Systems and processes for production of trisilylamine

What is claimed is: 1. A system for gas-phase synthesis of trisilylamine comprising: (a) a reactor vessel ( 2 ) having a top ( 7 ), a bottom ( 9 ), and a sidewall ( 15 ) having an inner surface ( 21 ), the sidewall ( 15 ) connecting the top ( 7 ) and bottom ( 9 ), the reactor vessel ( 2 ) including first ( 11 ) and second ( 13 ) gas inlets for gaseous reactants ammonia and monohalosilane, and a third gas inlet ( 17 ) for an inert gas, wherein at least the first and second gas inlets ( 11 , 13 ) are positioned at or near the top ( 7 ) of the reactor vessel ( 2 ) and configured to inject the ammonia and the monohalosilane in the reactor vessel ( 2 ) substantially vertically and downward from the top ( 7 ) of the reactor vessel ( 2 ); (b) one or more baffles ( 32 ) having a peripheral edge ( 33 ), the one or more baffles ( 32 ) substantially horizontally positioned in the reactor vessel ( 2 ) at a position to define a reaction zone ( 3 ) above the one or more baffles ( 32 ) extending to the top ( 7 ) of the reactor vessel ( 2 ) and a separation zone ( 5 ) below the one or more baffles ( 32 ) extending to the bottom of the reactor vessel ( 2 ); (c) the one or more baffles ( 32 ) positioned in the reactor vessel ( 2 ) such that there is a gap ( 34 ) between the peripheral edge ( 33 ) and the inner surface ( 21 ) of the reactor vessel ( 2 ); and (d) a reaction products collection conduit ( 36 ) having an inlet end ( 38 ) positioned in the separation zone ( 5 ), where the reaction products include trisilylamine. 2. The system of claim 1 wherein the reactor vessel ( 2 ) is cylindrically shaped and has a length (L), a diameter (D), and an L/D ratio, where the L/D ratio ranges from about 0.1 to about 100, or from about 1 to about 10. 3. The system of claim 1 wherein the reaction products collection conduit ( 36 ) includes a particle filter. 4. The system of claim 1 comprising a heating and/or cooling sub-system (H/C) thermally connected at least with the reaction zone ( 3 ) for temperature control. 5. The system of claim 4 wherein the heating and/or cooling sub-system (H/C) is configured to maintain the reaction zone ( 3 ) at a temperature ranging from about −20° C. to about 180° C., or from about 10° C. to about 150° C., or from about 40° C. to about 150° C. 6. The system of claim 1 further comprising a condensation trap ( 51 ) fluidly connected to the separation zone ( 5 ) at or near the bottom ( 9 ) of the reactor vessel ( 2 ) and configured to be maintained at a temperature ranging from about −10° C. to about −80° C. for removing silylamines from the reaction products. 7. The system of claim 1 further comprising a condensation trap ( 51 ) fluidly connected to the separation zone ( 5 ) at or near the bottom ( 9 ) of the reactor vessel ( 2 ) and configured to be maintained at a temperature ranging from about −20° C. to about −40° C. for removing silylamines from the reaction products. 8. The system of claim 1 wherein the reactor vessel ( 2 ) is configured to operate at pressures ranging from about 0.01 to about 15 bar (about 1 to about 1500 kPa), or from about 0.1 to 10 bar (about 10 to about 1000 kPa), or from about 0.2 to about 5 bar (about 20 to about 500 kPa). 9. The system of claim 1 wherein the reactor vessel ( 2 ) is configured to operate at temperature and pressure conditions such that the ammonia, the monohalosilane, and the reaction products are all in gas phase. 10. The system of claim 1 wherein the one or more baffles ( 32 ) are selected from the group consisting of flat plate baffles ( 32 , 32 C), corrugated plate baffles ( 32 A), and cone-shaped baffles ( 32 B), and the one or more baffles ( 32 , 32 A, 32 B, and 32 C) are supported by brackets selected from the group consisting of two or more hanger support brackets ( 28 , 30 ) connected at or near the top ( 7 ) of the reactor vessel ( 2 ) and two or more local support brackets ( 92 ) connected to the inner surface ( 21 ) of sidewall ( 15 ). 