최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
DataON 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Edison 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0801390 (2001-03-07) |
발명자 / 주소 |
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출원인 / 주소 |
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인용정보 | 피인용 횟수 : 8 인용 특허 : 47 |
Parallel flow reaction systems comprising four or more reaction channels are disclosed. Distribution systems, and parallel flow reaction systems comprising such distribution systems are also disclosed. Specifically, the distribution systems comprise one or more subsystems, including for example, a
Parallel flow reaction systems comprising four or more reaction channels are disclosed. Distribution systems, and parallel flow reaction systems comprising such distribution systems are also disclosed. Specifically, the distribution systems comprise one or more subsystems, including for example, a flow-partitioning subsystem for providing a different flow rate to each of the four or more reactors, a pressure-partitioning subsystem for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, and a feed-composition subsystem for providing a different feed composition to each of the four or more reactors. In preferred embodiments, the one or more subsystems can comprise at least one set of four or more flow restrictors, each of the four or more flow restrictors having a flow resistance that varies relative to other flow restrictors in the set.
We claim: 1. A parallel flow reaction system for effecting four or more simultaneous reactions in four or more reaction channels, the reaction system comprising four or more reactors, each of the four or more reactors comprising a surface defining a reaction cavity for carrying out a chemical react
We claim: 1. A parallel flow reaction system for effecting four or more simultaneous reactions in four or more reaction channels, the reaction system comprising four or more reactors, each of the four or more reactors comprising a surface defining a reaction cavity for carrying out a chemical reaction, an inlet part in fluid communication with the reaction cavity, and an outlet port in fluid communication with the reaction cavity, a fluid distribution system for simultaneously supplying one or more reactants from one or more reactant sources to the inlet port of the reaction cavity for each of the four or more reactors, and for discharging a reactor effluent from the outlet port of each such reaction cavity to one or more effluent sinks, the fluid distribution system comprising one or more subsystems selected from the group consisting of (a) a flow-partitioning subsystem for providing a different flow rate to each of the four or more reactors, the flow-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, wherein each reactor of the four or more reactors is in fluid communication with at least one different passive flow restrictor from the set of four or more passive inlet or outlet flow restrictors than the other reactors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set, (b) a pressure-partitioning subsystem for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, the pressure-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, wherein each reactor of the four or more reactors is in fluid communication with at least one different passive flow restrictor from the set of four or more passive inlet or outlet flow restrictors than the other reactors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set, and (c) a feed-composition subsystem for providing a different feed composition to each of the four or more reactors, the feed-composition subsystem comprising four or more mixing zones, each mixing zone in fluid communication with an inlet port of a different reactor of the four or more reactors and at least two sets of four or more passive flow restrictors, a first of the two sets of passive flow restrictors in fluid communication with a first reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the first reactant source through at least one passive flow restrictor of the first set of flow restrictors, a second of the two sets of passive flow restrictors in fluid communication with a second reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the second reactant source through at least one passive flow restrictor of the second set of flow restrictors, each of the four or more flow restrictors in a set providing a resistance to flow between the or more reactant sources and one of the four or more mixing zones, each of the four or more flow restrictors in a set having a flow resistance that varies relative to other flow restrictors in the set. 2. The reaction system of claim 1 comprising the flow-partitioning subsystem and the pressure-partitioning subsystem. 3. The reaction system of claim 2 wherein the flow-partitioning subsystem and the pressure-partitioning subsystem are integrated and the flow restrictors are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance, Rinlet, that varies relative to other inlet flow restrictors in the set, the fluid distribution system further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance, Routlet, that varies relative to other outlet flow restrictors in the set, the total resistance of the inlet and outlet flow restrictors for each channel, Rtotal=Rinlet+Routlet, varying between each of the four or more channels of the reaction system to provide different flow rates through each of the four or more reactors, and the ratio of the resistances of the inlet and outlet flow restrictors for each channel, Rinlet: Routlet, varying between each of the four or more channels of the reaction system to provide a different pressure in the reaction cavities of each of the four or more reactors. 4. The reaction system of claim 3 wherein the flow restrictors are microfluidic channels. 5. The reaction system of claim 3 wherein the flow restrictors are capillaries. 6. The reaction system of claim 3 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a common factor, and the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a common factor. 7. The reaction system of claim 1 comprising the flow-partitioning subsystem and the feed-composition subsystem. 8. The reaction system of claim 1 comprising the flow-partitioning subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 9. The reaction system of claim 1 comprising the flow-partitioning subsystem, the pressure-partitioning subsystem and the feed-composition subsystem. 10. The reaction system of claim 1 comprising the flow-partitioning subsystem, the pressure-partitioning subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 11. The reaction system of claim 1 comprising the flow-partitioning subsystem, the feed-composition subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 12. The reaction system of claim 1 comprising the flow-partitioning subsystem, the pressure-partitioning subsystem, the feed-composition subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 13. The reaction system of claim 1 comprising the pressure-partitioning subsystem and the feed-composition subsystem. 14. The reaction system of claim 1 comprising the pressure-partitioning subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 15. The reaction system of claim 1 comprising the pressure-partitioning subsystem, the feed-composition subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 16. The reaction system of claim 1 comprising the feed-composition subsystem. 