Abstract: A sampling nozzle 21, an ion supply tube 31 leading to an analysis apparatus 50 and a barrier discharge tube 11 are connected to first, second and third ends, respectively, of a T-shaped tube 41 having three connecting ports, and the central portion of the T-shaped tube is an ionization chamber SP. The ionization chamber SP is a closed space, and ions generated therein are introduced to the analysis apparatus 50 through the ion supply tube 31. As a result, almost all of the ions are introduced into the interior of the analysis apparatus.

Abstract: A sampling nozzle 21, an ion supply tube 31 leading to an analysis apparatus 50 and a barrier discharge tube 11 are connected to first, second and third ends, respectively, of a T-shaped tube 41 having three connecting ports, and the central portion of the T-shaped tube is an ionization chamber SP. The ionization chamber SP is a closed space, and ions generated therein are introduced to the analysis apparatus 50 through the ion supply tube 31. As a result, almost all of the ions are introduced into the interior of the analysis apparatus.

Abstract: A sampling nozzle 21, an ion supply tube 31 leading to an analysis apparatus 50 and a barrier discharge tube 11 are connected to first, second and third ends, respectively, of a T-shaped tube 41 having three connecting ports, and the central portion of the T-shaped tube is an ionization chamber SP. The ionization chamber SP is a closed space, and ions generated therein are introduced to the analysis apparatus 50 through the ion supply tube 31. As a result, almost all of the ions are introduced into the interior of the analysis apparatus.

Abstract: An ionization apparatus comprises a first electrode provided on the outer periphery of a dielectric cylindrical body and a second cylindrical electrode placed inside at a center of the cylindrical body. When an AC high voltage is impressed across the first electrode and the second cylindrical electrode, a barrier discharge occurs within the cylindrical body. A distal end portion of the second cylindrical electrode projects outwardly from the distal end of the cylindrical body, a thermal equilibrium plasma P having a low electron temperature is generated outwardly from the distal end of the cylindrical body without a plasma jet ascribable to the barrier discharge emerging outwardly from the distal end of the cylindrical body. By exposing a sample S to the thermal equilibrium plasma P, particles (atoms, molecules) desorbed from the sample S undergo soft ionization without being decomposed or polymerized.

Abstract: It is arranged so that ions can be analyzed accurately and with high sensitivity. A first electrode 11 is provided on the outer periphery of a dielectric cylindrical body 13 and a second electrode 12 is placed inside the cylindrical body 13 leaving a clearance between itself and the inner surface of the cylindrical body 13. When an AC high voltage is impressed across the first electrode 11 and second electrode 12, a barrier discharge occurs within the cylindrical body 13. When a distal end portion 12a of the second electrode 12 projects outwardly from the distal end of the cylindrical body 13, a thermal equilibrium plasma P having a low electron temperature is generated outwardly of the distal end of the cylindrical body 13 without a plasma jet ascribable to the barrier discharge emerging outwardly from the distal end of the cylindrical body 13.