11. The system of claim 1 further including a disproportionation unit ( 101 ) comprising a distillation column ( 120 ), a disproportionation reactor ( 126 ), a condenser ( 132 ), and an accumulator ( 136 ), the distillation column ( 120 ) fluidly connected to a condensation trap ( 51 ) by a feed conduit ( 122 ), the condensation trap ( 51 ) fluidly connected to the separation zone ( 5 ) at or near the bottom ( 9 ) of the reactor vessel ( 2 ), the distillation unit ( 120 ) fluidly connected to the disproportionation reactor ( 126 ) by a conduit ( 124 ), and a TSA rich stream conduit ( 142 ) for routing the TSA rich stream to mix with TSA in product conduit ( 36 ), the disproportionation unit ( 126 ) having a disproportionation product conduit ( 128 ) and a conduit ( 130 ) for routing ammonia and volatiles to the condenser ( 132 ), the condenser ( 132 ) having a conduit ( 134 ) for routing DSA liquid to the accumulator ( 136 ), and the accumulator ( 136 ) having a recycle conduit ( 140 ) and recycle pump ( 138 ) for routing DSA liquid from the accumulator ( 136 ) to the disproportionation reactor ( 126 ). 12. A system for gas-phase synthesis of trisilylamine comprising: (a) a reactor vessel ( 2 ) having a top ( 7 ), a bottom ( 9 ), and a sidewall ( 15 ) having an inner surface ( 21 ), the sidewall ( 15 ) connecting the top ( 7 ) and bottom ( 9 ), the reactor vessel ( 2 ) including first ( 11 ) and second ( 13 ) gas inlets for gaseous reactants ammonia and monohalosilane, and a third gas inlet ( 17 ) for an inert gas, wherein at least the first and second gas inlets ( 11 , 13 ) are positioned at or near the top ( 7 ) of the reactor vessel ( 2 ) and configured to inject the ammonia and the monohalosilane in the reactor vessel ( 2 ) substantially vertically and downward from the top ( 7 ) of the reactor vessel ( 2 ); (b) one or more baffles ( 32 ) having a peripheral edge ( 33 ), the one or more baffles ( 32 ) substantially horizontally positioned in the reactor vessel ( 2 ) at a position to define a reaction zone ( 3 ) above the one or more baffles ( 32 ) extending to the top ( 7 ) of the reactor vessel ( 2 ) and a separation zone ( 5 ) below the one or more baffles ( 32 ) extending to the bottom of the reactor vessel ( 2 ); (c) the one or more baffles ( 32 ) positioned in the reactor vessel ( 2 ) such that there is a gap ( 34 ) between the peripheral edge ( 33 ) and the inner surface ( 21 ) of the reactor vessel ( 2 ); (d) one or more turbulence inducing mixing structures ( 60 , 70 ) positioned in the reaction zone ( 3 ); and (e) a reaction products collection conduit ( 36 ) having an inlet end ( 38 ) positioned in the separation zone ( 5 ), where the reaction products include trisilylamine. 13. The system of claim 12 wherein the one or more turbulence inducing mixing structure ( 60 , 70 ) are selected from the group consisting of one or more mechanical stirrers ( 60 ) and one or more static mixers ( 70 ). 14. The system of claim 13 wherein the one or more mechanical stirrers ( 60 ) are selected from the group consisting of motor-driven impellers and magnetic stirrers. 15. The system of claim 13 wherein the one or more static mixers ( 70 ) are selected from the group consisting of porous ceramic materials, porous steel mesh materials, and like materials, and the one or more static mixers ( 70 ) are supported by brackets selected from the group consisting of two or more hanger support brackets ( 28 , 30 ) connected at or near the top ( 7 ) of the reactor vessel ( 2 ) and two or more local support brackets ( 92 ) connected to the inner surface ( 21 ) of sidewall ( 15 ). 16. The system of claim 12