17. The reaction system of claim 1 comprising the feed-composition subsystem and a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 18. The reaction system of claim 1 wherein the reaction cavity of each of the four or more reactors has a volume of not more than about 10 ml. 19. The reaction system of claim 1 wherein the reactors and fluid distribution system are adapted to effect a chemical reaction of interest at a temperature of not less than about 100째 C. and additionally, or alternatively, at a pressure of not less than about 10 bar. 20. A parallel flow reaction system for effecting four or more simultaneous reactions in four or more reaction channels, the reaction system comprising four or more reactors, each of the four or more reactors comprising a surface defining a reaction cavity having a volume of not more than about 100 ml for carrying out a chemical reaction, an inlet port in fluid communication with the reaction cavity, and an outlet port in fluid communication with the reaction cavity, and a fluid distribution system for simultaneously supplying one or more reactants from one or more reactant sources to the inlet port of the reaction cavity for each of the four or more reactors, and for discharging a reactor effluent from the outlet port of each such reaction cavity to one or more effluent sinks, the fluid distribution system comprising one or more subsystems selected from the group consisting of (a) a flow-partitioning subsystem having operational capability for providing a different flow rate to each of the four or more reactors, the flow-partitioning subsystem comprising at least one set of four or more flow restrictors integral with a substrate or with one or more microchip bodies mounted on a substrate, wherein each reactor of the four or more reactors is in fluid communication with at least one different flow restrictor from the set of four or more flow restrictors than the other reactors. (b) a pressure-partitioning subsystem having operational capability for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, the pressure-partitioning subsystem comprising at least one set of four or more flow restrictors integral with a substrate or with one or more microchip bodies mounted on a substrate, wherein each reactor of the four or more reactors is in fluid communication with at least one different flow restrictor from the set of four or more flow restrictors than the other reactors, and (c) a feed-composition subsystem for having operational capability providing a different feed composition to each of the four or more reactors, the feed-composition subsystem comprising four or more mixing zones, each mixing zone in fluid communication with an inlet port of a different reactor of the four or more reactors and at least two sets of four or more flow restrictors, a first of the two sets of flow restrictors in fluid communication with a first reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the first reactant source through at least one flow restrictor of the first set of flow restrictors, a second of the two sets of flow restrictors in fluid communication with a second reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the second reactant source through at least one flow restrictor of the second set of flow restrictors, each of the four or more flow restrictors in a set providing a resistance to flow between the or more reactant sources and one of the four or more mixing zones, the four or more flow restrictors being integral with a substrate or with one or more microchip bodies mounted on a substrate. 21. The reaction system of claim 1 or 20 further comprising a temperature-control subsystem having operational capability for providing a different reaction temperature in the reaction cavity of each of the four or more reactors. 22. The reaction systems of claims 1 or 20 wherein when the fluid distribution system comprises a flow-partitioning subsystem or a pressure-partitioning subsystem, the flow restrictors are four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set, and when the fluid distribution system comprises a feed-composition subsystem, the fluid distribution system further comprises a set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set. 23. The reaction systems of claims 1 or 20 wherein when the fluid distribution system comprises a flow-partitioning subsystem or a pressure-partitioning subsystem, the flow restrictors are four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set and when the fluid distribution system comprises a feed-composition subsystem, the fluid distribution system further comprises a set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 24. The reaction systems of claims 1 or 20 wherein when the fluid distribution system comprises a flow-partitioning subsystem or a pressure-partitioning subsystem, the flow restrictors are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set, and when the fluid distribution system comprises a feed-composition subsystem, the fluid distribution system further comprises a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flaw restrictors in the set, the fluid distribution further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 25. The reaction system of claims 1 or 20 further comprising a detection system in fluid communication with the outlet ports of the four or more reactors for detecting at least one reaction product or unreacted reactant from the effluent discharged from each of the four or more reactors. 26. The reaction system of claims 1 or 20 further comprising a parallel detection system in fluid communication with the outlet ports of the four or more reactors for simultaneously detecting at least one reaction product or unreacted reactant from the effluent discharged from each of the four or more reactors. 27. The reaction system of claims 1 or 20 further comprising a parallel gas chromatograph in fluid communication with the outlet ports of the four or more reactors for simultaneously detecting at least one reaction product or unreacted reactant from the effluent discharged from each of the four or more reactors. 28. A parallel flow reaction system for effecting four or more simultaneous reactions in four or more reaction channels, the reaction system comprising four or more reactors, each of the four or more reactors comprising a surface defining a reaction cavity for carrying out a chemical reaction, an inlet port in fluid communication with the reaction cavity, and an outlet port in fluid communication with the reaction cavity, and a fluid distribution system for simultaneously supplying one or more reactants from one or more reactant sources to the inlet port of the reaction cavity for each of the four or more reactors, and for discharging a reactor effluent from the outlet port of each such reaction cavity to one or more effluent sinks, the fluid distribution system comprising a flow-partitioning subsystem for providing a different flow rate to each of the four or more reactors, the flow-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set wherein each reactor of the four or more reactors is in fluid communication with at least one different flow restrictor from the set of four or more flow restrictors than the other reactor. 29. The reaction system of claim 28 wherein the flow restrictors of the flow-partitioning subsystem are a set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set. 30. The reaction system of claim 29 wherein the set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 31. The reaction system of claim 29 wherein the flow restrictors are microfluidic channels. 32. The reaction system of claim 29 wherein the flow restrictors are capillaries. 33. The reaction system of claim 29 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a common factor. 34. The reaction system of claim 29 wherein the flow-partitioning subsystem comprises a first plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a first reactor of the four or more reactors, a second plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a second reactor of the four or more reactors, a third plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a third reactor of the four or more reactors, a fourth plurality of selectable dedicated inlet flow restrictors having different flaw resistances, and providing selectable fluid communication between the at least one reactant source and a fourth reactor of the four or more reactors, and a means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors. 35. The reaction system of claim 34 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 36. The reaction system of claim 34 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 37. The reaction system of claim 34 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 38. The reaction system of claim 34 wherein the selection means comprises four or more inlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors. 39. The reaction system of claim 34 wherein the selection means comprises a first plurality of inlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated inlet flow restrictors, a second plurality of inlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated inlet flow restrictors, a third plurality of inlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated inlet flow restrictors, and a fourth plurality of inlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated inlet flow restrictors. 