Inline Ion Reaction Device Cell and Method of Operation

1 . A reaction apparatus for ions comprising: a first pathway comprising a first axial end and a second axial end disposed at a distance from the first pathway axial end along a first central axis; a second pathway comprising a first axial end and a second axial end disposed at a distance from the first axial end of the second pathway along a second central axis; said first and second central axis being substantially orthogonal to one another and having an intersection point; a first set of quadrupole electrodes arranged in a quadrupole orientation around said first central axis and disposed between said first axial end of said first pathway and said intersection point, said first set of electrodes for guiding ions along a first portion of said first central axis; a second set of quadrupole electrodes arranged in a quadrupole orientation around said first central axis and disposed between said second axial end of said first pathway and said intersection point, said second set of electrodes for guiding ions along a second portion of said first central axis; the first set of electrodes being separated from the second set of electrodes so as to form a gap transverse to said first central axis; a voltage source for providing an RF voltage to said first and second sets of electrodes to generate an RF field; a controller for controlling said RF voltages; an ion source disposed at or proximate either the first or second axial end of said first pathway for introducing ions along said first central axis towards the other of said first or second axial end of the first pathway; and a charged species source disposed at or proximate either the first or second axial end of the second pathway for introducing a charged species along the second central axis, said charged species travelling through said gap towards said intersection point. 2 . The apparatus of claim 1 wherein said controller is configured to deliver voltages to said electrodes such that each electrode in said first plurality of electrodes is paired with an electrode in said second plurality of electrodes to form an electrode pair wherein each electrode in each electrode pair has opposite polarity and is directly opposite across the intersection point of the other electrode in the electrode pair and wherein the RF fields generated between said intersection point and said first axial end of said second pathway by said first and second plurality of electrodes is in reverse phase to the RF fields generated between said intersection point and said second axial end of said second pathway. 3 . The apparatus of claim 1 further comprising a magnetic field generator that generates a magnetic field parallel to and along said second central axis; 4 . The apparatus of claim 3 wherein said ions are positively charged and said charged species are electrons. 5 . The apparatus of claim 4 wherein said charged species source is a filament or a Y 2 O 3 cathode and optionally wherein the filament is a tungsten or thoriated tungsten filament. 6 . The apparatus of claim 1 wherein said charged species are reagent anions. 7 . The apparatus of claim 1 wherein said first pathway comprises a gate disposed or proximate to the axial end opposite of said first or second axial end at which said ions are introduced. 8 . The apparatus of claim 1 wherein said first pathway comprises a gate disposed at or proximate to both said first and second axial ends wherein one of said gates is for controlling the introduction of said ions and the other of said gates is for controlling the removal of said ions or the reaction products of said ions. 9 . The apparatus of claim 1 wherein said apparatus also comprises a gate electrode at or proximate to both the first and second axial end of said second pathway. 10 . The apparatus of claim 1 wherein said second pathway comprises lenses disposed at or proximate to said first or second axial ends for focusing said charged species. 11 . The apparatus of claim 1 wherein said second pathway comprises a laser source disposed at or proximate to the axial end opposite of said end for introduction of said charged species, said laser source for providing energy to said ions or said charged species. 12 . The apparatus of claim 11 wherein said laser source provides ultraviolet or infrared light. 13 . The apparatus of claim 1 wherein both of said axial ends of said second pathway comprise a charged species source and said charged species are electrons and wherein only one of said charged species sources is operational at a time. 14 . The apparatus of claim 1 wherein said ions interact with said charged species and optionally wherein the interaction causes electron capture dissociation, electron transfer dissociation or proton transfer dissociation. 15 . The apparatus of claim 1 wherein the RF fields generated are at a frequency of between about 400 kHz to 1.2 MHz. 16 . The apparatus of claim 14 wherein the frequency is about 800 kHz. 17 . A method for performing an electron capture dissociation reaction comprising: providing a first pathway comprising a first axial end and a second axial end disposed at a distance from the first pathway axial end along a first central axis; providing a second pathway comprising a first axial end and a second axial end disposed at a distance from the second pathway axial end along a second central axis; positioning said first and second central axis such that the first and second central axis are substantially orthogonal to one another and having an intersection point; providing a first set of quadrupole electrodes arranged in a quadrupole orientation around said first central axis and disposed between said first axial end of said first pathway and said intersection point, said first set of electrodes for guiding ions along a first portion of said first central axis; providing a second set of quadrupole electrodes arranged in a quadrupole orientation around said first central axis and disposed between said second axial end of said first pathway and said intersection point, said second set of electrodes for guiding ions along a second portion of said first central axis; the first set of electrodes being separated from the second set of electrodes so as to form a gap transverse to said first central axis; providing a magnetic field parallel to said second central axis; providing RF voltages to said first and second sets of electrodes; providing a controller for controlling the RF voltages so as to control the RF fields generated by said first and second sets of electrodes; introducing a plurality of positively charged ions into either the first or second axial end of said first pathway along said first central axis; and introducing electrons into the first or second axial end of the second pathway along the second central axis, said electrons travelling through said gap towards said intersection point. 18 . The method of claim 17 further comprising: providing a gate in said first pathway at or proximate to the axial end that is opposite of said axial end wherein said positively charged ions are introduced, said gate being switchable between an open and closed position wherein when in an open position, said ions or product of said ion reaction is allowed to pass and when in a closed position, said ions or product of said ion reactions is not allowed to pass. 19 . The method of claim 18 wherein said gate is open continuously. 20 . The method of claim 18 further comprising: controlling the l