Claims
- 1. A method of detecting the presence of gaseous NO.sub.2 and more strongly oxidizing gases in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing an electro-chemical gas sensing cell including a sensor formed of a doped chalcogenide glass consisting of about 60 mole percent selenium, 28 mole percent germanium, 12 mole percent antimony and containing as a dopant about 1% to about 4% by weight of iron, an electrolyte contacting a side of said sensor, and a reference electrode contacting said electrolyte,
- exposing the doped chalcogenide glass sensor on the side opposite to said electrolyte -- contacting side to a sample of the gaseous atmosphere, and
- measuring the electrical signal developed by the cell in response to the exposure of the doped chalcogenide glass sensor to the gas sample.
- 2. A method as set forth in claim 1, further including providing a predetermined electrical potential across the doped chalcogenide glass sensor and the reference electrode,
- passing an electrical current between the doped chalcogenide glass sensor and a second electrode, and
- measuring the electrical current passing between the doped chalcogenide glass sensor and the second electrode as the doped chalcogenide glass sensor is being exposed to the gas sample.
- 3. A method of detecting the presence of more strongly oxidizing gases than gaseous NO.sub.2 in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing an electro-chemical gas sensing cell including a sensor formed of a doped chalcogenide glass consisting of 15% MnAs.sub.2 S.sub.3, an electrolyte contacting a side of said sensor, and a reference electrode contacting said electrolyte,
- exposing the doped chalcogenide glass sensor on the side opposite to said electrolyte -- contacting side to a sample of the gaseous atmosphere, and
- measuring the electrical signal developed by the cell in response to the exposure of the doped chalcogenide glass sensor to the gas sample.
- 4. A method as set forth in claim 3, further including providing a predetermined electrical potential across the doped chalcogenide glass sensor and the reference electrode,
- passing an electrical current between the doped chalcogenide glass sensor and a second electrode, and
- measuring the electrical current passing between the doped chalcogenide glass sensor and the second electrode as the doped chalcogenide glass sensor is being exposed to the gas sample.
- 5. A method of detecting the presence of gaseous NO.sub.2 and more strongly oxidizing gases in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing a first electro-chemical gas sensing cell including a doped chalcogenide glass sensor of about 60 mole percent selenium, 28 mole percent germanium, 12 mole percent antimony and containing as a dopant about 1% to about 4% by weight of iron, an electrolyte contacting a side of said sensor, and a reference electrode contacting said electrolyte for producing an electrical signal from said first cell representative of the presence of gaseous NO.sub.2 and more strongly oxidizing gases in response to the exposure of the doped chalcogenide glass of said first cell to a sample of the gaseous atmosphere,
- providing a second electro-chemical gas sensing cell including a doped chalcogenide glass sensor of 15% MnAs.sub.2 S.sub. 3, an electrolyte contacting a side of said sensor, and a reference electrode contacting said electrolyte for producing an electrical signal from said second cell representative of the presence of more strongly oxidizing gases than NO.sub.2 in response to the exposure of the doped chalcogenide glass sensor of said second cell to the same gas sample,
- exposing the respective doped chalcogenide glass sensors of said first and second electro-chemical sensing cells on the sides opposite to said electrolyte -- contacting sides to a sample of the gaseous atmosphere,
- measuring the respective electrical signal developed by said first and second cells in response to the exposure of the doped chalcogenide glass sensors thereof to the gas sample, and
- determining from the presence or absence of electrical signals developed by said first and second cells whether NO.sub.2 and more strongly oxidizing gases are present in the gas sample.
- 6. A method of detecting the presence of gaseous NO.sub.2 and more strongly oxidizing gases in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing an electro-chemical gas sensing cell including a doped chalcogenide glass consisting of about 60 mole percent selenium, 28 mole percent germanium, 12 mole percent antimony and containing as a dopant about 1% to about 4% by weight of iron, an electrical conductor connected to one side of said glass, an electrolyte material contacting the other side of said glass, and a reference electrode contacting said electrolyte material,
- exposing said one side of said glass to a sample of the gaseous atmosphere, and
- measuring the electrical signal developed by the cell in response to the exposure of said one side of said glass to the gas sample.
- 7. A method as set forth in claim 6, further including providing a pre-determined electrical potential across said glass and said spaced apart reference electrode included in the electrochemical gas sensing cell,
- passing an electrical current between said glass and a second spaced apart electrode of the electro-chemical gas sensing cell, wherein said glass, the reference electrode, and the second electrode are spaced from each other but in engagement with said electrolyte material, and
- measuring the electrical current passing between said glass and said the second electrode as said glass is being exposed to the gas sample.
- 8. A method of detecting the presence of more strongly oxidizing gases than gaseous NO.sub.2 in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing an electro-chemical gas sensing cell including a chalcogenide glass consisting of 15% MnAS.sub.2 S.sub.3, an electrical conductor connected to one side of said glass, an electrolyte material contacting the other side of said glass, and a reference electrode contacting said electrolyte material,
- exposing said one side of said glass to a sample of the gaseous atmosphere, and
- measuring the electrical signal developed by the cell in response to the exposure of said one side of said glass to the gas sample.
- 9. A method as set forth in claim 8 further including providing a pre-determined electrical potential across said glass and said spaced apart reference electrode included in the electro-chemical gas sensing cell,
- passing an electrical current between said glass and a second spaced apart electrode of the electro-chemical gas sensing cell, wherein said glass, the reference electrode, and the second electrode are spaced from each other but in engagement with the electrolyte material, and
- measuring the electrical current passing between the said glass and the second electrode as said glass is being exposed to the gas sample.
- 10. A method of detecting the presence of gaseous NO.sub.2 and more strongly oxidizing gases in a gaseous atmosphere including at least one gas taken from the group consisting of CO, O.sub.2, N.sub.2, SO.sub.2, NO and chemically compatible mixtures of these gases, said method comprising:
- providing a first electro-chemical gas sensing cell including a chalcogenide glass of about 60 mole percent selenium, 28 mole percent germanium, 12 mole percent antimony and containing as a dopant about 1% to about 4% by weight of iron, an electrical conductor connected to one side of said glass, an electrolyte material contacting the other side of said glass, and a reference electrode contacting said electrolyte material for producing an electrical signal from said first cell representative of the presence of gaseous NO.sub.2 and more strongly oxidizing gases in response to the exposure of said one side of said glass of the first cell to a sample of the gaseous atmosphere,
- providing a second electro-chemical gas sensing cell including a chalcogenide glass of 15% MnAs.sub.2 S.sub.3, an electrical conductor connected to one side of said glass, an electrolyte material contacting the other side of said glass, and a reference electrode contacting said electrolyte material for producing an electrical signal from said second cell representative of the presence of more strongly oxidizing gases than NO.sub.2 in response to the exposure to said one side of said chalcogenide glass of said second cell to the same gas sample,
- exposing said one sides of the respective glasses of the said first and the said second electro-chemical sensing cells to a sample of the gaseous atmosphere,
- measuring the respective electrical signals developed by said first and second cells in response to the exposure of said one side of the respective chalcogenide glasses thereof to the gas sample, and
- determining from the presence or absence of electrical signals developed by said first and second cells whether NO.sub.2 and more strongly oxidizing gases are present in the gas sample.
Parent Case Info
This is a division of application Ser. No. 370,898, filed June 18, 1973, now U.S. Pat. No. 3,909,384, issued Sept. 30, 1975.
US Referenced Citations (7)
Divisions (1)
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Number |
Date |
Country |
Parent |
370898 |
Jun 1973 |
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