40. The reaction system of claim 39 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves of the inlet isolation valve array are integral with a substrate or with one or more microchip bodies mounted on the substrate. 41. The reaction system of claim 39 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on the substrate. 42. The reaction system of claim 39 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 43. The reaction system of claim 29 wherein the flow-partitioning subsystem comprises a series of selectable sets of inlet flow restrictors, the inlet-set series comprising a first set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between at least one reactant source and first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the first set having a different flow resistance relative to each other, a second set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between the least one reactant source and the first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more inlet flow restrictors of the second set varying from the flow resistance of the corresponding inlet flow restrictor of the first set, and a means for selecting the first set or the second set of inlet flow restrictors to provide fluid communication between the at least one reactant source and the four or more reactors. 44. The reaction system of claim 43 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 45. The reaction system of claim 43 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 46. The reaction system of claim 43 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 47. The reaction system of claim 43 wherein the selection means comprises an inlet selection valve for selecting at least one the first set of inlet flow restrictors or the second set of inlet flow restrictors. 48. The reaction system of claim 43 wherein the selection means comprises a series of inlet isolation valves, the inlet-isolation-valve series comprising a first inlet isolation valve for selecting the first set of inlet flow restrictors, and a second inlet isolation valve for selecting the second set of inlet flow restrictors. 49. The reaction system of claim 48 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 50. The reaction system of claim 48 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 51. The reaction system of claim 48 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set array are integral with a substrate or with one or more microchip bodies mounted on a substrate. 52. The reaction system of claim 28 wherein the flow restrictors of the flow-partitioning subsystem are a set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 53. The reaction system of claim 52 wherein the set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 54. The reaction system of claim 52 wherein the flow restrictors are microfluidic channels. 55. The reaction system of claim 52 wherein the flow restrictors are capillaries. 56. The reaction system of claim 52 wherein the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a common factor. 57. The reaction system of claim 52 wherein the flow-partitioning subsystem comprises a first plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a first reactor of the four or more reactors and the at least one effluent sink, a second plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a second reactor of the four or more reactors and the at least one effluent sink, a third plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a third reactor of the four or more reactors and the at least one effluent sink, a fourth plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a fourth reactor of the four or more reactors and the at least one effluent sink, and a means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 58. The reaction system of claim 57 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 59. The reaction system of claim 57 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 60. The reaction system of claim 57 wherein the first plurality, the second plurality the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies detachably mounted on the substrate. 61. The reaction system of claim 57 wherein the selection means comprises four or more outlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 62. The reaction system of claim 57 wherein the selection means comprises a first plurality of outlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated outlet flow restrictors, a second plurality of outlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated outlet flow restrictors, a third plurality of outlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated outlet flow restrictors, and a fourth plurality of outlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated outlet flow restrictors. 63. The reaction system of claim 62 wherein the first plurality of outlet isolation valves the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate. 64. The reaction system of claim 62 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 65. The reaction system of claim 62 wherein the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on the substrate. 66. The reaction system of claim 52 wherein the flow-partitioning subsystem comprises a series of selectable sets of outlet flow restrictors, the outlet-set series comprising a first set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between first, second, third and fourth reactors, respectively, and at least one effluent sink, each of the first second, third and fourth outlet flow restrictors of the first set having a different flow resistance relative to each other, a second set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between the first, second, third and fourth reactors, respectively, an the at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more outlet flow restrictors of the second set varying from the flow resistance of the corresponding outlet flow restrictor of the first set, and a means for selecting the first set or the second set of outlet flow restrictors to provide fluid communication between the four or more reactors and the at least one effluent sink. 67. The reaction system of claim 66 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 68. The reaction system of claim 66 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 69. The reaction system of claim 66 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 70. The reaction system of claim 66 wherein the selection means comprises an outlet selection valve for selecting at least one the first set of outlet flow restrictors or the second set of outlet flow restrictors. 71. The reaction system of claim 66 wherein the selection means comprises a series of outlet isolation valves, the outlet-isolation valve series comprising a first outlet isolation valve for selecting the first set of outlet flow restrictors, and a second outlet isolation valve for selecting the second set of outlet flow restrictors. 72. The reaction system of claim 71 wherein the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 73. The reaction system of claim 71 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 74. The reaction system of claim 71 wherein the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with a substrate or with one or microchip bodies mounted on a substrate. 