Simultaneous positive and negative ion accumulation in an ion trap for mass spectroscopy

What is claimed is: 1. An ion reaction device, comprising: an ion injection inlet for receiving a plurality of ions and an ion ejection outlet through which ions can exit the device, a plurality of non-linear rods disposed relative to one another so as to provide an axial region configured to receive a plurality of anions and cations via said ion injection inlet, and a plurality of trapping regions in communication with the axial region in which said anions and cations can be confined, the plurality of non-linear rods defining a pair of quadrupole rod sets wherein said quadrupole rod sets are stacked relative to one another so as that each non-linear rod in one of said quadrupole rod sets is disposed below a respective non-linear rod of the other of the pair of quadrupole rod sets and in substantial register therewith, each of the non-linear rods includes a longitudinal portion and a transverse portion forming an angle relative to the longitudinal portion, the axial region being spatially defined by the longitudinal portions of the non-linear rods, and the plurality of trapping regions comprise two trapping regions spatially defined by said transverse portion of the non-linear rods, each of said two trapping regions extending from a proximal opening in communication with said axial region to a distal opening, and a DC voltage source adapted to apply a DC voltage across at least two of said non-linear rods so as to generate a dipolar electric field within at least a portion of said axial region for spatially separating the received anions and cations and guiding said anions into one of said two trapping regions and the cations into the other of said two trapping regions, first and second lenses, wherein one of said lenses is disposed in proximity of said distal opening of the two trapping regions and the other one of said lenses is disposed in proximity of said distal opening of the other of the two trapping regions, said lenses being adapted for application of DC bias voltages thereto for facilitating trapping of the anions and cations in the respective two trapping regions. 2. The ion reaction device of claim 1 , wherein said non-linear rods are L-shaped rods. 3. The ion reaction device of claim 1 , further comprising a third lens disposed upstream of said plurality of rods and adapted for application of a DC voltage thereto, wherein said third lens comprises a plate having an orifice forming said ion injection inlet. 4. The ion reaction device of claim 3 , further comprising a fourth lens dispose downstream of said plurality of rods and adapted for application of a DC voltage thereto, wherein said fourth lens comprises a plate having an orifice forming said ion ejection outlet. 5. The ion reaction device of claim 4 , further comprising a fifth lens disposed in said axial region in proximity to said proximal openings of said trapping regions. 6. An ion reaction device, comprising: an ion injection inlet for receiving a plurality of ions and an ion ejection outlet through which ions can exit the device, a plurality of non-linear rods disposed relative to one another so as to provide an axial region configured to receive a plurality of anions and cations via said ion injection inlet, and a plurality of trapping regions in communication with the axial region in which said anions and cations can be confined, the plurality of non-linear rods defining a pair of quadrupole rod sets and a DC voltage source adapted to apply a DC voltage across at least two of said non-linear rods so as to generate a dipole electric field within at least a portion of said axial region for spatially separating the received anions and cations and guiding said anions into one of said trapping regions and the cations into another one of said trapping regions, wherein said DC voltage source is connected at one of one terminal to a subset of said non-linear rods and at another terminal to another subset of said non-linear rods so as to generate the dipole electric field in at least a portion of said axial region, and each terminal thereof to two non-linear rods of one of said pair of quadrupole rod sets and to two non-linear rods of the other of said pair of quadrupole rod sets, where said two non-linear rods of one of said pair of quadrupole rod set are vertically stacked relative to said two non-linear rods of the other of said pair of quadrupole rod sets, so as to generate the dipole electric field in at least a portion of said axial region. 7. The ion reaction device of claim 1 , further comprising a first RF source for applying RF voltages to said non-linear rods configured to provide radial confinement of said anions and cations. 8. The ion reaction device of claim 7 , further comprising a second RF source for applying RF voltages to said non-linear rods configured to provide axial confinement of said anions and cations. 9. The ion reaction device of claim 8 , wherein said first and second RF sources are configured to apply RF voltages having the same frequencies to said non-linear rods. 10. The ion reaction device of claim 8 , wherein said first and second RF sources are configured to apply RF voltages having different frequencies to said non-linear rods. 11. A mass spectrometer, comprising: a plurality of ion sources, wherein at least one of said sources is adapted to generate anions and another of said sources is adapted to generate cations, an ion reaction device configured to receive said anions and cations, said reaction device comprising an ion injection inlet for receiving a plurality of ions and an ion ejection outlet through which ions can exit the device, a plurality of non-linear rods disposed relative to one another so as to provide an axial region configured to receive a plurality of anions and cations via said ion injection inlet, and a plurality of trapping regions in communication with the axial region in which said anions and cations can be confined, and a DC voltage source adapted to apply a DC voltage across at least two of said non-linear rods so as to generate a dipolar electric field within at least a portion of said axial region for spatially separating the received anions and cations and guiding said anions into one of said trapping regions and the cations into another one of said trapping regions, a DC deflector disposed upstream of said reaction device, said deflector having first and second inlet ports for receiving, respectively, said anions and cations from said ion sources and having an outlet port in communication with said reaction device, wherein said DC deflector is configured to guide said received anions and cations to said outlet port, wherein said DC deflector comprises a quadrupole DC deflector. 12. The mass spectrometer of claim 11 , further comprising a quadrupole lens disposed between said DC deflector and said reaction device for selecting cations and anions having an m/z ratio in a desired range. 13. The mass spectrometer of claim 11 , further comprising a quadrupole lens disposed between said sources for generating one of anions and cations and said DC deflector for selecting one of anions and cations having an m/z ratio in a desired range for delivery to said DC deflector. 14. An ion reaction device for use in a mass spectrometer, comprising: a plurality of non-linear electrodes each of which includes a longitudinal segment and a transverse segment forming a non-zero angle with the longitudinal segment, said electrodes being disposed relative to one another such that longitudinal segments of the electrodes provide an axial region therebetween having an ion injection port for receiving a plurality of anions and cati