Abstract: An electrochemical gas generator for ammonia with the use of ionic liquids containing nitrate ions as the electrolyte and to the use of the gas generator for generating gaseous ammonia, especially for testing the function of and/or calibrating gas sensors.

Abstract: An electrochemical gas sensor system (100) detects the concentration of a harmful gas in a measuring environment (70). The electrochemical gas sensor system (100) contains a voltage generator (19) and an electrochemical gas sensor (1). The electrochemical gas sensor (1) has a sensor housing (2) and a gas inlet (18). A measuring electrode (3), an auxiliary electrode (5), a reference electrode (17), a first generator electrode (13) and a second generator electrode (14) are in an electrolyte liquid (11) in the sensor housing (2). A salt (28) (halide) of a halogen is dissolved in the electrolyte liquid (11). The first generator electrode (13) and the second generator electrode (14) are connected to the voltage generator (19) to form a galvanic source. The galvanic source causes the salt (28) (halide) to react to form a halogen (28?). A defined, largely stable reference voltage potential becomes established on the reference electrode (17).

Abstract: An electrochemical gas generator for ammonia with the use of ionic liquids containing nitrate ions as the electrolyte and to the use of the gas generator for generating gaseous ammonia, especially for testing the function of and/or calibrating gas sensors.

Abstract: An electrochemical gas sensor system (100) detects the concentration of a harmful gas in a measuring environment (70). The electrochemical gas sensor system (100) contains a voltage generator (19) and an electrochemical gas sensor (1). The electrochemical gas sensor (1) has a sensor housing (2) and a gas inlet (18). A measuring electrode (3), an auxiliary electrode (5), a reference electrode (17), a first generator electrode (13) and a second generator electrode (14) are in an electrolyte liquid (11) in the sensor housing (2). A salt (28) (halide) of a halogen is dissolved in the electrolyte liquid (11). The first generator electrode (13) and the second generator electrode (104) are connected to the voltage generator (19) to form a galvanic source. The galvanic source causes the salt (28) (halide) to react to form a halogen (28?). A defined, largely stable reference voltage potential becomes established on the reference electrode (17).

Abstract: An electrochemical gas sensor for detecting hydrocyanic acid in a gas sample has a measuring electrode (3) formed of carbon nanotubes (CNT) and a counterelectrode (8) in an electrolyte (9), which contains lithium bromide in an aqueous solution.

Abstract: An electrochemical gas sensor for detecting ozone or nitrogen dioxide in a gas sample has a measuring electrode (3) formed of carbon nanotubes (CNT) or a counterelectrode (8) in an electrolyte solution (9), which contains lithium chloride or lithium bromide in an aqueous solution.