75. The reaction system of claim 28 wherein the flow restrictors of the flow-partitioning subsystem are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set, the flow-partitioning subsystem further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 76. The reaction system of claim 75 wherein the set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 77. The reaction system of claim 75 wherein the flow restrictors are microfluidic channels. 78. The reaction system of claim 75 wherein the flow restrictors are capillaries. 79. The reaction system of claim 75 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a factor of two, and the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a factor of two. 80. The reaction system of claim 75 wherein the flow-partitioning subsystem comprises a first plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a first reactor of the four or more reactors, a second plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a second reactor of the four or more reactors, a third plurality of selectable dedicated inlet flow restrictors baying different flow resistances, and providing selectable fluid communication between the at least one reactant source and a third reactor of the four or more reactors, a fourth plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a fourth reactor of the four or more reactors, and a first means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors. a first plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the first reactor and the at least one effluent sink, a second plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the second reactor and the at least one effluent sink, a third plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the third reactor and the at least one effluent sink, a fourth plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the fourth reactor and the at least one effluent sink, and a second means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 81. The reaction system of claim 80 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on the substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 82. The reaction system of claim 80 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 83. The reaction system of claim 80 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies detachably mounted on the substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies detachably mounted on the substrate. 84. The reaction system of claim 80 wherein the first selection means comprises four or more inlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors, and the second selection means comprises four or more outlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 85. The reaction system of claim 80 wherein the first selection means comprises a first plurality of inlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated inlet flow restrictors, a second plurality of inlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated inlet flow restrictors, a thirds plurality of inlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated inlet flow restrictors, a fourth plurality of inlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated inlet flow restrictors, and the second selection means comprises a first plurality of outlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated outlet flow restrictors, a second plurality of outlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated outlet flow restrictors, a third plurality of outlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated outlet flow restrictors, and a fourth plurality of outlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated outlet flow restrictors. 86. The reaction system of claim 85 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate. 87. The reaction system of claim 85 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 88. The reaction system of claim 85 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 89. The reaction system of claim 75 wherein the flow-partitioning subsystem comprises a series of selectable sets of inlet flow restrictors, the inlet-set series comprising (a) a first set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between at least one reactant source and first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the first set having a different flow resistance relative to each other, (b) a second set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between the least one reactant source and the first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more inlet flow restrictors of the second set varying from the flow resistance of the corresponding inlet flow restrictor of the first set, and (c) a first means for selecting the first set or the second set of inlet flow restrictors to provide fluid communication between the at least one reactant source and the four or more reactors, and a series of selectable sets of outlet flow restrictors, the outlet-set series comprising (a) a first set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between first, second, third and fourth reactors, respectively, and at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the first set having a different flow resistance relative to each other, and (b) a second set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between the first, second, third and fourth reactors, respectively, an the at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more outlet flow restrictors of the second set varying from the flow resistance of the corresponding outlet flow restrictor of the first set, and (c) a second means for selecting the first set or the second set of outlet flow restrictors to provide fluid communication between the four or more reactors and the at least one effluent sink. 90. The reaction system of claim 89 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 91. The reaction system of claim 89 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 92. The reaction system of claim 89 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 93. The reaction system of claim 89 wherein the first selection means comprises an inlet selection valve for selecting at least one the first set of inlet flow restrictors or the second set of inlet flow restrictors, and the second selection means comprises an outlet selection valve for selecting at least one the first set of outlet flow restrictors or the second set of outlet flow restrictors. 94. The reaction system of claim 89 wherein the first selection means comprises a series of inlet isolation valves, the inlet-valve series comprising a first inlet isolation valve for selecting the first set of inlet flow restrictors, and a second inlet isolation valve for selecting the second set of inlet flow restrictors, and the second selection means comprises a series of outlet isolation valves, the outlet-valve series comprising a first outlet isolation valve for selecting the first set of outlet flow restrictors, and a second outlet isolation valve for selecting the second set of outlet flow restrictors. 95. The reaction system of claim 94 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 96. The reaction system of claim 94 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 97. The reaction system of claim 94 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set any are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 98. The reaction system of claim 28 wherein the flow restrictors of the flow-partitioning subsystem are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance, Rinlet, that varies relative to other inlet flow restrictors in the set, the fluid distribution system further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance, Routlet, that varies relative to other outlet flow restrictors in the set, the total resistance of the inlet and outlet flow restrictors for each channel, Rtotal=Rinlet+Routlet, varying between each of the four or more channels of the reaction system to provide a different flowrate through each of the four or more reactors, and the ratio of the resistances of the inlet and outlet flow restrictors for each channel, Rinlet: Routlet, being substantially the same between each of the four or more channels of the reaction system to provide substantially the same pressure in the reaction cavities of each of the four or more reactors. 