Targeted frequency multiple path length mixers

What is claimed is: 1. A method of mixing a solvent composition for a microfluidic separation system, comprising: providing a mixing well; providing a distribution well; receiving an incoming flow of the solvent composition, including an input compositional step having a set volume, a known noise characteristic, constituent frequencies, and a noise profile, into the distribution well; and providing at least three fluidic paths extending from the distribution well to the mixing well, the flow of solvent composition being split at the distribution well into as many streams as fluidic paths, the fluidic paths having different dwell volumes that determine a percentage of the flow of solvent composition carried by each of the fluidic paths, the fluidic paths configured to produce output steps of the streams to produce a mixing profile having designed constituent frequencies to target the constituent frequencies the known noise characteristic in the flow of solvent composition, the output steps of the streams recombining at the mixing well in accordance with percentages of the input compositional step determined by the dwell volumes of the fluidic paths and respectively different predetermined travel times to produce an output compositional stream for the microfluidic separation system having the known noise characteristic attenuated, wherein the designed constituent frequencies of the mixing profile attenuate the constituent frequencies and target the noise profile. 2. The method of claim 1 , wherein the fluidic paths have different lengths. 3. The method of claim 1 , wherein the fluidic paths have different cross-sectional areas. 4. The method of claim 1 , wherein the dwell volume of a given fluidic path is a function of length and cross-sectional area of the given fluidic path. 5. The method of claim 1 , wherein the known noise characteristic is produced by a low-pressure gradient pump system that provides the flow of solvent composition. 6. The method of claim 1 , wherein the known noise characteristic is produced deliberately by a high-pressure gradient pump system that provides the flow of solvent composition. 7. A method of mixing a solvent composition, comprising: providing a pump system pumping a flow of solvent composition with a known noise characteristic; providing a mixer with a mixing well; providing a distribution well; receiving the flow of solvent composition including an input compositional step having a set volume, the known noise characteristic, constituent frequencies, and a noise profile; and providing a plurality of fluidic paths extending from the distribution well to the mixing well, the flow of solvent composition being split at the distribution well into as many streams as fluidic paths, the fluidic paths having different dwell volumes that determine a percentage of the flow of solvent composition carried by each of the fluidic paths, the fluidic paths configured to produce output steps of the streams to produce a mixing profile having designed constituent frequencies to target the constituent frequencies of the known noise characteristic in the flow of solvent composition, the output steps of the streams recombining at the mixing well in accordance with percentages of the input compositional step determined by the dwell volumes of the fluidic paths and respectively different predetermined travel times to produce an output compositional stream for the microfluidic separation system having the known noise characteristic attenuated, wherein the designed constituent frequencies of the mixing profile attenuate the constituent frequencies and target the noise profile. 8. The method of claim 7 , wherein the fluidic paths have different lengths. 9. The method of claim 7 , wherein the fluidic paths have different cross-sectional areas. 10. The method of claim 7 , wherein the dwell volume of a given fluidic path is a function of a length and cross-sectional area of the given fluidic path. 11. The method of claim 7 , wherein the pump system is a low-pressure gradient pump system that produces the known noise characteristic. 12. The method of claim 7 , wherein the pump system is a high-pressure gradient pump system deliberately operated to produce the known noise characteristic. 13. A mixer for a microfluidic separation system, comprising: a mixing well; a distribution well for receiving an incoming flow of solvent composition; and a contoured surface disposed between the distribution and mixing wells, the contoured surface having a plurality of fluidic paths extending from the distribution well to the mixing well, each fluidic path passing through a different valley defined by opposing upwardly sloping banks, the incoming flow of solvent composition splitting at the distribution well into as many streams as fluidic paths, the streams recombining at the mixing well to produce an output compositional stream, wherein neighboring valleys abut at a ridgeline traversable by the solvent composition. 14. The mixer of claim 13 , wherein each valley has a dwell volume that determines a percentage of the flow of solvent composition that passes through that valley. 15. The mixer of claim 14 , wherein the dwell volumes of the valleys are specifically configured to target a known noise characteristic in the flow of solvent composition. 16. The mixer of claim 14 , wherein the streams recombine at the mixing well in accordance with the percentages determined by the dwell volumes of the valleys to produce an output compositional stream with the noise characteristic attenuated. 17. The mixer of claim 14 , wherein the dwell volume of a given valley is a function of length and width of the valley and of a dwell volume of the fluidic path extending through that given valley. 18. The mixer of claim 13 , wherein the fluidic paths have different lengths. 19. The mixer of claim 13 , wherein the fluidic paths have different cross-sectional areas. 20. The mixer of claim 13 , wherein neighboring valleys are fluidically isolated from each other. 21. A microfluidic system, comprising: a pump system pumping a flow of solvent composition; and a mixer with a distribution well for receiving the flow of solvent composition, a mixing well, and a contoured surface disposed between the distribution and mixing wells, the contoured surface having a plurality of fluidic paths extending from the distribution well to the mixing well, each fluidic path passing through a different valley defined by opposing upwardly sloping banks, the flow of solvent composition splitting at the distribution well into as many streams as fluidic paths, the streams recombining at the mixing well to produce an output compositional stream, wherein neighboring valleys abut at a ridgeline traversable by the solvent composition. 22. The microfluidic system of claim 21 , wherein each valley has a dwell volume that determines a percentage of the flow of solvent composition that passes through that valley. 23. The microfluidic system of claim 22 , wherein the dwell volumes of the valleys are specifically configured to target a known noise characteristic in the flow of solvent composition. 24. The microfluidic system of claim 22 , wherein the streams recombine at the mixing well in accordance with the percentages determined by the dwell volumes of the valleys to produce an output compositional stream with the noise characteristic attenuated. 25. The microfluidic system of