Tandem mass spectrometer and tandem mass spectrometry method

The invention claimed is: 1. A tandem mass spectrometer, including: an ionization source suitable for producing ions; a mass analyzer including an ion trap that is arranged so that the ion trap can receive ions originating from the ion source, and detection means suitable for detecting ions exiting the ion trap based on their mass m to charge z ratio (m/z); ion activation means suitable for activating at least part of the ions trapped inside the ion trap; and coupling means ( 5 , 6 ) arranged between the ion trap and said ion activation means, wherein the ion activation means are composed of a glow discharge lamp suitable for generating a light beam directed towards the ion trap, said light beam being an electromagnetic radiation within the vacuum ultraviolet (VUV) range at photon energies ranging from 8 eV to 41 eV, in order to fragment at least part of the ions trapped inside the ion trap, wherein the wavelength of the light beam emitted by the glow discharge lamp is adjustable so as to produce various ion fragmentation products, and wherein said coupling means include vacuum mechanical connecting means and differential pumping means suitable for pumping the glow discharge lamp so as to enable simultaneous operation of the glow discharge lamp and the tandem mass spectrometer. 2. The mass spectrometer of claim 1 , additionally including control means for turning on the glow discharge lamp so as to control the start and duration of activation via VUV radiation. 3. The mass spectrometer of claim 1 , wherein said coupling means include a beam shutter for controlling the start and duration of activation via VUV radiation. 4. The mass spectrometer of claim 1 , wherein said coupling means include an optical system with a mirror and/or with a lens that is arranged so as to optimize the interaction of the VUV radiation beam with an ion packet stored inside the ion trap. 5. The mass spectrometer of claim 1 , wherein the ionization source includes an electrospray source, an electronic impact source, a chemical ionization source, a photoionization source, a matrix-assisted laser-induced desorption (MALDI) source, an atmospheric-pressure MALDI source, an atmospheric-pressure chemical ionization source, or an atmospheric-pressure photoionization source. 6. The mass spectrometer of claim 1 , wherein the glow discharge lamp is a discharge lamp in a gas of helium, neon, argon, krypton, or a mixture of a plurality of these gases. 7. The mass spectrometer of claim 1 , wherein the ion trap includes a radiofrequency ion trap, a 3D radiofrequency ion trap, or a quadrupole linear ion trap. 8. The mass spectrometer of claim 1 , wherein the detection means include an ion detector or another mass analyzer equipped with an ion detector. 9. A tandem mass spectrometry method, including the following steps: generating ions by means of an ion source; trapping at least part of the ions originating from the ion source in an ion trap; selecting and activating the trapped ions so as to activate at least part of the ions trapped inside the ion trap; and analyzing and detecting ions exiting the ion trap based on their mass m to charge z (m/z) ratio, wherein the ion selection and activation step includes i) a step of coupling a glow discharge lamp to the ion trap by vacuum mechanical connecting means and differential pumping means suitable for pumping the glow discharge lamp so as to enable simultaneous operation of the glow discharge lamp and ii) a step for photoactivation of the trapped ions by a light beam originating from the glow discharge lamp, with said light beam being an electromagnetic radiation within the vacuum ultraviolet range at photon energies ranging from 8 eV to 41 eV in order to fragment at least part of the ions trapped inside the ion trap, and wherein the ion activation step at photon energies ranging from 8 eV to 41 eV is repeated n times prior to ion detection and the wavelength of the light beam emitted by the glow discharge lamp is adjusted so as to produce various ion fragmentation products. 10. The tandem mass spectrometry method of claim 9 , wherein activation of the ions is applied for a predetermined duration. 11. The tandem mass spectrometry method of claim 9 additionally including one or plural selection steps prior to ion analysis and detection. 12. The tandem mass spectrometry method of claim 9 , wherein the ion fragments formed are different from those formed by Collision-Induced Dissociation (CID). 13. The tandem mass spectrometry method of claim 9 , wherein the ion fragments formed are different from those formed by laser dissociation.