99. The reaction system of claim 98 wherein the flow restrictors are microfluidic channels. 100. The reaction system of claim 98 wherein the flow restrictors are capillaries. 101. The reaction system of claim 98 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a common factor, and the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a common factor. 102. A parallel flow reaction system for effecting four or more simultaneous reactions in four or more reaction channels, the reaction system comprising four or more reactors, each of the four or more reactors comprising a surface defining a reaction cavity for carrying out a chemical reaction, an inlet port in fluid communication with the reaction cavity, and an outlet port in fluid communication with the reaction cavity, and a fluid distribution system for simultaneously supplying one or more reactants from one or more reactant sources to the inlet port of the reaction cavity for each of the four or more reactors, and for discharging a reactor effluent from the outlet port of each such reaction cavity to one or more effluent sinks, the fluid distribution system comprising a pressure-partitioning subsystem for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, the pressure-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, wherein each reactor of the four or more reactors is in fluid communication with at least one different passive flow restrictor from the set of four or more passive inlet or outlet flow restrictors than the other reactors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set. 103. The reaction system of claim 102 wherein the flow restrictors of the pressure-partitioning subsystem are a set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set. 104. The reaction system of claim 103 wherein the set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 105. The reaction system of claim 103 wherein the flow restrictors are microfluidic channels. 106. The reaction system of claim 103 wherein the flow restrictors are capillaries. 107. The reaction system of claim 103 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a common factor. 108. The reaction system of claim 103 wherein the pressure-partitioning subsystem comprises a first plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a first reactor of the four or more reactors, a second plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a second reactor of the four or more reactors, a third plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a third reactor of the four or more reactors, a fourth plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a fourth reactor of the four or more reactors, and a means for selecting at least one flow restrictor from each of the first plurality, the second plurality. the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors. 109. The reaction system of claim 108 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 110. The reaction system of claim 108 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 111. The reaction system of claim 108 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or the microchip bodies detachably mounted on a substrate. 112. The reaction system of claim 108 wherein the selection means comprises four or more inlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors. 113. The reaction system of claim 108 wherein the selection means comprises a first plurality of inlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated inlet flow restrictors, a second plurality of inlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated inlet flow restrictors, a third plurality of inlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated inlet flow restrictors, and a fourth plurality of inlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated inlet flow restrictors. 114. The reaction system of claim 113 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate. 115. The reaction system of claim 113 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 116. The reaction system of claim 113 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 117. The reaction system of claim 103 wherein the pressure-partitioning subsystem comprises a series of selectable sets of inlet flow restrictors, the series comprising a first set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between at least one reactant source and first second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the first set having a different flow resistance relative to each other, a second set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between the least one reactant source and the first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more inlet flow restrictors of the second set varying from the flow resistance of the corresponding inlet flow restrictor of the first set, and a means for selecting the first set or the second set of inlet flow restrictors to provide fluid communication between the at least one reactant source and the four or more reactors. 118. The reaction system of claim 117 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 119. The reaction system of claim 117 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 120. The reaction system of claim 117 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 121. The reaction system of claim 117 wherein the selection means comprises an inlet selection valve for selecting at least one the first set of inlet flow restrictors or the second set of inlet flow restrictors. 122. The reaction system of claim 117 wherein the selection means comprises a series of inlet isolation valves, the inlet-isolation valve series comprising a first inlet isolation valve for selecting the first set of inlet flow restrictors, and a second inlet isolation valve for selecting the second set of inlet flow restrictors. 123. The reaction system of claim 122 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 124. The reaction system of claim 122 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 125. The reaction system of claim 122 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set array are integral with a substrate or with one or more microchip bodies mounted on a substrate. 126. The reaction system of claim 102 wherein the flow restrictors of the pressure-partitioning subsystem are a set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 127. The reaction system of claim 126 wherein the set of four or more outlet flow resistors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 128. The reaction system of claim 126 wherein the flow restrictors are microfluidic channels. 129. The reaction system of claim 126 wherein the flow restrictors are capillaries. 130. The reaction system of claim 126 wherein the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a common factor. 131. The reaction system of claim 126 wherein the pressure-partitioning subsystem comprises a first plurality of selectable dedicated outlet flow restrictors having different flow resistances, end providing selectable fluid communication between a first reactor of the four or more reactors and the at least one effluent sink, a second plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a second reactor of the four or more reactors and the at least one effluent sink, a third plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a third reactor of the four or more reactors and the at least one effluent sink, a fourth plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between a fourth reactor of the four or more reactors and the at least one effluent sink, and a means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 132. The reaction system of claim 131 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 133. The reaction system of claim 131 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 134. The reaction system of claim 131 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 135. The reaction system of claim 131 wherein the selection means comprises four or more outlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 136. The reaction system of claim 131 wherein the selection means comprises a first plurality of outlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated outlet flow restrictors, a second plurality of outlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated outlet flow restrictors, a third plurality of outlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated outlet flow restrictors, and a fourth plurality of outlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated outlet flow restrictors. 