In the case of oxygen, it is able to give or receive 0 ions.

It has a chemical stability over time that is compatible with the duration of the measurement. In the case of oxygen, it consists of an M / MO (M for metal) system, which is for example a non-stoichiometric mixture, such as Cu / CuO, Cu / Cu ₂ O, Pb / PbO, Fe / FeO, FeJQ, / FsJDy

Their thickness is on the order of a micrometer. It can be deposited on the substrate in a vacuum Deposition in the vapor phase, by electrolytic deposition or by thermal treatments or can be made by implantation. Their final shape can be obtained by photolithogravure.

This electrode, which serves as a reference electrode, is surrounded by the solid electrolyte.

b) the electrode 4 is able to act as a catalyst for the

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Ionization of the species to be analyzed and to serve only that species. In the case of oxygen, it should be able to convert O ₂ atoms into ions through the following chemical reaction: 4e + O ₂ - * - 2 O ² "

The ion obtained has an electrical charge of -2e. The electrode may be made of a metal (platinum, silver), or a compound of the type Na _x W ₁ "0_ by any thin film deposition method (sputtering, etc.) are prepared.

c) The solid electrolyte 3 should be placed between the two electrodes be pasted thin layer. The material from which it is made is said to be a poor conductor for the electrons while on the other hand it should be a good conductor for the ions of the species to be analyzed.

Its thickness can vary from 50 Å to 100 µm.

It can be produced by the following known processes: for example, by deposition in a vacuum (cathode sputtering, Vapor deposition), vapor deposition, electrochemical deposition or a combination all of these treatments with thermal treatments in adapted atmospheres or with ion implantation treatments.

A good example of a solid electrolyte for the

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Oxygen ions is a material with the formula (Zr O ₂ ) _χ (Ca O) ^ _x , where 0.80 <X <0.95 applies.

Two electrical contacts 5 and 6 connect the substrate and the electrode 4 to one and the other of, respectively two terminals of a voltmeter 7 (voltmeter with high impedance).

The arrangement works as follows:

The electrode 4 by catalysis converts the oxygen atoms to in I _o nen. The solid electrolyte 3 can also receive ions from the electrode 2 or from the electrode 4. Depending on the partial pressure of the oxygen, an EMF forms between the electrodes 2 and 4 in the event of equilibrium in one or the other direction.

The voltmeter 7 measures this emf.

It can be shown that this EMF V (measured in volts) with the partial tension of 0 «by Nernst's law is linked:

Po ₂

^v - I

where:

Z is the electrical charge of the ion to be analyzed, Z - 2 applies to oxygen,

F is the Faraday constant,

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T is the absolute temperature,

Po ~ is the partial pressure of the oxygen in the to be analyzed Fluid, and

P ¹ O ₂ is the pressure of the oxygen in equilibrium with the M / MO system of electrode 2.

Fig. 2 shows the curve of the change in EMF V as a function from the partial pressure Po, where Po is plotted on a logarithmic scale (log Po) for a given temperature is.

3 shows in section a further exemplary embodiment at which is made use of the planar technique. The different reference numbers denote the same elements therein as in Fig. 1. The substrate 100 is insulating and the electrode 2 is partially buried and conductive Layer 8 extended to which the ohmic contact 6 is soldered.

Fig. 4 shows a third embodiment of the invention in perspective. In this case it is Substrate 100 a p-type semiconductor. On this substrate is a MOS transistor 15 has been integrated, the source and drain electrodes of which in FIG. 4 are not visible n-diffusions are. A contact 11 has been applied to the source electrode, through a conductive layer 14 which is on the substrate is applied, with the in, Fig. 4 not visible layer 2 is connected. The same applies to the drain electrode a contact 10 has been applied, which with a conductive

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trending layer 16 is connected. This layer is isolated from the substrate.

An insulating layer 9 is located between the drain electrode and the source electrode and adjoining the electrolyte 3 upset. The metallic gate electrode is on top of this layer 13, which is connected to the electrode 4.

5 shows the electrical equivalent circuit diagram. Layer 2 is connected to ground and to the drain electrode of the transistor 15 connected. The layer 4 is connected to the gate electrode of this transistor, the source electrode 10 of which has a Ammeter 18 is connected to the positive terminal of a battery 16.

The transistor also serves as an impedance matching element and as an amplifier. Its input impedance is much greater than that of the electrochemical cell.

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Claims (6)

Patent attorneys Dipl.-Ing. Dipl.-Chem Dipt-Ing. E. Prince - Dr. G. Hauser - G. Leiser Erns "bergerstrasse19. Fc / / U 4/4 8 Munich 60 THOMSON - GSP May 6, 1977 173, vol. Haussmann 75008 PA RIS / France Our reference: T 2192 PATENT CLAIMS; (J !.) Probe for sensing the concentration of a species in a fluid, with a first and a second electrode, which are separated from one another by a solid electrolyte wherein the first electrode in contact with the fluid is capable of selectively converting the species into electrical To convert charge-bearing ions, and wherein the second electrode is embedded in the solid electrolyte and is able to exchange ions with the electrolyte, which is conductive for the ions, and with electrical contacts, which establish the connection of the electrodes with one or the other terminal of a voltmeter, characterized in that the first electrode, the solid electrolyte and the second electrode are each thin layers which are superimposed on one another on a substrate which ensures the strength of the overall arrangement. 2. Sensor according to claim 1, characterized in that the species is oxygen. 7 09847/0939 ORIGINAL INSPECTED 3. Sensor according to claim 2, characterized in that the second electrode consists of a metal-oxide system of this metal is formed. 4. Sensor according to claim 1, characterized in that the substrate consists of a conductive material and the contact forms on the second electrode. 5. Sensor according to claim 1, characterized in that the substrate is an insulator or a lightly doped semiconductor is that the contact on the first electrode is connected to ground and that an electrical contact on the second Electrode is formed over the layer consisting of the solid electrolyte. 6. Sensor according to claim 5, characterized in that the contact on the first electrode with the gate electrode is one MOS transistor integrated on the substrate is connected, the source electrode of which is connected to the second electrode and to Ground is connected, while its drain electrode is connected to a fixed voltage source via an ammeter. 7uab47.'ü939