137. The reaction system of claim 136 wherein the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate. 138. The reaction system of claim 136 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 139. The reaction system of claim 136 wherein the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 140. The reaction system of claim 126 wherein the pressure-partitioning subsystem comprises a series of selectable sets of outlet flow restrictors, the series comprising a first set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between first, second, third and fourth reactors, respectively, and at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the first set having a different flow resistance relative to each other, a second set of four or more outlet flow restrictors comprising first second, third and fourth outlet flow restrictors providing fluid communication between the first, second, third and fourth reactors, respectively, an the at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more outlet flow restrictors of the second set varying from the flow resistance of the corresponding outlet flow restrictor of the first set, and a means for selecting the first set or the second set of outlet flow restrictors to provide fluid communication between the four or more reactors and the at least one effluent sink. 141. The reaction system of claim 140 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 142. The reaction system of claim 140 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 143. The reaction system of claim 140 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate. 144. The reaction system of claim 140 wherein the selection means comprises an outlet selection valve for selecting at least one the first set of outlet flow restrictors or the second set of outlet flow restrictors. 145. The reaction system of claim 140 wherein the selection means comprises a series of outlet isolation valves, the outlet-valve series comprising a first outlet isolation valve for selecting the first set of outlet flow restrictors, and a second outlet isolation valve for selecting the second set of outlet flow restrictors. 146. The reaction system of claim 145 wherein the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 147. The reaction system of claim 145 wherein the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 148. The reaction system of claim 145 wherein the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 149. The reaction system of claim 102 wherein the flow restrictors of the pressure-partitioning subsystem are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance that varies relative to other inlet flow restrictors in the set, the pressure-partitioning system further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance that varies relative to other outlet flow restrictors in the set. 150. The reaction system of claim 149 wherein the set of four or more inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 151. The reaction system of claim 149 wherein the flow restrictors are microfluidic channels. 152. The reaction system of claim 149 wherein the flow restrictors are capillaries. 153. The reaction system of claim 149 wherein the flow resistance of each of the four or more inlet flow restrictors varies relative to other inlet flow restrictors in the set by a factor of two, and the flow resistance of each of the four or more outlet flow restrictors varies relative to other outlet flow restrictors in the set by a factor of two. 154. The reaction system of claim 149 wherein the pressure-partitioning subsystem comprises a first plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a first reactor of the four or more reactors, a second plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a second reactor of the four or more reactors, a third plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a third reactor of the four or more reactors, a fourth plurality of selectable dedicated inlet flow restrictors having different flow resistances, and providing selectable fluid communication between the at least one reactant source and a fourth reactor of the four or more reactors, and a first means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors and further comprises, a first plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the first reactor and the at least one effluent sink, a second plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the second reactor and the at least one effluent sink, a third plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the third reactor and the at least one effluent sink, a fourth plurality of selectable dedicated outlet flow restrictors having different flow resistances, and providing selectable fluid communication between the fourth reactor and the at least one effluent sink, a second means for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 155. The reaction system of claim 154 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 156. The reaction system of claim 154 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 157. The reaction system of claim 154 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with one or more microchip bodies detachably mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with one or more mircochip bodies detachably mounted on a substrate. 158. The reaction system of claim 154 wherein the first selection means comprises four or more inlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors to form the set of four or more inlet flow restrictors, and the second selection means comprises four or more outlet selection valves for selecting at least one flow restrictor from each of the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors to form the set of four or more outlet flow restrictors. 159. The reaction system of claim 154 wherein the first selection means comprises a first plurality of inlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated inlet flow restrictors, a second plurality of inlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated inlet flow restrictors, a thirds plurality of inlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated inlet flow restrictors, a fourth plurality of inlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated inlet flow restrictors, and the second selection means comprises a first plurality of outlet isolation valves for selecting at least one flow restrictor from the first plurality of selectable dedicated outlet flow restrictors, a second plurality of outlet isolation valves for selecting at least one flow restrictor from the second plurality of selectable dedicated outlet flow restrictors, a third plurality of outlet isolation valves for selecting at least one flow restrictor from the third plurality of selectable dedicated outlet flow restrictors, and a fourth plurality of outlet isolation valves for selecting at least one flow restrictor from the fourth plurality of selectable dedicated outlet flow restrictors. 160. The reaction system of claim 159 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate. 161. The reaction system of claim 159 wherein the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 162. The reaction system of claim 159 wherein the first plurality of inlet isolation valves, the second plurality of inlet isolation valves, the third plurality of inlet isolation valves and the fourth plurality of inlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first plurality of outlet isolation valves, the second plurality of outlet isolation valves, the third plurality of outlet isolation valves and the fourth plurality of outlet isolation valves are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated inlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first plurality, the second plurality, the third plurality and the fourth plurality of selectable dedicated outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 163. The reaction system of claim 149 wherein the pressure-partitioning subsystem comprises a series of selectable sets of inlet flow restrictors, the series comprising (a) a first set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between at least one reactant source and first second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the first set having a different flow resistance relative to each other, (b) a second set of four or more inlet flow restrictors comprising first, second, third and fourth inlet flow restrictors providing fluid communication between the least one reactant source and the first, second, third and fourth reactors, respectively, each of the first, second, third and fourth inlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more inlet flow restrictors of the second set varying from the flow resistance of the corresponding inlet flow restrictor of the first set, and (c) a first means for selecting the first set or the second set of inlet flow restrictors to provide fluid communication between the at least one reactant source and the four or more reactors, and a series of selectable sets of outlet flow restrictors, the series comprising (a) a first set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between first, second, third and fourth reactors, respectively, and at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the first set having a different flow resistance relative to each other, (b) a second set of four or more outlet flow restrictors comprising first, second, third and fourth outlet flow restrictors providing fluid communication between the first, second, third and fourth reactors, respectively, an the at least one effluent sink, each of the first, second, third and fourth outlet flow restrictors of the second set having a different flow resistance relative to each other, the flow resistance of at least one of the four or more outlet flow restrictors of the second set varying from the flow resistance of the corresponding outlet flow restrictor of the first set, and (c) a second means for selecting the first set or the second set of outlet flow restrictors to provide fluid communication between the four or more reactors and the at least one effluent sink. 164. The reaction system of claim 163 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flaw restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 165. The reaction system of claim 163 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies mounted on a substrate. 166. The reaction system of claim 163 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors are integral with one or more microchip bodies detachably mounted on the substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors are integral with one or more microchip bodies detachably mounted on the substrate. 167. The reaction system of claim 163 wherein the first selection means comprises an inlet selection valve for selecting at least one the first set of inlet flow restrictors or the second set of inlet flow restrictors, and the second selection means comprises an outlet selection valve for selecting at least one the first set of outlet flow restrictors or the second set of outlet flow restrictors. 168. The reaction system of claim 163 wherein the first selection means comprises a series of inlet isolation valves, the inlet-valve series comprising a first inlet isolation valve for selecting the first set of inlet flow restrictors, and a second inlet isolation valve for selecting the second set of inlet flow restrictors, and the second selection means comprises a series of outlet isolation valves, the outlet-valve series comprising a first outlet isolation valve for selecting the first set of outlet flow restrictors, and a second outlet isolation valve for selecting the second set of outlet flow restrictors. 169. The reaction system of claim 168 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 170. The reaction system of claim 168 wherein the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 171. The reaction system of claim 168 wherein the first inlet isolation valve and the second inlet isolation valve of the inlet-isolation valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first outlet isolation valve and the second outlet isolation valve of the outlet-isolation-valve series are integral with a substrate or with one or more microchip bodies mounted on a substrate, the first set of four or more inlet flow restrictors and the second set of four or more inlet flow restrictors of the inlet-set array are integral with a substrate or with one or more microchip bodies mounted on a substrate, and the first set of four or more outlet flow restrictors and the second set of four or more outlet flow restrictors of the outlet-set series are integral with a substrate or with one or more microchip bodies mounted on a substrate. 172. The reaction system of claim 102 wherein the flow restrictors of the pressure partitioning subsystem are a first set of four or more inlet flow restrictors, each of the four or more inlet flow restrictors providing fluid communication between at least one reactant source and one of the four or more reactors, each of the four or more inlet flow restrictors having a flow resistance, Rinlet, that varies relative to other inlet flow restrictors in the set, the pressure-partitioning system further comprising a second set of four or more outlet flow restrictors, each of the four or more outlet flow restrictors providing fluid communication between one of the four or more reactors and at least one effluent sink, each of the four or more outlet flow restrictors having a flow resistance, Routlet, that varies relative to other outlet flow restrictors in the set, the total resistance of the inlet and outlet flow restrictors for each channel, Rtotal=Rinlet+Routlet, being substantially the same between each of the four or more channels of the reaction system to provide substantially the same flow rates through each of the four or more reactors, and the ratio of the resistances of the inlet and outlet flow restrictors for each channel, Rinlet: R outlet, varying between each of the four or more channels of the reaction system to provide a different pressure in the reaction cavities of each of the four or more reactors. 173. The reaction system of claim 172 wherein the flow restrictors are microfluidic channels. 174. The reaction system of claim 172 wherein the flow restrictors are capillaries. 175. A method for evaluating a chemical reaction process, the method comprising simultaneously supplying one or more reactants to each of four or more reactors under reaction conditions to effect a chemical reaction of interest, the one or more reactants being supplied through a fluid distribution system, controllably varying a first set of reaction conditions between the four or more reactors, the first set of reaction conditions being selected from flow rate, pressure and feed composition, and discharging a reactor effluent from each of the four or more reactors, the fluid distribution system comprising one or more subsystems selected from the group consisting of a flow-partitioning subsystem for providing a different flow rate to each of the four or more reactors, the flow-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, wherein each reactor of the four or more reactors is in fluid communication with at least one different passive flow restrictor from the set of four or more passive inlet or outlet flow restrictors than the other reactors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set, a pressure-partitioning subsystem for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, the pressure-partitioning subsystem comprising at least one set of four or more passive inlet or outlet flow restrictors, wherein each reactor of the four or more reactors is in fluid communication with at least one different passive flow restrictor from the set of four or more passive inlet or outlet flow restrictors than the other reactors, each of the four or more inlet or outlet flow restrictors having a flow resistance that varies relative to other flow restrictors in the set, and a feed-composition subsystem for providing a different feed composition to each of the four or more reactors, the feed-composition subsystem comprising four or more mixing zones, each mixing zone in fluid communication with an inlet port of a different reactor of the four or more reactors and at least two sets of four or more passive flow restrictors, a first of the two sets of passive flow restrictors in fluid communication with a first reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the first reactant source through at least one passive flow restrictor of the first set of flow restrictors, a second of the two sets of passive flow restrictors in fluid communication with a second reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the second reactant source through at least one passive flow restrictor of the second set of flow restrictors, each of the four or more flow restrictors in a set providing a resistance to flow between the or more reactant sources and one of the four or more mixing zones, each of the four or more flow restrictors in a set having a flow resistance that varies relative to other flow restrictors in the set. 176. A method for evaluating a chemical reaction process, the method comprising simultaneously supplying one or more reactants through a fluid distribution system to each of four or more reactors under reaction conditions to effect a chemical reaction of interest, each of the four or more reactors having a volume of not more than about 10 ml, controllably varying a first set of reaction conditions between the four or more reactors, the first set of reaction conditions being selected from flow rate, pressure and feed composition, and discharging a reactor effluent from each of the four or more reactors through the fluid distribution system, the fluid distribution system comprising one or more subsystems selected from the group consisting of a flow-partitioning subsystem having operational capability for providing a different flow rate to each of the four or more reactors, the flow-partitioning subsystem comprising at least one set of four or more flow restrictors integral with a substrate or with one or more microchip bodies mounted on a substrate, wherein each reactor of the four or more reactors is in fluid communication with at least one different flow restrictor from the set of four or more flow restrictors than the other reactors, a pressure-partitioning subsystem having operational capability for providing a different reaction pressure in the reaction cavity of each of the four or more reactors, the pressure-partitioning subsystem comprising at least one set of four or more flow restrictors integral with a substrate or with one or more microchip bodies mounted on a substrate, wherein each reactor of the four or more reactors is in fluid communication with at least one different flow restrictor from the set of four or more flow restrictors than the other reactors, and a feed-composition subsystem for having operational capability providing a different feed composition to each of the four or more reactors, the feed-composition subsystem comprising four or more mixing zones. each mixing zone in fluid communication with an inlet port of a different reactor of the four or more reactors and at least one two sets of four or more flow restrictors, a first of the two sets of flow restrictors in fluid communication with a first reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the first reactant source through at least one flow restrictor of the first set of flow restrictors, a second of the two sets of flow restrictors in fluid communication with a second reactant source and the four or more mixing zones so that each of the four or more mixing zones is in fluid communication with the second reactant source through at least one flow restrictor of the second set of flow restrictors, each of the four or more flow restrictors in a set providing a resistance to flow between the or more reactant sources and one of the four or more mixing zones, the four or more flow restrictors being integral with a substrate or with one or more microchip bodies mounted on a substrate. 177. The method of claims 175 or 176 further comprising controlling a second set of reaction conditions to be substantially the same in each of the four or more reactors. 178. The method of claims 175 or 176 further comprising analyzing the reactor effluent from each of the four or more reactors to determine the conversion, selectivity or yield of the chemical reaction of interest, and comparing the determined conversion, selectivity or yield for the reactions effected in each of the four or more reactors. 179. The method of claim 178 wherein the reactor effluent from each of the four or more reactors are simultaneously analyzed. 180. The method of claim 178 wherein the reactor effluent from each of the four or more reactors are simultaneously analyzed using gas chromatography or mass spectrometry. 181. The method of claim 178 wherein the reactor effluent from each of the four or more reactors are simultaneously analyzed using gas chromatography. 182. A system comprising four or more cavities, each of the four or more cavities having an inlet providing fluid communication with at least one fluid source, and optionally, where each of the four or more cavities is a flow cavity, an outlet providing fluid communication with at least one effluent sink, and a fluid distribution system comprising one or more subsystems selected from the group consisting of (a) a flow-partitioning subsystem for providing a different flow rate to each of the four or more cavities, (b) a pressure-partitioning subsystem for providing a different pressure in each of the four or more cavities, and (c) a feed-composition subsystem for providing a different feed composition to each of the four or more cavities, the one or more subsystems comprising at least one set of four or more flow restrictors, each of the four or more flow restrictors having a flow resistance that varies relative to other flow restrictors in the set each of the four or more flow restrictors (i) being a capillary or (ii) being integral with a substrate or with one or more microchip bodies mounted on a substrate, wherein in the feed-composition subsystem, the at least one set of flow restrictors is a first set of flow restrictors in fluid communication with a first fluid source and the four or more cavities so that each of the four or more cavities is in fluid communication with the first fluid source through at least one flow restrictor of the first set of flow restrictors, the feed-composition subsystem further comprising a second set of four or more flow restrictors in fluid communication with a second fluid source and the four or more cavities so that each of the four or more cavities is in fluid communication with the second fluid source through at least one flow restrictor of the second set of flow restrictors, each of the second set of four or more flow restrictors (i) being a capillary or (ii) being internal with a substrate or with one or more microchip bodies mounted on a substrate. 183. The system of claim 182 wherein the four or more flow restrictors are integral with a substrate or with one or more microchip bodies mounted on a substrate. 184. The system of claim 182 wherein the four or more flow restrictors are integral with a substrate or with one or more microchip bodies detachably mounted on a substrate. 185. The system of claim 182 wherein the cavity is a flow cavity and comprises the outlet in fluid communication with the at least one effluent sink. 186. The system of claim 182 wherein the cavity has a volume of not more than about 100 ml.
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